A bootstrap and a subsequent injected alpha analysis were conducted on 1,221 Chinese mutual funds that were active at some point between July 2001 and July 2021. The results show that most active managers achieve a positive risk-adjusted return. Additionally, we find that this phenomenon is primarily attributable to local (i.e., Chinese) fund managers. We argue that one explanation for the different levels of risk-adjusted returns observed is the information asymmetry between foreign and local fund managers. Additional results support this view, as fund managers primarily investing in small- to mid-cap and value stocks provide a superior performance, which inherently exhibit greater information asymmetry. The findings are contrary to those from similar studies in developed markets, where only a few active managers demonstrate actual skill in their performance.
Citation: Julius Nickelsen, Olaf Stotz. Do fund managers in the Chinese mutual fund market deliver positive risk-adjusted returns? Yes, but it is mainly observed for local fund managers[J]. Quantitative Finance and Economics, 2023, 7(4): 595-621. doi: 10.3934/QFE.2023029
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A bootstrap and a subsequent injected alpha analysis were conducted on 1,221 Chinese mutual funds that were active at some point between July 2001 and July 2021. The results show that most active managers achieve a positive risk-adjusted return. Additionally, we find that this phenomenon is primarily attributable to local (i.e., Chinese) fund managers. We argue that one explanation for the different levels of risk-adjusted returns observed is the information asymmetry between foreign and local fund managers. Additional results support this view, as fund managers primarily investing in small- to mid-cap and value stocks provide a superior performance, which inherently exhibit greater information asymmetry. The findings are contrary to those from similar studies in developed markets, where only a few active managers demonstrate actual skill in their performance.
In the current paper, we focus on two basic, interrelated principles of systemic regulation of brain functions—the opponent process theory by R.S. Solomon [1,2,3], and A.A. Ukhtomsky's principle of the dominant [4,5], and apply them to electroencephalographic (EEG) analysis of human performance at university oral exams in naturalistic conditions [6]. By drawing on the experimental results of this pilot study, we demonstrate that successful adaptation of students to the requirements of an oral examination depends on the presence of individual types of cortical activation patterns (CAPs), involving high indices of left-hemispheric and frontal cortical dominance, whereas the lack thereof reliably predicts low achievement on the task, and seems to be associated with difficulties in the executive regulation of cognitive (intellectual) and acquired motivational processes in these highly challenging and stressful conditions. Findings from these studies seem to support several key tenets of Solomon's opponent process theory of motivation dynamics [3], and may help to analyze its so far relatively poorly understood neurophysiological mechanisms in the light of the dominant principle [4,5]. In particular, the widely prevalent, if not universal functional principle of coupled opposed dynamics (COD) of cortical activity, as revealed in the principle of the dominant, can be of fundamental importance for elucidating how functional cerebral systems with mutually exclusive and opposed effects interact in time, leading to both adaptive or maladaptive behavioral and cognitive responses. We introduce functional measures of COD, such as the coupled inversion of anterio-posterior (fronto-occipital) and bilateral (inter-hemispheric) activation gradients, to analyze these responses, and show how their dynamics change in different task conditions and cognitive states in a manner consistent with the opponent process theory.
Methodologically, analyzing the neurophysiological dynamics of motivational reactions in ecological settings may require specific approaches, and this has been rarely attempted in exam conditions. While numerous works are devoted to the role of emotions, stress and anxiety in the learning process [7,8,9], including the exam situation, virtually all such studies are limited to pre-examination and post-examination analysis [10,11,12,13,14,15], without affecting the exam itself, particularly with regard to measuring the brain's bioelectric activity in the course of the exam interaction and presumable peak stress experience. The current line of studies sought to validate the applicability of dynamic EEG analysis in these settings [6,16,17]. It may therefore represent particular interest for analysing not only the electrophysiological correlates of opponent processes, as understood by Solomon, but also for considering their so far little explored social and interpersonal aspects in relevant natural settings.
As will be shown, based on such knowledge, the individual variability of dominant and opponent processes can be analyzed, and improved pedagogical and therapeutic interventions suggested which take into account marked individual differences in the neural and cognitive mechanisms underlying adaptation to motivationally and intellectually challenging tasks, such as the oral exam. These aspects will be more extensively addressed in the discussion, after the concepts of the dominant and opponent processes have been introduced (section 2), and relevant empirical materials presented (section 3). Theoretically, the integrative approach developed here [6,16,17] corresponds to the widely recognized need for systemic frameworks and methodologies in the fields of behavioral and human neuroscience [18,19], and in the analysis of EEG [20,21], in particular.
In the fields of neuroscience and psychophysiology, both the theory of opponent processes, as well as the principle of the dominant stand out by their systemic, heuristic predictions and specific applications in an unusually wide range of topics. Thus, Solomon and Corbit [1] proposed a general model of opponent processes to explain an apparently widespread mechanism securing the dynamic homeostasis of intense, contrastive emotional and motivational states [3]. The authors gathered evidence from physiology and psychology for a general model explaining how intense hedonic experiences can automatically induce in the nervous system a biphasic, compensatory motivational or affective process of opposite hedonic valence, before a return to stable affective baseline state occurs in the subject. However, the neurophysiological underpinnings of this dynamic homeostatic phenomenon have remained relatively elusive and little studied, in comparison to its behavioral and psychological effects.
Recently, some of the related methodical and methodological challenges have been discussed by Comer et al. [22]. In particular, the authors propose that the functional cerebral systems theory of A.R. Luria [23] may still provide "unsurpassed explanatory value and testability" in promoting the systemic-dynamic exploration of functional processes within the nervous system [22], including the relevant homeostatic and compensatory effects. Indeed, such aspects have remained largely underappreciated, and challenge current attempts to integrate opponent processes into mainstream neuroscience research, according to their view [22].
Here, we suggest that besides the works of A.R. Luria, valuable insights for the study of dynamic functional systems can be obtained from a historically and methodologically closely related tradition, namely A.A. Ukhtomsky's study on the dominant [4,5]. The fundamental basis informing this line of work concerns the unity of opposed functional processes in the brain—excitation and inhibition—as tonic neurophysiological states, and their reciprocal induction in cortical and neuronal excitability [24,25,26]. In particular, this approach may help to understand how intense work-load on any functional system—of immediate hedonic valence or not—can evoke its auto-inhibition and resultant "super-compensatory" effects, before a more stable baseline of excitability is restored or modified in the brain. In the present paper, we are limited to discussing this phenomenon in its cortical physiological aspects.1
1Currently, the concept of hormesis is widely discussed as a general biological model of state-dependent functional effects in physiological systems, particularly in relation to the varying and opposed effects which neurotransmitters and other substances may have at the cellular level, depending on their concentration (dose-response effects) or other conditions of exposure [77]. On the other hand, the conceptual and historical parallels of the hormetic research paradigm with the framework of parabiosis and paranecrosis, going back to Ukhtomsky's teacher N.E. Wedensky's and D.N. Nasonov's works [78,79], are also recognized [80,81]. These aspects lay beyond the scope of this paper, but are important to theoretically highlight, particularly given the recent interest in hormetic phenomena in the nervous system [82,83]. Without addressing such opposed phased functional effects, it may be difficult to develop a low-level neuronal interpretation of opponent processes in relation to particular transmitter systems, as currently sought [84,85], and thus firmly ground opponent process theory in biology. Interestingly, the school of Wedensky-Ukhtomsky appears to remain the only physiological tradition where principles characterizing homeostatic phenomena at the neuronal level, and the functional state parameters of general, brain-wide dynamics have been investigated from a common perspective [25,86].
The dominant approach allows to highlight how the opponent temporal dynamics of motivations and emotions may depend on the non-equilibrium properties of the cortical biopotential field as a whole. This field can be characterized by transitions in the foci of maximal activation (FMA), and by the localization of the accompanying coupled, collaterally inhibited areas in the surrounding cortical tissue. These two contrastive neurophysiological responses represent a pattern of coupled opposed dynamics (COD) in the cortex that seems to be of wide, perhaps universal relevance for interpreting neurophysiological coordination dynamics and mechanisms [6,17,27] (section 3).
In particular, this approach to opponent processes may allow to better understand the mechanisms governing dynamic changes in hemispheric dominance [22,28], as well as to demonstrate how shifts in inter-hemispheric and prefrontal dominance relate to changes in the motivational and higher cognitive processes of subjects as they adapt to diverse task conditions and cognitive work load [6,16,27]. Below, we show evidence for the hypothesis that opponent motivational processes may be directly related to changes in hemispheric and prefrontal dominance indices. While this hypothesis has been proposed and is supported by other experimental paradigms and evidence [22,28], the current approach allows to extend and generalize these findings by applying a novel experimental and methodological framework for their neurophysiologically rigorous and ecologically valid investigation—albeit in a small-scale pilot study.
It can be noted that respective materials raise also general theoretical problems, as they highlight that shifts in motivational states are most probably not limited to the sphere of "hedonic" processes or specific subcortical regions in the brain, but seem to involve widely distributed functional cerebral systems, including cortical ones associated with higher psychological processes and executive functions in humans. Although direct EEG evidence on opponent effects is so far limited, a recent study by Kline et al. [28] has obtained relevant results in this regard and should be shortly highlighted.
The authors revealed the role of prefrontal cortical regions in the opponent-type regulation of emotional experience, and showed how the organization of this experience depends on the dynamics of hemispheric functional asymmetry. In particular, it was shown that fear reactions evoked in a group of participants (in response to aversive pictures of human faces) are accompanied by increased relative right prefrontal activation, whereas the predominance of left prefrontal regions inhibits the same negative reaction and may, in well-coping subjects, respectively show enhanced and super-compensatory activity after the initial fear response. The authors interpret this increased leftward activation as a contrastive after-reaction necessary for suppressing, on an opponent process basis, the mainly right-hemispheric aversive response [28]. Although not obtained in an exam setting, these results seem to confirm the view that opponent affective processes, as conceived by Solomon, are closely associated with a corresponding contrastive dynamics in frontal lobe activity. A replication of this hypothesis in other experimental paradigms would be highly desirable, nevertheless, to demonstrate the pervasiveness of such opponent regulations and their possible functional contexts. This could also lead to a better understanding of the intra-and inter-individual variability which such opponent effects may have, their task-specificity, as well as association with other neural systems.
Close to the present focus, an early study by Craig and Siegel [29] has addressed the principle of opponent regulation in the exam situation. The authors investigated habituation to test-anxiety in college students and obtained evidence supporting Solomon's theory. In particular, by administering mood adjective checklists to students for self-rating just before and immediately after taking a final course exam, the authors quite expectably found a reliable decrease in dysphoria—but more significantly, also an increase in euphoria subsequent to the stressful test event, consistent with the opponent process model [29]. The important implication of the latter is the prediction of not simply attenuating apprehension, but also a surge in elation upon completing the exam. However, this study did not employ any physiological measures, and together with other related studies on exams [10,11,12,30], would clearly benefit from an integrated psychophysiological approach, allowing to analyze the neural substrates and mechanisms directly involved in the exam situation and interactions [16,17]. Likewise, most research on emotional and stress reactions has so far investigated EEG and peripheral signals separately [31], although their fusion and joint assessment may improve the robustness of both lines of findings [31], as our own data in the exam setting also suggests.
As shown below, our research on the higher cortical regulation of cognitive and motivational processes are in direct agreement with the above results [28,29], and may help to generalize and extend these findings on opponent-type regulation to more complex types of motivational and cognitive responses—such as involved in real-time exam situations. Before turning to the empirical findings obtained in this framework, we will briefly describe some methodological specifics of this line of studies based on A.A. Ukhtomsky's principle of the dominant. Further integration of this approach and findings with opponent-type processes is presented in the discussion.
It's passing first to consider A.A. Ukhtomsky's pioneering insights on the functional role of EEG rhythms. Based on the concept of "operative rest" or calm (cf. [32,25]), his views were among the first to clarify the controversial issue of the quasi-periodic alpha-rhythm (8–10 Hz) and its significance in human brain activity. Ukhtomsky proceeded from the experimental fact that in humans, the resting state is dominated by coherent, low-frequency alpha-waves of high amplitude. Peripheral stimuli from sense organs are known to disturb this "resting-state oscillation" and to give rise to higher-frequency activation (beta rhythms > 12 Hz) in the cortical projections, further enhanced by the subject's endogenous attentional and emotional arousal. These facts led Ukhtomsky to conclude that it would be incorrect to see coordination as being generally based on the synchronization of neuronal activity alone [4]—more often than not, it depends on a parallel increase in the desynchronization of neural networks [4,6]. This constitutes a general principle of coupled opposed dynamics (COD) in brain function, as clarified below.
Elucidating the role and mechanisms of alpha-rhythm desynchronization continues to be an active area of research, where various general and more specific hypotheses have been offered to account for its functions. Jensen et al. [33] have framed an influential view on the gating and filtering properties of the cortical alpha, which through targeted suppression ("pulsed inhibition") of higher-frequency rhythms, particularly gamma oscillations (30–70 Hz), is assumed to have an active inhibitory role in shaping functional cortical architecture. Closely compatible interpretations have been recently proposed by Klimesch [34], who suggests an active inhibitory function for alpha activity in controlling attentional and conscious access to stored memory and knowledge; for this access to occur, information from competing sources must be temporarily excluded (suppressed). In more formal terms stemming from information theory, alpha desynchronization can be related to information richness in the brain, necessary for the encoding and retrieval of memory and other cognitive processes [35]; on the other hand, the degree of synchrony in neural firing patterns is inversely related to their information carrying capacity [35]. Indeed, hypersynchronized cortical activity in the alpha range has been associated with complete blockage of intracortical communication, leading to the breakdown in sensory processing and loss of consciousness [36]. Important studies, closely related to our own, have also been carried out in the framework of coupled event-related desynchornization/synchronization (ERD/ERS) by Pfurtscheller and colleagues, suggesting that cortical activation (reflected in ERD) may be more focused and concentrated when surrounded by fields of antagonistic inhibitory synchronization (ERS), particularly within the alpha band [37,38,39].
Thus, modern studies seem to offer numerous confirmations regarding the dominant concept and its application in the field of EEG study. At the same time, some methodological differences regarding the principles of EEG analysis should be noted. This concerns above all the problem of dynamic features of neural signals, specifically the non-stationary (discontinuous, segmentary) and stochastic properties they exhibit. While knowledge of such features has been available for a long time (and forms the basis of our work [40]), they have typically been ignored in current and classical frameworks of EEG interpretation due to methodical and theoretical premises [20,21]. On the other hand, while this may simplify signal analysis, neglecting such dynamic features has also lead to significant difficulties in constructing global models of the EEG phenomenon, and in relating it to problems of cognition and consciousness [20,21]. Thus, novel methodologies sensitive to the underlining quasi-stationary nature of the EEG signal are clearly necessary [21]. One of the earliest such frameworks has been developed in collaboration with one of the authors (L.P.) [17,40] on the basis of the dominant principle. Below, some of its key premises and methods are briefly outlined.
The principle of dominant introduces into cognitive science a factor rarely considered in other frameworks—the factor of non-equilibrium as an invariant principle in all neurocognitive phenomena. In its most general form, Ukhtomsky characterized dominant states as consisting of two coupled and inverse processes—a leading "focus" or excitatory link, and systemic propagation of inhibition over the remaining elements of the system. This divergent pattern constitutes a universal mechanism of coordination in his view, and the means by which superfluous degrees of freedom are eliminated in neural systems. In this context, dominance is not so much a theory or hypothesis, but an obvious feature of functional cerebral systems in his view. However, it can offer powerful heuristics for studying brain activity when constrained by specific models and analytic methods, and may prove to be its highly universal organizational feature.
It is thus instrumental to define an adequate model for dominant states and the associated non-equilibrium dynamics in brain networks. The dominance model outlined below presents methods for multi-parametric and multi-channel analysis of such functional dynamics according to coherence and synchrony parameters [6,40]. Accordingly, the activation gradients (AG) characterizing functional asymmetry indices along anterio-posterior (AP) and bilateral (LR) interhemispheric cortical zones define the structure of cortical activation patterns (CAPs), and their "non-equilibrium" (functional asymmetry). In our previous works, we elaborated optimal statistical quantitative measures for characterizing functional shifts in the brain's dominant CAP states, defined by the momentary activation gradients between α-and higher frequency rhythms [40,17] (Appendix 1).
In this model, a dominant CAP state is reflected in two coupled inverse shifts in regional biorhythm indices characterizing cortical areas: (1) a focus of maximal activation (FMA), with amplified β-rhythms in a given region and attenuated α-oscillations (down to their complete disappearance in that area); and (2) a state of coupled inhibition in the surrounding cortical regions, as reflected in the simultaneous appearance of amplified α-rhythm [6,17] (Appendix 1).
Additionally, an activation coefficient KC/O can be determined by the relation of latent reaction periods (LRP) after closing and opening the eyes—with LRP for closed eyes (LRP–CE) reflecting excitation inertia, and LRP for opened eyes (LRP–OE) reflecting inhibition inertia, or the inertial properties of inhibitory cortical states (Appendix 2).
Oral exams present one of the most intense forms of human mental activity, combining both intellectual, emotional, and stress-regulatory components in a highly dynamic social setting [6]. Examining their individual variability and neurocognitive structure may therefore present unique insights into the mechanisms of opponent processes in naturalistic conditions.
Our studies were carried out in an experimental EEG recording facility in collaboration with Dr. N. Volkind from Krasnoyarsk Pedagogical Institute, with whom we conducted university term examinations on the subject "physiology of higher nervous activity" on volunteering student participants from St.-Petersburg State University's Psychology Faculty. To ensure high performance criteria, students' examination grades were recorded on exam sheets and reflected in their official study records.
Experimental conditions: In a group of 20 students (18 y.o., male, all right-handed), EEG was recorded continuously from 8 to 10 symmetrical anterior and posterior cortical sites (using the device "Biofizpribor", 0.3–100 Hz bandwidth), simultaneously with electrocardiogram (ECG) data [6,17]. Electrode montage is specified in Appendix 3. On the eve of the exams, a test experiment was carried out on each participant to ensure habituation to exam settings and to the Eyes Closed/Eyes Open (EC/EO) test (Appendix 2). Each experimental session lasted for no less than 1.5 hours in a row, during daytime, under normal daylight conditions. EEG recordings were made as the subjects were seated in a comfortable chair, in a specially screened room (3 × 3 m2) shielded from external noise. After installing the electrodes, the FAM test (Feeling, Activity, Mood) [41,42] was administered to students, who thereafter were left alone for 15 minutes to rest and prepare before starting the exam. After completing the exam, students were left to rest for 20 minutes, before being again administered a FAM test by the experimenter. Furthermore, prior to the experiment we tested subjects by the Hand [43], personal orientation inventory (POI), and Eysenck personality questionnaire (EPQ) psychological tests.
Students' EEG and ECG were recorded continuously throughout 5 stages of the exam: Ⅰ stage—students await for the examiner, corresponding to a state of operative rest (15 min); Ⅱ stage—the examiner enters the room, students receive tickets (topics), read them in the examiner's presence, the examiner leaves; Ⅲ stage—students prepare independently an answer to the ticket (20 min); Ⅳ stage—students are orally examined on the ticket and on additional questions, are notified of their grade (20 min); Ⅴ stage—period of post-exam rest, the examiner has left (20 min). Throughout the whole exam, short EC/EO tests were administered every 2–3 min.
It should be stressed that we did not assess FAM scores by averaging results across the participants, but distinguished between 2 experimental subgroups by their grades—a high-achieving group (A), who passed for "excellent", and a low-achieving group (B), who either failed the exam or passed it poorly. This strategy was used to reveal adequate correlations between CAP types and given sets of activity. While selecting students to be included in either group by their grade, we strove to maintain their homogeneity also by other indices, above all by high achievement motivation, which was present in all subjects. (In group A, all 5 students had "excellent" academic records exclusively in all subjects, and had all graduated with honors from highschool. In group B, students with high achievement motivation and generally good knowledge of the subject were chosen, but who failed to demonstrate this knowledge in the specific settings of an oral exam, both in the current study and during prior oral exams). These inclusion criteria were applied meticulously, particularly given the small sample size of the study.
Ethical conditions: The study was conducted on unpaid volunteers. Experimental procedures of study, including its ethical and medical aspects, were reviewed and approved by an expert committee at the A.A. Ukhtomsky Physiological Research Institute at St.-Petersburg State University. Participation in the study involved written consent from students and Deans of the Psychology and the Biology Faculties of the University.
Most significant shifts in the level of cortical activation (by the coefficient KC/O) (Appendix 2) and vegetative nervous activity (pulse rate) were observed in stages Ⅱ and Ⅳ of the exam—while drawing the ticket and answering it, respectively. Signs of examination stress were particularly pronounced in highly anxious, poorly answering students (Figure 1).
Figure 1. Shifts in general activation of cerebral cortex (A) and pulse rate (B) in consecutive stages (Ⅰ–Ⅴ) of oral examination in four variously graded groups (5 subjects in each group). Ordinate: A—average measures of general cortical activation (ΣKC/O, in conditional units), B—pulse rate (bpm); a, b, c, d—grades received: excellent (a), good (b), average (c), poor (d), respectively. Abscissa—exam stages: Ⅰ—waiting; Ⅱ—drawing a ticket; Ⅲ—preparing the answer; Ⅵ—exam response; Ⅴ—after-effects.Significant individual differences in the indices of general cortical activation by KC/O(Figure 1A) and pulse rate (Figure 1B) can be seen in relation to success rate at the exam. During all stages of the exam, students receiving excellent and good grades (groups a and b) showed intermediate values for these indices, in comparison to students receiving average and poor grades (groups c and d). Thus, less successful responders where characterized either by an excessive degree of cortical activation and pulse rate (group c), or an insufficient value of these functional indices (group d), in comparison to the high-achiving groups. The reliability of this data is increased by the identical conditions in which all examinees were tested, and the highly significant differences in functional brain states of high-and low-achieving participants (Figure 2).
Figure 2. CAP types and mental work productivity at university exams (average data in 2 groups, 5 people in each). A—students with "excellent" results, generally high-achieving subjects; B—students with average or poor results, generally lower-achieving subjects. Ⅰ—relative activation (by KC/O) of left and right symmetrical cortical zones (%). Ⅱ—regional activation indices (on hemispheric projections; conditional units); numbers on the right: numerator—anterio-posterior non-equilibrium (KA/P), denominator—bilateral asymmetry index (KL/R). Ⅲ—variational distribution of KC/O values on logarithmic scale (on abscissa), number of variants (n = 400) for eachvalue (on ordinate). One curve corresponds to one subject. Values within KC/O > 0 reflect activation, values within KC/O < 0 reflect marked inhibition, deactivation. For methods, cf Appendix 2.Additionally, consideration of background EEG signals at the exam complements materials obtained by the EC/EO test, and allows to reveal symptoms of stress as well as mental fatigue in students. Most pronounced general cortical activation, determined by the coefficient of relative β-and α rhythm power (Kβ/α), was observed in stages Ⅱ and Ⅳ of the exam, and was accompanied by most significant increases in pulse rate (by 1.5–2 times).
Below, we analyze the CAP types in two groups of students with most divergent results at the exam, respectively receiving "excellent" or "poor" (insufficient) grades. Both groups included five subjects, who were tested during the exam (by EC/EO test) no less than 60 times each. The high significance of obtained differences is reflected in the variational curves obtained from large sample sizes (n = 400) of the EC/EO test in the two student groups (Figure 2).
In the "excellent"—graded group of students (Figure 2A), stable FMA was observed in left frontal areas by the general activation level as well as by the percentage of prevalent left-sided activity on the background of high anterio-posterior (fronto-occipital) activation gradients (AGs). At the same time, the almost complete superposition of KC/O variational curve values, revealing the presence of a distinct FMA in left frontal areas, testifies to a largely identical functional brain state in all five high-achieving subjects. Double-peaking variational curves reveal a distinct FMA in left frontal areas on the background of significantly reduced activation range in the subdominant brain regions, with a non-significant transition rate in the deactivated areas (by KC/O < 0; cf. Appendix 2). This allows to speak of a correspondence between the identified CAP type and requirements posed by the given class of verbal-logical tasks.
Among students receiving average and poor grades (group B), no distinct and stable FMA was found on the background of predominantly right-hemispheric activity (Figure 2B). In this group, diverse types of individual variational curves are seen, as well as a wider range of functional states (FSs). There is significant variation in regions with increased (KC/O > 0), as well as decreased activation, the latter reflecting an inhibited cortical FS (KC/O < 0) (Appendix 2). Reduced mental working capacity is accompanied by predominant activity in right prefrontal areas, on the background of significantly diminished anterio-posterior AG.
Comparing exam stages Ⅳ and Ⅴ—the oral response and post-exam rest (after the examiner has left)—leads to the suggestion that opponent-type functional states, as described by R. Solomon [1,2,3], characterize also cognitive performance during exams. This is reflected in the shifting activation indices for the left and right hemispheres, and accompanying changes in mood and feeling by FAM test (discussed below). During exam stage Ⅴ, an interesting paradoxical reaction can be seen in the brain activity of highly anxious subjects: a state of defensive cortical inhibition characterizing the response period typically changes, after the examiner has left, to a relatively normal state with FMA in frontal cortical regions; at the same time, speech functions recover that had been suppressed in the student during the response period in the examiner's presence.
Below, a detailed comparison of functional brain states during key stages of the exam, Ⅰ, Ⅳ and Ⅴ, are shown for two most highly contrastive students (Figures 3 and 4; Table 1). The students belong to different grade groups (Figure 2): Student R. was the best among high-achievers, while student G. the poorest performer in the weaker group. Data on intra-individual and comparative time-series variation can be particularly informative given the non-Gaussian distribution of obtained within-and between group measures (Figure 2), as well as considering the marked variabilty of individual EEG indices across various stages of the exam (Figures 3 and 4).
Figure 3. Examples of individual EEG dynamics during three examination stages in an excellently graded student (R.). A—diagram of the summed activation index of left and right cortical hemispheres (∑ KC/O, left ordinate). Deviations above midline—functional predominance of left-hemispheric activity, below midline—right-hemispheric predominance; numbers above and below curves: in brackets—summed general cortical activation (∑ KC/O), without brackets—relative activation predominance (%); isolated dots—values of inter-hemispheric asymmetry (KL/R, right ordinate). B—magnitude of anterio-posterior non-equilibrium (KA/P, ordinate); numbers below curves—averaged activation value; on abscissa—number of EC/EO trials (dots). Ⅰ—before exam start; Ⅱ—while answering the ticket; Ⅲ—after exam termination (examiner has left). Differences in the scale for summed cortical activation in hemispheres (0–300) and their functional asymmetry (-1 to 1) are due to respective equations (measurement units are conditional) (Appendices 1 and 2).
Figure 4. Examples of individual EEG dynamics during 3 examination stages in a poorly graded student (G.). Same designations as in Figure 3.| Student R. | Student G. | |||||
| Examination stage | Ⅰ | Ⅳ | Ⅴ | Ⅰ | Ⅳ | Ⅴ |
| Left hemisphere activation index | 97 | 158 | 21 | 14 | 27 | 30 |
| Left hemisphere dominance | 42% | 90% | 33% | 18% | 30% | 70% |
| Right hemisphere activation index | 38 | 20 | 100 | 30 | 39 | 22 |
| Right hemisphere dominance | 33% | 10% | 42% | 82% | 70% | 70% |
| KL/R | 0.4 | 0.7 | -0.6 | -0.3 | -0.2 | 0.5 |
| KA/P | 0.7 | 0.8 | 0.7 | -0.3 | -0.07 | 0.3 |
| Heart-rate (bpm) | 73 | 85 | 69 | 105 | 125 | 95 |
| FAMai | 6.0 | 4.5 | 2.2 | 5.3 | ||
| Hemispheric activation indices are in conditional units (Appendix 2). Ⅰ, Ⅳ, Ⅴ—stage of experiment; KL/R—bilateral asymmetry index; KA/P—anterio-posterior asymmetry index; FAMai—FAM-test averaged scale index. Subject R. received an excellent evaluation, subject G.—poor evaluation | ||||||
DownLoad: CSVSignificant differences in the dynamics of cortical functional state can be seen in the representative highly-graded subject R. and poorly graded subject G. As seen on Figures 3-4, this difference is manifest already before exam onset, during the waiting stage (operative rest). This is reflected in the general level of cortical activation, which is significantly higher in student R. on the background of left-hemispheric dominance (shown as dots on Figures 3A, 4A), and the significantly higher (0.78) and more stable predominance of frontal cortical regions (Figures 3B, 4B). In student G., right-hemispheric dominance can be seen on the background of significantly reduced cortical activation and appearance on the EEG of slow hyper-synchronous delta-waves, reflecting cortical defensive inhibition already prior to exam onset. At the same time, anterio-posterior functional asymmetry is markedly diminished (0.34) due to deactivation of frontal brain regions.
These differences between students R. and G. increase during the response stage (Ⅱ). In the high-achieving student R., left-hemispheric dominance is strongly amplified (with rising general activation), and the stability of frontal activity is increased. In student G., right-hemispheric dominance is retained on the background of reduced activation and instable dominance of frontal areas.
However, after exam completion, in both students rapid shifts occur in the opposite direction: in R., there is a transition to right-hemispheric dominance with a sharp drop in general cortical activation and reduced stability of frontal dominance, which can be interpreted as a reduction in neurocognitive work load. In student G., on the other hand, left-hemispheric dominance is quickly increased after the examiner has left, together with increases in inter-hemispheric functional asymmetry and frontal activation, i.e. cortical activation is increased.
On the example of these two students, strongly opposed intra-individual functional brain states can be seen by EEG and pulse measures when comparing stages 4 (response) and 5 (examiner's departure) (cf. Table 1 and Figure 5).
Figure 5. Prevalence of left-and right-hemispheric activation (by KC/O) at three stages of the exam. Green—left hemisphere; purple—right hemisphere. Above—student R., excellent response. Below—student G., poor response. Abscissa: Ⅰ—Initial state; Ⅱ—response; Ⅲ—after-effects. Left ordinate—activation sum by KC/O (curves in left columns); right ordinate—relative dominance of LH and RH, percentage (right columns).Additionally, before and after the exam, we administered to all students the FAM test [41,42] on feeling, activity and mood changes (Table 1). The range of functional state (FS) shifts on this test lies on a scale from 1 to 6 points. Normal FS is considered to lie between 5.0–5.5 points; scores below 4 reflect poor FS and mood. In the high-performing group (Figure 2A), the average score prior to the exam was 5.5, and fell to 3.6 post-exam; in the unsuccessful group (Figure 2B) the average pre-exam score was 3.5, and rose to 4.9 after exam termination. In student R., the pre-exam score was 6.0 (highest in group A), but fell to 4.5 post-exam (by mood factor). In student G., the pre-exam score was 2.2 points; however, 20 minutes post-exam the score had risen to 5.3 (by mood factor) (Table 1).
Although these results are preliminary and need careful replication on larger samples, it should be noted that the corresponding changes in neural activity observed across task conditions in each group seem to confirm them. In particular, this concerns the widely reported associations of relative left frontal activation with positive emotions and approach motivation, versus the negative emotions and defensive motivation associated with right-hemispheric frontal functions [28,44,45,46]. This asymmetry has also been directly observed in the context of examination stress regulation [10]. In this light, let us consider the two students' indices more closely.
Student R., with low anxiety, prevalence of verbal intellect, and analytical cognitive style (by Eysenck EPQ test), obtained an excellent grade. His initial functional state is characterized by left-hemispheric dominance, which increases during the exam response on the background of significant elevation of fronto-occipital AG and some increase in pulse rate. During this period, right-hemispheric activation decreases due to collateral inhibition from left-hemispheric dominants.
During the response, student R. shows positive emotions, apparently takes pleasure in answering the questions posed by the examiner. However, after responding, there is a clear drop in mood according to the FAM test (Table 1). At the same time, a significant reduction in left-hemispheric activation can be observed, together with increased activity and dominance of the right hemisphere, as well as diminished fronto-occipital AG, as shown in Table 1.
We can see from the above data how a clear transition takes place in student R., from a highly active physiological and cognitive state (and positive emotional experience) to an opposite functional state (accompanied by notably declined mood after the examiner has left). This is also reflected in the contrastive changes of EEG indices and pulse rate (Figure 5; Table 1).
Student G. shows high anxiety, has synthetic cognitive style, and prevalence of non-verbal intellect (by Eysenck's EPQ test). The subject knows the material, but has since school-years been afraid of exams. In the initial state, his cortical activity is reduced on the background of right-hemispheric dominance and markedly increased pulse rate (Figure 5; Table 1). Anterio-posterior AG and inter-hemispheric functional asymmetry are reduced. During the response, general cortical activation somewhat increases in the right hemisphere on the background of reduced activation and percentage of left-hemispheric activity, as well as deactivation of frontal regions (reflected in low fronto-occipital AG). However, as the examiner leaves, indices of functional brain state change contrastively—an increase is observed in left-hemispheric activation, together with increasing fronto-occipital AG on the background of collateral inhibition of the right hemisphere (Figure 5). In this case, a transition could be seen from negative emotional experience in the presence of the arousing stimuli (answering the ticket) to the appearance of a contrastive reaction—relief and satisfaction after the stressful situation has ended (as the examiner left).
A variety of methods were used to determine the emotional state of subjects. In addition to the oral response, the FAM test as well as certain behavioral characteristics and anamnesis were used. Student R., who received the excellent grade, had received during his two years of study at St.-Petersburg State University only the highest marks. Student G. did not manage to pass the exam and received a "poor"grade. During the response his speech was inhibited, and he did not seem to understand well the questions he was asked. Significant cortical deactivation was observed, and this coincided with markedly increased pulse rate (105 bpm) even before the exam, as well as during the response (125 bpm). This state can be defined as involving defensive inhibition ("functional pessimum") in the cerebral cortex on the background of simultaneous cardiac acceleration. It can be noted that this student, as well as others in the given group (Figure 2B), had frequent breakdowns during exams regardless of sufficiently good knowledge in the subjects. In all high-achieving students (Figure 2A), on the other hand, high mental productivity and composure were observed on the background of stable left frontal FMA while answering the ticket.
Apparently, the reason for CAP "dissolution" in stressful conditions is related to excessive stimulation of the cortex by the ascending activating systems. This gives rise to a flow of tonic impulses that are amplified in conditions of novelty and stress, and remain insufficiently regulated by the cortex. According to Luria's [23] and many later studies [47,48], key functions in the top-down regulation of ascending activating impulses are fulfilled by frontal cortical structures—a view supported also by Kline et al.'s [28], as well as our own findings.
Furthermore, prior to the exam we tested both subjects by the Hand [43] and POI psychological tests. In student R., we found high directiveness (13 points) and high self-actualization (40 points); in student G.—high frustration (88 points), high anxiety (44 points), and low self-actualization (6 points).
From a methodological perspective, it may be revealing to compare the above results with the findings by Dayan et al. [42], who used the FAM test and cardiac activity measures to study examination stress among high-school students enrolled in general educational classes versus differential classes (with more intensive coursework). FAM test scores demonstrated different dynamics of FS change depending on the type of class the students were enrolled in, as seen in Table 2.
| Measurement time | Average FAM scores in general program | Average FAM scores in differential program |
| Regular day | 5.24 ± 0.22 | 5.09 ± 0.19 |
| Pre-exam | 5.10 ± 0.25 | 4.85 ± 0.17 |
| Post-exam | 4.99 ± 0.25 | 4.95 ± 0.29. |
| FAM: Feeling, activity mood (test) | ||
DownLoad: CSVThus, in the differential (intense coursework) class the scores were somewhat lower (4.85) than in the general class, possibly due to a sense of hightened responsibility for exam results. Higher examination stress was found in sympatotonics. However, in this study FAM scores were averaged across all students of a given class, without differentiating between highly and poorly performing subjects, as in our study. This may explain the less significant differences observed in the above summed FAM test results (Table 2). In other words, representative groups were not defined in either class by academic achievement motivation or actual progress, which may explain the differences from our findings.
Importantly, the above findings seem to indicate that processes with an opponent-type organization affect also higher cognitive functions dependent on strong motivational and emotional arousal. Of course, further similar studies including other groups of students and larger sample sizes are necessary to confirm and extend these findings. However, this should be done in representative groups (e.g., highly motivated subjects), such as the reported groups of psychology students (all of whom were motivated to achieve high grades). Even then, regardless of possessing sufficient knowledge, some participants received low average or even poor grades since they were unable to concentrate, maintain composure, and cope with the stresses presented by the examination setting. In high-performing students, stable left-hemispheric dominance and strong fronto-occipital activation gradients helped to cope with the stressful situation. In low-performing students, on the other hand, no distinct left-hemispheric and frontal FMAs were observed, and this resulted in lower grades and stress-resistance in the same objective examination setting.
In sum, the above results reveal marked differences in the CAPs of successful and unsuccessful students at the exam, as reflected in the significantly higher activation of left frontal regions in high-achievers and of right frontal areas in those who failed the exam or passed it poorly. However, it should be stressed that in both groups, the characteristic CAP structure was regularly replaced by a symmetrically opposite one, with the predominant FMA periodically shifting to the right hemisphere in high-achievers, and conversely, to the left hemisphere in low-achievers, depending on particular stages of the exam. These inverse changes were combined with changes in pulse rate and the affective state of subjects, as registered by the FAM questionnaire and judged subjectively by the examiners at the exam interview. Together with available data on the contribution of prefrontal regions to the lateralization of emotions [10,22,44,45,46], these results suggest a key role of frontal brain regions' dominance shifts in the task-specific regulation of motivational and emotional states, including their opponent dynamics [28].
Further, the obtained results show not only the relevant role of activational asymmetries in bilateral hemispheric regions, but also in anterior and posterior brain regions, the relative dominance of which must likewise be regulated in accordance with task settings. Increases in left frontal activity in high-achievers were coupled to decreased, highly structured and stereotypical activation of posterior brain regions. On the other hand, the activation of right frontal regions in low-achievers was associated with higher, more generalized and individually varied activity in posterior cortical areas. Thus, the CAPs revealed in high-achievers were found to be relatively uniform in distribution (Figure 2) compared to low-achievers, in whom higher divergence between individual variational curves was observed, reflecting a wider range of distinct cortical functional states (Figure 2). Similar results on the higher variability of EEG indices during the exam period in low-achieving students have been reported by Wiet et al. [14].
The present study has shown that in exam settings, individually specific reorganizations of CAPs can be observed in students, accompanied by corresponding shifts in their motivational-emotional and cognitive processes. In the light of the opponent process model of homeostasis, we find the indications of dynamic "super-compensatory" effects in inter-hemispheric and anterio-posterior interactions to be particularly interesting, as observed in students under high work-load and exam stress conditions (Figures 3, 4). Thus, after periods involving high activation and relative dominance of either hemisphere or prefrontal regions, these functional activation indices are typically not simply downregulated to the baseline, but show a steep decline below it, accompanied by increased activation in the opposite hemisphere, or posterior regions (Figures 3, 4), in comparison to the initial functional state. This type of super-compensatory regulation seems not to be addressed in the classical frameworks of homeostasis, although as revealed by current and earlier related studies [1,3,28,29], it may represent a phenomenon of potentially wide adaptive significance in the self-regulation of excitability in cerebral functional systems [22,28].2 Theoretically, the opponent principle of regulation seems also consistent with current attempts to extend the classical frameworks of neural homeostasis by concepts such as anticipation and allostasis, to emphasize the inherent temporal variability and complexity of homeostatic processes in the brain [49,50,51].
2Interestinly, the problematic of super-compensation has a long history in Russian stress and sports physiology [87], as well as neurophysiology [25,88], although this has remained largely unknown in the West [5].
Earlier, Craig et al. [29] investigated students' emotional dynamics during the high exam session, and found them to closely match Solomon's concept of opponent-type regulation. Our research has led to closely comparable findings. However, unlike in any prior studies, our study included integrated physiological and EEG measures, which were analyzed together with emotional and cognitive processes immediately in exam conditions, and while taking into account the various success rate of responders in high-and low-achiving groups. This is most important for distinguishing between the qualitatively different patterns of psychophysiological response expectable in subjects who not only achieve different grades, but who may experience the whole exam situation and challenge differently in terms of the motivational, stress-regulatory, and affective dynamics involved [9,52]. Indeed, in line with growing appreciation of the positive roles of stress in motivation and performance [53], Strack et al. [9] have recently shown how the stressful period immediately leading up to the exams can be experienced by some students as motivating rather than threatening or emotionally exhausting, indicating they interpret anxiety as facilitative to learning, and are less likely to appraise the exam stressor as a threat. While this ability is positively associated with academic performance, and prevents emotional exhaustion [9], it is also expectable that the opponent effects in such students would be manifestly different from those who experience the exam, or the days leading up to it, as primarily a negative and threatening stressor [9,52], with adverse health impacts [10,12].
Thus, although we have underscored the importance of differentiating between participants based on their performance to overcome such difficulties, there are further methodological and technical challenges to be addressed in this line of research. This includes, besides organizational difficulties, the relatively high diversity of motivational and emotional reactions involved in the exam situation, owing both to individual trait differences [30,54], as well as to individual expectations and experience in taking exams, the degree of preparation [55], and the subjective significance of the academic result [55,56]. For this reason, we enlisted only highly motivated and well prepared subjects in our study, and assigned them to different groups based on test scores before comparing the physiological data. Even then, besides group-averages, data on within-individual variability can be instrumental for understanding the neurocognitive structures and dynamics underlying successful and unsuccessful responses. In this way, the possible unique characteristics and strategies of responders can be characterized, together with their individual psychophysiological profile and state.
It should be noted here that most neurophysiological studies on opponent processes to date have looked at cases of pathological dysregulation, mainly addictive behavior and its underlying neurobiological circuitry, changes in which show obvious maladaptive dynamics—and probably involve pathological super-compensatory effects as described by the opponent-process model [57]. On the other hand, besides such obviously dysregulatory effects in neural substrates mediating motivational states [57], and other allostatic effects involved in pathology [49], the opponent type regulation seems to also reflect key principles underlying normal adaptation with a positive and adaptive temporal trend. For example, this has been revealed in sports and physical exercise, the accompanying motivational and affective dynamics of which seem to reveal similar biphasic fluctuations, at least under more strenuous and intense exercise leading to increased resilience and stress tolerance (e.g., via stress-induced analgesia by endogenous opioids) [58]. Recently, this biphasic dynamics has been associated also with increased frontal asymmetry measures on a possible opponent process basis [59,60], similarly as we demonstrate here for the exam setting. Together, this may allow to hypothesize a close integration between higher cortical, emotional, and bodily stress-regulatory responses, on the basis of shared or similar opponent effects in the neural circuits mediating them.
Before turning to more general theoretical and methodological implications of our findings, it is therefore appropriate to comment on their potential applied significance. Indeed, the facts obtained in the current study reflect not only theoretical concerns, but also practical interest regarding the functional diagnostics of students' functional state in educational settings, and in particular, prior to stressful tasks such as (oral) exams. This offers the prospect of detecting "risk groups" most prone to the possible adverse health effects of such educational tasks. Given the increasing rates of anxiety and stress among college students found in recent research [61,62,63], and their close relation to depression and other mental health problems [63], these have become particularly urgent requirements today, and are now challenging universities to continually evaluate the mental health of students, as well as to tailor programs of prevention and treatment sensitive to their individual needs and work specifics [61,63]. Based on the dominant principle and relevant findings, we can suggest several non-invasive measures to increase the resilience of cortical functions and work dominants in easily stressed, highly anxious, and chronically tired students.
(1) In students practicing sports, symptoms of cortical over-excitation or defensive inhibition were generally not observed during exams. This allows to speak of optimal relations between intellectual, emotional, and stress-regulatory components of the exam response in physically trained subjects [6], and is in accord with numerous findings on the neurocognitive benefits of exercise [64,65], even if its relations to opponent neural dynamics require further study [58,59]. In particular, defining universal dose-response relations between excercise vigor, motivational and affective opponent effects, and health benefits has remained a difficult and largely elusive task [58]. From the present perspective, this further underscores the need to develop methods sensitive to the individual variability and specificity of such integrated physiological responses. Below, we discuss this question in more detail with respect to EEG analysis.
(2) Development of self-control through neurofeedback [66,67,68]. Our results have shown increased neurofeedback effectiveness if, in each individual, a most "controllable" cortical zone is selected, in which the alpha-rhythm can be most easily amplified by neurofeedback signals through visual, or other feedback channels [69]. Neurofeedback sessions are found to increase the efficiency of mental work and optimize cognitive performance on the background increased left-hemispheric dominance and fronto-occipital activation gradients [6,46], in accordance with the above reported results.
(3) The stress impact of an exam can be reduced by changing how students are engaged—e.g., by allowing a written reply, additional time for preparing responses, encouraging attitudes by the examiners, etc. In anxious and neurotic subjects this creates conditions for forming a sufficiently stable frontal left FMA and is accompanied by improved quality of the exam response [6,16]. Furthermore, we have found evidence for possible personal compatibility effects in student-examiner interactions based on the similarity of their resting-state hemispheric dominance patterns [6,17]. The possible influence of such effects on a student's performance and grading should be taken into account, particularly in low-achieving students most prone to examination stress and anxiety.
Although traditionally, educational problems have been solved in the confines of humanities, the reported findings clearly indicate how a psychophysiological framework may support and enhance educational practices. This is particularly relevant for meeting special educational needs [16]. To best address these requirements, we propose that distinct types of integrative methods and concepts are needed to analyze not only inter-individual and quantitative, but also intra-individual and qualitative physiological measures of adaptation and human performance [70]. With regard to EEG analysis, this requires particular attention to the dynamic features of the EEG signal, such as its non-stationary stochastic properties [40]. While methods ignoring these complex properties have led to important discoveries, such as the functional specificity of individual EEG frequency bands, the initially rapid temporal resolution of the EEG signal is usually lost under such conditions [20,21], and makes its neurophysiological systemic interpretation more difficult. This limitation may particularly affect most dynamic experimental settings, such as those analyzed above, involving human psycho-social and socio-physiological functioning in exam conditions, or other conditions involving prolonged and conflicting motivational and stress responses.
In line with these requirements, we have presumed here that instead of individual frequency bands or correlational dependences between them, the neurophysiological units of cognitive processes should be sought in the rapidly shifting, discontinuous metastable states of the brain's biopotential field as a whole, characterized by anterio-posterior and inter-hemispheric activation gradients, as well as by global and regional changes in cortical states' inertial ("trace") properties (Appendices 1, 2). Such dynamic indices are highly variable both intra-and inter-individually, and this in close dependence on task conditions. Such methodological and methodical aspects may be fundamental if neuroscience research results are to be more directly applicable to educational settings and classroom scenarios, as currently called for [71]. Besides questions of methods and modeling, however, also ethical concerns should be further addressed in this line of research [72], including the possibilities of optimal educational and therapeutic interventions, preventive and rehabilitative measures at the individual level [16], as discussed above.
In our view, the framework of the dominant and the theory of opponent processes could provide valuable, mutually reinforcing concepts and models in this regard. These two frameworks are not only closely compatible, but both seem to possess the optimal levels of generality and complexity expected for integrative explanations and models in theoretical neuroscience [18]. Indeed, the necessity for such concepts—both sufficiently generalizable, yet well specifiable due to adequately chosen basic parameters—is becoming increasingly apparent in the field [18], together with some of the risks associated with prematurely formalizing its subject matter by methods drawn directly from other, non-biological disciplines (informatics, physics, etc.) [17,18,40,73]. These methodological considerations have played an important role in designing the current framework of EEG analysis on the basis of the dominant principle [6]. As such, it is hoped the presented materials encourage further research on the neural dynamics mediating opponent processes, and their integration into theoretical and applied human neuroscience.
The preparation of this work was supported by Charles University Grant Agency grant No. 926916. The authors wish to thank Dr. Aaro Toomela and an anonymous reviewer for comments and suggestions on an early version of this paper, and Mr. Sergey Tkachenko for his help with processing the image materials.
The authors declare no conflicts of interest in this paper.
| [1] |
Agyei-Ampomah S, Clare A, Mason A, et al. (2015) On luck versus skill when performance benchmarks are style-consistent. J Bank Financ 59: 127–145. https://doi.org/10.1016/j.jbankfin.2015.05.013 doi: 10.1016/j.jbankfin.2015.05.013
|
| [2] |
Ayers BC, Ramalingegowda S, Yeung PE (2011) Hometown advantage: The effects of monitoring institution location on financial reporting discretion. J Account Econ 52: 41–61. https://doi.org/10.1016/j.jacceco.2011.03.003 doi: 10.1016/j.jacceco.2011.03.003
|
| [3] |
Berk J, van Binsbergen JH (2015) Measuring skill in the mutual fund industry. J Financ Econ 118: 1–20. https://doi.org/10.1016/j.jfineco.2015.05.002 doi: 10.1016/j.jfineco.2015.05.002
|
| [4] |
Blake D, Caulfield T, Ioannidis C, et al. (2017) New evidence on mutual fund performance: a comparison of alternative bootstrap methods. J Financial Quant Anal 52: 1279–1299. https://doi.org/10.1017/S0022109017000229 doi: 10.1017/S0022109017000229
|
| [5] |
Carhart MM (1997) On persistence in mutual fund performance. The Journal of Finance 52: 57–82. https://doi.org/10.2307/2329556 doi: 10.2307/2329556
|
| [6] |
Chan K, Covrig V, Ng L (2005) What determines the domestic bias and foreign bias? Evidence from mutual fund equity allocations worldwide. J Finance 60: 1495–1534. https://doi.org/10.1111/j.1540-6261.2005.768_1.x doi: 10.1111/j.1540-6261.2005.768_1.x
|
| [7] |
Chen X, Wu C (2022) Retail investor attention and asymmetry: evidence from China. Pacific-Basin Finance J 75: 1–19. https://doi.org/10.1016/j.pacfin.2022.101847 doi: 10.1016/j.pacfin.2022.101847
|
| [8] |
Chung CY, Sul HK, Wang K (2021) A tale of two forms of proximity: Geography and market. J Bus Res 122: 14–23. https://doi.org/10.1016/j.jbusres.2020.08.060 doi: 10.1016/j.jbusres.2020.08.060
|
| [9] |
Cuthbertson K, Nitzsche D (2013) Performance, stock selection and market timing of the German equity mutual fund industry. J Empir Finance 21: 86–101. https://doi.org/10.1016/j.jempfin.2012.12.002 doi: 10.1016/j.jempfin.2012.12.002
|
| [10] |
Cochrane JH (2011) Presidential address: Discount rates. J Finance 66: 1047–1108. https://doi.org/10.1111/j.1540-6261.2011.01671.x doi: 10.1111/j.1540-6261.2011.01671.x
|
| [11] |
Corbet S, Hou Y, Hu Y, et al. (2020) The influence of the COVID-19 pandemic on asset-price discovery: Testing the case of Chinese informational asymmetry. Int Rev Financial Anal 72: 1015–1060. https://doi.org/10.1016/j.irfa.2020.101560 doi: 10.1016/j.irfa.2020.101560
|
| [12] |
Cornell B, Hsu J, Kiefer P, et al. (2020) Assessing mutual fund performance in China. J Portf Manag 46: 118–127. https://doi.org/10.3905/jpm.2020.1.140 doi: 10.3905/jpm.2020.1.140
|
| [13] |
Deng Y, Xu Y (2014) Do institutional investors have superior stock selection ability in China? China J Account Res 4: 107–119. https://doi.org/10.1016/j.cjar.2011.06.001 doi: 10.1016/j.cjar.2011.06.001
|
| [14] |
Fama EF, French KR (1993) Common risk factors in the returns on stocks and bonds. J Financ Econ 33: 3–56. https://doi.org/10.1016/0304-405X(93)90023-5 doi: 10.1016/0304-405X(93)90023-5
|
| [15] |
Fama EF, French KR (2010) Luck versus skill in the cross-section of mutual fund returns. J Finance 65:1915–1947. https://doi.org/10.1111/j.1540-6261.2010.01598.x doi: 10.1111/j.1540-6261.2010.01598.x
|
| [16] |
Fama EF, French KR (2015) A five-factor asset pricing model. J Financ Econ 116: 1–22. https://doi.org/10.1016/j.jfineco.2014.10.010 doi: 10.1016/j.jfineco.2014.10.010
|
| [17] |
Fama EF, French KR (2018) Choosing factors. J Financ Econ 128: 234–252. https://doi.org/10.1016/j.jfineco.2018.02.012 doi: 10.1016/j.jfineco.2018.02.012
|
| [18] |
Ferreira MA, Matos P, Pereira JP, et al. (2017) Do locals know better? A comparison of the performance of local and foreign institutional investors. J Bank Financ 82: 1–164. https://doi.org/10.1016/j.jbankfin.2017.06.002 doi: 10.1016/j.jbankfin.2017.06.002
|
| [19] | Fifield SG, Jetty J (008) Further evidence on the efficiency of the Chinese stock markets: A note. Res Int Bus Finance 22: 351–361. https://doi.org/10.1016/j.ribaf.2008.02.002 |
| [20] |
Gao J, O'Sullivan N, Sherman M (2020) An evaluation of Chinese securities investment fund performance. Q Rev Econ Finance 76: 249–259. https://doi.org/10.1016/j.qref.2019.08.007 doi: 10.1016/j.qref.2019.08.007
|
| [21] |
Gao J, O'Sullivan N, Sherman M (2021) Chinese securities investment funds: The role of luck in performance. Rev Account Financ 20: 271–297. https://doi.org/10.1108/RAF-07-2020-0182 doi: 10.1108/RAF-07-2020-0182
|
| [22] |
Grinblatt M, Keloharju M (2000) The investment behavior and performance of various investor types: A study of Finland unique data set. J Financ Econ 55: 43–67. https://doi.org/10.1016/S0304-405X(99)00044-6 doi: 10.1016/S0304-405X(99)00044-6
|
| [23] |
Harvey CH, Liu Y (2020) False (and missed) discoveries in financial economics. J Finance 75: 2503–2553. https://doi.org/10.1111/jofi.12951 doi: 10.1111/jofi.12951
|
| [24] |
Jensen MC (1968) The performance of mutual funds in the period 1945–1964. J Finance 23: 389–416. https://doi.org/10.1111/j.1540-6261.1968.tb00815.x doi: 10.1111/j.1540-6261.1968.tb00815.x
|
| [25] |
Kiymaz H (2015) A performance evaluation of Chinese mutual funds. In J Emer Mark 10: 820–836. https://doi.org/10.1108/IJoEM-09-2014-0136 doi: 10.1108/IJoEM-09-2014-0136
|
| [26] |
Kosowski R, Timmermann A, Wermers R, et al. (2006) Can mutual fund "stars" really pick stocks? New evidence from a bootstrap analysis. J Finance 61: 2551–2595. https://doi.org/10.1111/j.1540-6261.2006.01015.x doi: 10.1111/j.1540-6261.2006.01015.x
|
| [27] |
Koutmos D, Wu B, Zhang Q (2020) In search of winning mutual funds in the Chinese stock market. Rev Quant Finance Account 54: 589–616. https://doi.org/10.1007/s11156-019-00800-z doi: 10.1007/s11156-019-00800-z
|
| [28] |
Kutan AM, Lin H, Sun PW, et al. (2018) A reliable performance measure to differentiate China's actively managed open-end equity mutual funds. Appl Econ 50: 5592–5603. https://doi.org/10.1080/00036846.2018.1488055 doi: 10.1080/00036846.2018.1488055
|
| [29] |
Leuz C, Lins KV, Warnock FE (2008) Do foreigners invest less in poorly governed firms? Rev Financ Stud 22: 3245–3285. https://doi.org/10.1093/rfs/hhn089 doi: 10.1093/rfs/hhn089
|
| [30] |
Li S, Brockman P, Zurbruegg R (2015) Cross-listing, firm-specific information, and corporate governance: Evidence from Chinese A-shares and H-shares. J Corp Finance 32: 347–362. https://doi.org/10.1016/j.jcorpfin.2014.10.008 doi: 10.1016/j.jcorpfin.2014.10.008
|
| [31] |
Li Y, Yan D, Greco J (2006) Market segmentation and price differentials between A shares and H shares in the Chinese stock markets. J Multinatl Financial Manag 16: 232–248. https://doi.org/10.1016/j.mulfin.2005.07.003 doi: 10.1016/j.mulfin.2005.07.003
|
| [32] |
Liang Q, Liao J, Leng L (2021) Social interactions and mutual fund portfolios: The role of alumni networks in China. China Financ Rev Int 12: 433–450. https://doi.org/10.1108/CFRI-04-2021-0073 doi: 10.1108/CFRI-04-2021-0073
|
| [33] |
Malloy C (2005) The geography of equity analysis. J Finance 60: 719–755. https://doi.org/10.1111/j.1540-6261.2005.00744.x doi: 10.1111/j.1540-6261.2005.00744.x
|
| [34] |
Mondria J, Wang X, Wu T (2021) Familiarity and surprises in international financial markets: bad news travel like wildfire, good news travels slow. J Int Money Finance 115: 1–16. https://doi.org/10.1016/j.jimonfin.2021.102390 doi: 10.1016/j.jimonfin.2021.102390
|
| [35] | MSCI (2021) MSCI China All Shares Index (USD) Factsheet (July). |
| [36] | Parshakov P (2014) Russian Mutual Funds: Skill vs. Luck. https://dx.doi.org/10.2139/ssrn.2539490 |
| [37] |
Pilbeam K, Preston H (2019) An empirical investigation of the performance of Japanese mutual funds: Skill or luck? Int J Financ Stud 7: 6. https://doi.org/10.3390/ijfs7010006 doi: 10.3390/ijfs7010006
|
| [38] |
Rao Z, Ahsan T, Tauni MZ, et al. (2018) Performance and persistence in performance of actively managed Chinese equity funds. J Quant Econ 16: 727–747. https://doi.org/10.1007/s40953-017-0104-5 doi: 10.1007/s40953-017-0104-5
|
| [39] |
Seddighi HR, Nian W (2004) The Chinese stock exchange market: operations and efficiency. Appl Financial Econ 14: 785–797. https://doi.org/10.1080/0960310042000180826 doi: 10.1080/0960310042000180826
|
| [40] |
Suh S, Hong K (2011) Control of luck in measuring investment fund performance. Asia‐Pacific J Financ Stud 40: 467–493. https://doi.org/10.1111/j.2041-6156.2011.01046.x doi: 10.1111/j.2041-6156.2011.01046.x
|
| [41] |
Titman S, Wei C, Zhao R (2021) Corporate actions and the manipulation of retail investors in China: an analysis of stock splits. J Financ Econ 145: 762–787. https://doi.org/10.1016/j.jfineco.2021.09.018 doi: 10.1016/j.jfineco.2021.09.018
|
| [42] |
Wagner M, Margaritis D (2017) All about fun(ds) in emerging markets? The case of equity mutual funds. Emerg Mark Rev 22: 62–78. https://doi.org/10.1016/j.ememar.2017.08.004 doi: 10.1016/j.ememar.2017.08.004
|
| [43] |
Yang L, Liu W (2017) Luck versus skill: Can Chinese funds beat the market? Emerg Mark Finance and Trade 53: 629–643. https://doi.org/10.1080/1540496X.2015.1097951 doi: 10.1080/1540496X.2015.1097951
|
 QFE-07-04-029-s001.pdf |
 |
| 1. | Natasha Doyle, Philiswa Mbandlwa, William J. Kelly, Graeme Attwood, Yang Li, R. Paul Ross, Catherine Stanton, Sinead Leahy, Use of Lactic Acid Bacteria to Reduce Methane Production in Ruminants, a Critical Review, 2019, 10, 1664-302X, 10.3389/fmicb.2019.02207 | |
| 2. | Raphael D. Ayivi, Rabin Gyawali, Albert Krastanov, Sulaiman O. Aljaloud, Mulumebet Worku, Reza Tahergorabi, Roberta Claro da Silva, Salam A. Ibrahim, Lactic Acid Bacteria: Food Safety and Human Health Applications, 2020, 1, 2624-862X, 202, 10.3390/dairy1030015 | |
| 3. | Simon Khelissa, Nour-Eddine Chihib, Adem Gharsallaoui, Conditions of nisin production by Lactococcus lactis subsp. lactis and its main uses as a food preservative, 2021, 203, 0302-8933, 465, 10.1007/s00203-020-02054-z | |
| 4. | Wei-Kuang Lai, Ying-Chen Lu, Chun-Ren Hsieh, Chien-Kei Wei, Yi-Hong Tsai, Fang-Rong Chang, You Chan, Developing Lactic Acid Bacteria as an Oral Healthy Food, 2021, 11, 2075-1729, 268, 10.3390/life11040268 | |
| 5. | Lobna Elleuch, Olfa Ben Salem-Berrabah, Yasmin Cherni, Besma Sghaier-Hammami, Mariam Kasmi, Cristian Botta, Ikram Ouerghi, Irene Franciosa, Luca Cocolin, Ismail Trabelsi, Abdelwaheb Chatti, A new practical approach for the biological treatment of a mixture of cheese whey and white wastewaters using Kefir grains, 2020, 27, 0944-1344, 33127, 10.1007/s11356-020-09549-8 | |
| 6. | Leah B. Bushin, Brett C. Covington, Britta E. Rued, Michael J. Federle, Mohammad R. Seyedsayamdost, Discovery and Biosynthesis of Streptosactin, a Sactipeptide with an Alternative Topology Encoded by Commensal Bacteria in the Human Microbiome, 2020, 142, 0002-7863, 16265, 10.1021/jacs.0c05546 | |
| 7. | Marknoah Chinenye Nwamba, Fubao Sun, Marie Rose Mukasekuru, Guojie Song, Jean Damascene Harindintwali, Samaila Ajeje Boyi, Haiyan Sun, Trends and hassles in the microbial production of lactic acid from lignocellulosic biomass, 2021, 21, 23521864, 101337, 10.1016/j.eti.2020.101337 | |
| 8. | Amarela Terzić-Vidojević, Katarina Veljović, Maja Tolinački, Milica Živković, Jovanka Lukić, Jelena Lozo, Đorđe Fira, Branko Jovčić, Ivana Strahinić, Jelena Begović, Nikola Popović, Marija Miljković, Milan Kojić, Ljubiša Topisirović, Nataša Golić, Diversity of non-starter lactic acid bacteria in autochthonous dairy products from Western Balkan Countries - Technological and probiotic properties, 2020, 136, 09639969, 109494, 10.1016/j.foodres.2020.109494 | |
| 9. | Elisa Salvetti, Sandra Torriani, Jinshui Zheng, Sarah Lebeer, Michael G. Gänzle, Giovanna E. Felis, 2020, 9780081005965, 10.1016/B978-0-12-818766-1.00050-7 | |
| 10. | Ana C. Mendes, Ioannis S. Chronakis, Electrohydrodynamic encapsulation of probiotics: A review, 2021, 117, 0268005X, 106688, 10.1016/j.foodhyd.2021.106688 | |
| 11. | Larissa Cardoso Silva, Heitor de Souza Lago, Márcia Oliveira Terra Rocha, Vanessa Sales de Oliveira, Roberto Laureano-Melo, Evandro Toledo Gerhardt Stutz, Breno Pereira de Paula, José Francisco Pereira Martins, Rosa Helena Luchese, André Fioravante Guerra, Paula Rodrigues, Craft Beers Fermented by Potential Probiotic Yeast or Lacticaseibacilli Strains Promote Antidepressant-Like Behavior in Swiss Webster Mice, 2021, 1867-1306, 10.1007/s12602-020-09736-6 | |
| 12. | Baltasar Mayo, Javier Rodríguez, Lucía Vázquez, Ana Belén Flórez, Microbial Interactions within the Cheese Ecosystem and Their Application to Improve Quality and Safety, 2021, 10, 2304-8158, 602, 10.3390/foods10030602 | |
| 13. | Sungmin Jung, Chaerin Woo, Joanna Ivy Irorita Fugaban, Jorge Enrique Vazquez Bucheli, Wilhelm Heinrich Holzapfel, Svetoslav Dimitrov Todorov, Bacteriocinogenic Potential of Bacillus amyloliquefaciens Isolated from Kimchi, a Traditional Korean Fermented Cabbage, 2021, 1867-1306, 10.1007/s12602-021-09772-w | |
| 14. | Hoda S. El-Sayed, Heba H. Salama, Amr E. Edris, Survival of Lactobacillus helveticus CNRZ32 in spray dried functional yogurt powder during processing and storage, 2020, 19, 1658077X, 461, 10.1016/j.jssas.2020.08.003 | |
| 15. | Justina Mileriene, Loreta Serniene, Kristina Kondrotiene, Lina Lauciene, Vaida Andruleviciute, Neringa Kasetiene, Dalia Sekmokiene, Mindaugas Malakauskas, Effect of Indigenous Lactococcus lactis on physicochemical and sensory properties of thermo‐coagulated acid whey protein , 2021, 0145-8892, 10.1111/jfpp.15420 | |
| 16. | Guangqiang Wang, Pengyu Chen, Xiaoqing Yu, Yongjun Xia, Li-Tang Yan, Lianzhong Ai, C18:1 Improves the Freeze-Drying Resistance of Lactobacillus plantarum by Maintaining the Cell Membrane, 2020, 3, 2576-6422, 4933, 10.1021/acsabm.0c00444 | |
| 17. | Tiara Padayachee, Nomfundo Nzuza, Wanping Chen, David R. Nelson, Khajamohiddin Syed, Impact of lifestyle on cytochrome P450 monooxygenase repertoire is clearly evident in the bacterial phylum Firmicutes, 2020, 10, 2045-2322, 10.1038/s41598-020-70686-8 | |
| 18. | Maria Carolina Mesquita, Eliana dos Santos Leandro, Ernandes Rodrigues de Alencar, Raquel Braz Assunção Botelho, Fermentation of chickpea (Cicer arietinum L.) and coconut (Coccus nucifera L.) beverages by Lactobacillus paracasei subsp paracasei LBC 81: The influence of sugar content on growth and stability during storage, 2020, 132, 00236438, 109834, 10.1016/j.lwt.2020.109834 | |
| 19. | Gacem Mohamed Amine, Hiba Gacem, Djoudi Boukerouis, Joachim Wink, 2021, 9780128219102, 361, 10.1016/B978-0-12-821910-2.00027-8 | |
| 20. | Nikola Popović, Emilija Brdarić, Jelena Đokić, Miroslav Dinić, Katarina Veljović, Nataša Golić, Amarela Terzić-Vidojević, Yogurt Produced by Novel Natural Starter Cultures Improves Gut Epithelial Barrier In Vitro, 2020, 8, 2076-2607, 1586, 10.3390/microorganisms8101586 | |
| 21. | An Borremans, Ruben Smets, Leen Van Campenhout, Fermentation Versus Meat Preservatives to Extend the Shelf Life of Mealworm (Tenebrio molitor) Paste for Feed and Food Applications, 2020, 11, 1664-302X, 10.3389/fmicb.2020.01510 | |
| 22. | Erica Kosmerl, Diana Rocha-Mendoza, Joana Ortega-Anaya, Rafael Jiménez-Flores, Israel García-Cano, Improving Human Health with Milk Fat Globule Membrane, Lactic Acid Bacteria, and Bifidobacteria, 2021, 9, 2076-2607, 341, 10.3390/microorganisms9020341 | |
| 23. | Oktay YERLIKAYA, Derya SAYGILI, Asli AKPINAR, Evaluation of antimicrobial activity and antibiotic susceptibility profiles of Lactobacillus delbrueckii subsp. bulgaricus and Streptococcus thermophilus strains isolated from commercial yoghurt starter cultures, 2020, 1678-457X, 10.1590/fst.03920 | |
| 24. | Mahmoud S.M. Mohamed, Fouad M.F. Elshaghabee, Sulaiman Ali Alharbi, Ahmed El-Hussein, The Prospective Beneficial Effects of Red Laser Exposure on Lactocaseibacillus casei Fermentation of Skim Milk, 2020, 9, 2079-7737, 256, 10.3390/biology9090256 | |
| 25. | Ge Zhao, Jianming Liu, Jie Zhao, Robin Dorau, Peter Ruhdal Jensen, Christian Solem, Efficient Production of Nisin A from Low-Value Dairy Side Streams Using a Nonengineered Dairy Lactococcus lactis Strain with Low Lactate Dehydrogenase Activity, 2021, 69, 0021-8561, 2826, 10.1021/acs.jafc.0c07816 | |
| 26. | Tengku Haziyamin TENGKU ABDUL HAMİD, Nur FATİN AMYSYA, LACTIC ACID BACTERIUM WITH ANTIMICROBIAL PROPERTIES FROM SELECTED MALAY TRADITIONAL FERMENTED FOODS, 2020, 2651-4621, 10.38001/ijlsb.781522 | |
| 27. | Justina Mileriene, Loreta Serniene, Marta Henriques, David Gomes, Carlos Pereira, Kristina Kondrotiene, Neringa Kasetiene, Lina Lauciene, Dalia Sekmokiene, Mindaugas Malakauskas, Effect of liquid whey protein concentrate–based edible coating enriched with cinnamon carbon dioxide extract on the quality and shelf life of Eastern European curd cheese, 2021, 104, 00220302, 1504, 10.3168/jds.2020-18732 | |
| 28. | Gyu-Sung Cho, Olakunle Fagbemigun, Erik Brinks, Gbenga A. Adewumi, Folarin A. Oguntoyinbo, Charles M. A. P. Franz, David Rasko, Draft Genome Sequences of Lactobacillus helveticus, Lactobacillus fermentum, and Lactobacillus delbrueckii Strains from African Fermented Nono, 2020, 9, 2576-098X, 10.1128/MRA.01342-19 | |
| 29. | Jhonatan A. Hernandez-Valdes, Ana Solopova, Oscar P. Kuipers, Development of Lactococcus lactis Biosensors for Detection of Diacetyl, 2020, 11, 1664-302X, 10.3389/fmicb.2020.01032 | |
| 30. | Aneta Ciosek, Katarzyna Fulara, Olga Hrabia, Paweł Satora, Aleksander Poreda, Chemical Composition of Sour Beer Resulting from Supplementation the Fermentation Medium with Magnesium and Zinc Ions, 2020, 10, 2218-273X, 1599, 10.3390/biom10121599 | |
| 31. | LUÍS AUGUSTO NERO, CAIO FIALHO de FREITAS, LARA MARIA VIEIRA FLORES CARVALHO, CRISTINA CONSTANTINO, 3M Petrifilm Lactic Acid Bacteria Count Plate Is a Reliable Tool for Enumerating Lactic Acid Bacteria in Bacon, 2020, 83, 0362-028X, 1757, 10.4315/JFP-20-155 | |
| 32. | Adriana Criste, Lucian Copolovici, Dana Copolovici, Melinda Kovacs, Robert H. Madden, Nicolae Corcionivoschi, Ozan Gundogdu, Mihaela Berchez, Adriana Cristina Urcan, Jasbir Singh Bedi, Determination of changes in the microbial and chemical composition of Țaga cheese during maturation, 2020, 15, 1932-6203, e0242824, 10.1371/journal.pone.0242824 | |
| 33. | Alex MacLean, Anondo Bley, Vasu D. Appanna, 2021, 9780128200841, 101, 10.1016/B978-0-12-820084-1.00005-3 | |
| 34. | María del Pilar Angarita-Díaz, Johanna C. Arias, Claudia Bedoya-Correa, María J. Cepeda, María F. Arboleda, Juan M. Chacón, Yenny Leal, The effect of commercial functional food with probiotics on microorganisms from early carious lesions, 2020, 10, 2045-2322, 10.1038/s41598-020-67775-z | |
| 35. | Cécile Philippe, Amel Chaïb, Fety Jaomanjaka, Olivier Claisse, Patrick M. Lucas, Johan Samot, Christian Cambillau, Claire Le Marrec, Characterization of the First Virulent Phage Infecting Oenococcus oeni, the Queen of the Cellars, 2021, 11, 1664-302X, 10.3389/fmicb.2020.596541 | |
| 36. | Carla Martín, Iván Fernández-Vega, Juan E. Suárez, Luis M. Quirós, Adherence of Lactobacillus salivarius to HeLa Cells Promotes Changes in the Expression of the Genes Involved in Biosynthesis of Their Ligands, 2020, 10, 1664-3224, 10.3389/fimmu.2019.03019 | |
| 37. | Ranjana Sharma, Prakrati Garg, Pradeep Kumar, Shashi Kant Bhatia, Saurabh Kulshrestha, Microbial Fermentation and Its Role in Quality Improvement of Fermented Foods, 2020, 6, 2311-5637, 106, 10.3390/fermentation6040106 | |
| 38. | Larissa P. Margalho, Marcelo D'Elia Feliciano, Christian E. Silva, Júlia S. Abreu, Marcos Vinícius Fiorentini Piran, Anderson S. Sant'Ana, Brazilian artisanal cheeses are rich and diverse sources of nonstarter lactic acid bacteria regarding technological, biopreservative, and safety properties—Insights through multivariate analysis, 2020, 103, 00220302, 7908, 10.3168/jds.2020-18194 | |
| 39. | Kaidi Peng, Mohamed Koubaa, Olivier Bals, Eugène Vorobiev, Effect of Pulsed Electric Fields on the Growth and Acidification Kinetics of Lactobacillus delbrueckii Subsp. bulgaricus, 2020, 9, 2304-8158, 1146, 10.3390/foods9091146 | |
| 40. | Yingying Hu, Lang Zhang, Rongxin Wen, Qian Chen, Baohua Kong, Role of lactic acid bacteria in flavor development in traditional Chinese fermented foods: A review, 2020, 1040-8398, 1, 10.1080/10408398.2020.1858269 | |
| 41. | Hyun-Wook Baek, Seul-Ah Kim, Won-Ki Min, Shin Dal Kang, Sangmin Shim, Nam Soo Han, Jin-Ho Seo, A Species-Specific qPCR Method for Enumeration of Lactobacillus sanfranciscensis, Lactobacillus brevis, and Lactobacillus curvatus During Cocultivation in Sourdough, 2021, 14, 1936-9751, 750, 10.1007/s12161-020-01920-2 | |
| 42. | María Jesús Rodríguez-Sojo, Antonio Jesús Ruiz-Malagón, María Elena Rodríguez-Cabezas, Julio Gálvez, Alba Rodríguez-Nogales, Limosilactobacillus fermentum CECT5716: Mechanisms and Therapeutic Insights, 2021, 13, 2072-6643, 1016, 10.3390/nu13031016 | |
| 43. | Sepideh Gharehyakheh, Gamma aminobutyric acid (GABA) production using Lactobacillus sp. Makhdzir Naser‐1 (GQ451633) in the cherry‐kefir beverage , 2021, 0145-8892, 10.1111/jfpp.15521 | |
| 44. | Nasim Khorshidian, Mojtaba Yousefi, Neda Mollakhalili Meybodi, Amir M. Mortazavian, 2021, 9780128185889, 259, 10.1016/B978-0-12-818588-9.00018-8 | |
| 45. | S.C. Ribeiro, M.C. Coelho, C.C.G. Silva, A rapid screening method to evaluate acidifying activity by lactic acid bacteria, 2021, 185, 01677012, 106227, 10.1016/j.mimet.2021.106227 | |
| 46. | Edwin Hlangwani, Patrick Berka Njobeh, Chiemela Enyinnaya Chinma, Ajibola Bamikole Oyedeji, Beatrice Mofoluwaso Fasogbon, Samson Adeoye Oyeyinka, Sunday Samuel Sobowale, Olayemi Eyituoyo Dudu, Tumisi Beiri Jeremiah Molelekoa, Hema Kesa, Jonathan D. Wilkin, Oluwafemi Ayodeji Adebo, 2023, 9780323983419, 15, 10.1016/B978-0-323-98341-9.00031-1 | |
| 47. | Ilias Apostolakos, Spiros Paramithiotis, Marios Mataragas, Functional and Safety Characterization of Weissella paramesenteroides Strains Isolated from Dairy Products through Whole-Genome Sequencing and Comparative Genomics, 2022, 3, 2624-862X, 799, 10.3390/dairy3040055 | |
| 48. | Heng Li, Nancy E. Ramia, Frédéric Borges, Anne-Marie Revol-Junelles, Finn Kvist Vogensen, Jørgen J. Leisner, Identification of Potential Citrate Metabolism Pathways in Carnobacterium maltaromaticum, 2021, 9, 2076-2607, 2169, 10.3390/microorganisms9102169 | |
| 49. | Asli Akpinar, Oktay Yerlikaya, Some potential beneficial properties of Lacticaseibacillus paracasei subsp. paracasei and Leuconostoc mesenteroides strains originating from raw milk and kefir grains , 2021, 45, 0145-8892, 10.1111/jfpp.15986 | |
| 50. | Gabriele Rocchetti, Annalisa Rebecchi, Michele Dallolio, Gianpaolo Braceschi, Rubén Domínguez, Giuliano Dallolio, Marco Trevisan, José M. Lorenzo, Luigi Lucini, Changes in the chemical and sensory profile of ripened Italian salami following the addition of different microbial starters, 2021, 180, 03091740, 108584, 10.1016/j.meatsci.2021.108584 | |
| 51. | Abel T. Ingle, Nathaniel W. Fortney, Kevin A. Walters, Timothy J. Donohue, Daniel R. Noguera, Mixed Acid Fermentation of Carbohydrate-Rich Dairy Manure Hydrolysate, 2021, 9, 2296-4185, 10.3389/fbioe.2021.724304 | |
| 52. | Konstantin V. Moiseenko, Anna V. Begunova, Olga S. Savinova, Olga A. Glazunova, Irina V. Rozhkova, Tatyana V. Fedorova, Biochemical and Genomic Characterization of Two New Strains of Lacticaseibacillus paracasei Isolated from the Traditional Corn-Based Beverage of South Africa, Mahewu, and Their Comparison with Strains Isolated from Kefir Grains, 2023, 12, 2304-8158, 223, 10.3390/foods12010223 | |
| 53. | Harpreet Kaur, Gurjeet Kaur, Syed Azmal Ali, Dairy-Based Probiotic-Fermented Functional Foods: An Update on Their Health-Promoting Properties, 2022, 8, 2311-5637, 425, 10.3390/fermentation8090425 | |
| 54. | Ricardo V. Duarte, Carlos A. Pinto, Ana M. Gomes, Ivonne Delgadillo, Jorge A. Saraiva, A microbiological perspective of raw milk preserved at room temperature using hyperbaric storage compared to refrigerated storage, 2022, 78, 14668564, 103019, 10.1016/j.ifset.2022.103019 | |
| 55. | Charles Obinwanne Okoye, Ke Dong, Yongli Wang, Lu Gao, Xia Li, Yanfang Wu, Jianxiong Jiang, Comparative genomics reveals the organic acid biosynthesis metabolic pathways among five lactic acid bacterial species isolated from fermented vegetables, 2022, 70, 18716784, 73, 10.1016/j.nbt.2022.05.001 | |
| 56. | Jiangli Wu, Wenkang Hu, Yongde Zeng, Zhengbin Yang, xuefeng zeng, Effect of Flours Addition on the Physicochemical and Metabolome in Suanjiang, a Chinese Traditional Fermentation Coagulant, 2023, 1556-5068, 10.2139/ssrn.4350082 | |
| 57. | S. H. Sandez Penidez, M. A. Velasco Manini, C. L. Gerez, G. C. Rollan, Consortia of lactic acid bacteria strains increase the antioxidant activity and bioactive compounds of quinoa sourdough - based biscuits, 2023, 39, 0959-3993, 10.1007/s11274-023-03538-y | |
| 58. | Sargun Malik, Kiruba Krishnaswamy, Azlin Mustapha, Development and functional characterization of complementary food using kodo and proso millet with acid whey from Greek yogurt processing, 2022, 46, 0145-8892, 10.1111/jfpp.16051 | |
| 59. | Rania Anastasiou, Maria Kazou, Marina Georgalaki, Anastasios Aktypis, Georgia Zoumpopoulou, Effie Tsakalidou, Omics Approaches to Assess Flavor Development in Cheese, 2022, 11, 2304-8158, 188, 10.3390/foods11020188 | |
| 60. | Alessandro Bianchi, Isabella Taglieri, Francesca Venturi, Chiara Sanmartin, Giuseppe Ferroni, Monica Macaluso, Fabrizio Palla, Guido Flamini, Angela Zinnai, Technological Improvements on FML in the Chianti Classico Wine Production: Co-Inoculation or Sequential Inoculation?, 2022, 11, 2304-8158, 1011, 10.3390/foods11071011 | |
| 61. | Elena Nikitina, Tatyana Petrova, Adel Vafina, Asya Ezhkova, Monyr Nait Yahia, Airat Kayumov, Textural and Functional Properties of Skimmed and Whole Milk Fermented by Novel Lactiplantibacillus plantarum AG10 Strain Isolated from Silage, 2022, 8, 2311-5637, 290, 10.3390/fermentation8060290 | |
| 62. | Yuwei Sun, Shiyao Zhang, Hong Li, Jiang Zhu, Zhijia Liu, Xiaosong Hu, Junjie Yi, Assessments of Probiotic Potentials of Lactiplantibacillus plantarum Strains Isolated From Chinese Traditional Fermented Food: Phenotypic and Genomic Analysis, 2022, 13, 1664-302X, 10.3389/fmicb.2022.895132 | |
| 63. | Esther Alonso García, Juan José de la Fuente Ordoñez, Leyre Lavilla Lerma, María D. Estudillo-Martínez, Sonia Castillo-Gutiérrez, Nabil Benomar, Charles W. Knapp, Hikmate Abriouel, Transcriptomic Profile and Probiotic Properties of Lactiplantibacillus pentosus Pre-adapted to Edible Oils, 2021, 12, 1664-302X, 10.3389/fmicb.2021.747043 | |
| 64. | Pooja Attri, Drukshakshi Jodha, Poonam Bansal, Jasbir Singh, Suman Dhanda, Membrane Bound Aminopeptidase B of a Potential Probiotic Pediococcus acidilactici NCDC 252: Purification, Physicochemical and Kinetic Characterization, 2021, 27, 1573-3149, 1641, 10.1007/s10989-021-10197-w | |
| 65. | Wanida Pan-utai, Sitanan Thitiprasert, Soisuda Pornpukdeewattana, Arthrospira Cell Residues for Lactic Acid Fermentation as Bioproducts From Waste Utilization, 2022, 10, 2296-598X, 10.3389/fenrg.2022.878597 | |
| 66. | Raquel Muelas, Gema Romero, José Ramón Díaz, Paula Monllor, Juana Fernández-López, Manuel Viuda-Martos, Marina Cano-Lamadrid, Esther Sendra, Quality and Functional Parameters of Fermented Milk Obtained from Goat Milk Fed with Broccoli and Artichoke Plant By-Products, 2022, 11, 2304-8158, 2601, 10.3390/foods11172601 | |
| 67. | Jheng-Jhe Lu, Meng-Chun Cheng, Darin Khumsupan, Chen-Che Hsieh, Chang-Wei Hsieh, Kuan-Chen Cheng, Evaluation of Fermented Turmeric Milk by Lactic Acid Bacteria to Prevent UV-Induced Oxidative Stress in Human Fibroblast Cells, 2023, 9, 2311-5637, 230, 10.3390/fermentation9030230 | |
| 68. | Yu Hsuan How, Michelle Yee Mun Teo, Lionel Lian Aun In, Siok Koon Yeo, Liew Phing Pui, Development of fermented milk using food-grade recombinant Lactococcus lactis NZ3900, 2022, 28, 23523646, 1, 10.1016/j.nfs.2022.07.001 | |
| 69. | Joaquín Estrada-García, Eduardo Hernández-Aguilar, Diana I. Romero-Mota, Juan M. Méndez-Contreras, Influence of anaerobic biotransformation process of agro-industrial waste with Lactobacillus acidophilus on the rheological parameters: case of study of pig manure, 2023, 205, 0302-8933, 10.1007/s00203-023-03437-8 | |
| 70. | Wending Chen, Caiyun Xie, Qianqian He, Jianxia Sun, Weibin Bai, Improvement in color expression and antioxidant activity of strawberry juice fermented with lactic acid bacteria: A phenolic-based research, 2023, 17, 25901575, 100535, 10.1016/j.fochx.2022.100535 | |
| 71. | Muhammad Junaid, Saima Inayat, Nabila Gulzar, Anjum Khalique, Faisal Shahzad, Irfan Irshad, Muhammad Imran, Physical, chemical, microbial, and sensory evaluation and fatty acid profiling of value-added drinking yogurt (laban) under various storage conditions, 2023, 106, 00220302, 39, 10.3168/jds.2022-22358 | |
| 72. | Hassan Zafar, Milton H. Saier Jr., Comparative Analyses of the Transport Proteins Encoded within the Genomes of nine Bifidobacterium Species, 2022, 32, 2673-1665, 30, 10.1159/000518954 | |
| 73. | Sang-Hee Lee, Ah-Ram Han, Byoung-Mok Kim, Mi Sung, Sun-Mee Hong, Lactococcus lactis‑fermented spinach juice suppresses LPS‑induced expression of adhesion molecules and inflammatory cytokines through the NF‑κB pathway in HUVECs, 2022, 23, 1792-0981, 10.3892/etm.2022.11317 | |
| 74. | Elena Bartkiene, Romas Gruzauskas, Modestas Ruzauskas, Egle Zokaityte, Vytaute Starkute, Dovile Klupsaite, Laurynas Vadopalas, Sarunas Badaras, Fatih Özogul, Changes in the Microbial Community and Biogenic Amine Content in Rapeseed Meal during Fermentation with an Antimicrobial Combination of Lactic Acid Bacteria Strains, 2022, 8, 2311-5637, 136, 10.3390/fermentation8040136 | |
| 75. | Ho Myeong Kim, Seul-Gi Jeong, In Min Hwang, Hae Woong Park, Efficient Citrus (Citrus unshiu) Byproduct Extract-Based Approach forLactobacillus sakeiWiKim31 Shelf-Life Extension, 2021, 6, 2470-1343, 35334, 10.1021/acsomega.1c04335 | |
| 76. | U Suryadi, R T Hertamawati, S Imam, Fermented meat and digestive tract of snail as amino acid supplements for functional feed of native chickens, 2022, 980, 1755-1307, 012020, 10.1088/1755-1315/980/1/012020 | |
| 77. | Guangqiang Wei, Qiong Zhao, Yanan Shi, Aixiang Huang, Characteristic flavour compounds and formation of Chinese Rubing cheese: Comparative study between two different acidification technologies, 2022, 75, 1364-727X, 405, 10.1111/1471-0307.12851 | |
| 78. | Sadia Ahmed, Fatima Ashraf, Muhammad Tariq, Arsalan Zaidi, Aggrandizement of fermented cucumber through the action of autochthonous probiotic cum starter strains of Lactiplantibacillus plantarum and Pediococcus pentosaceus, 2021, 71, 1590-4261, 10.1186/s13213-021-01645-5 | |
| 79. | Alexandre J.K. Ouamba, Mérilie Gagnon, Gisèle LaPointe, P. Yvan Chouinard, Denis Roy, Graduate Student Literature Review: Farm management practices: Potential microbial sources that determine the microbiota of raw bovine milk, 2022, 105, 00220302, 7276, 10.3168/jds.2021-21758 | |
| 80. | Anna Łepecka, Anna Okoń, Piotr Szymański, Dorota Zielińska, Katarzyna Kajak-Siemaszko, Danuta Jaworska, Katarzyna Neffe-Skocińska, Barbara Sionek, Monika Trząskowska, Danuta Kołożyn-Krajewska, Zbigniew J. Dolatowski, The Use of Unique, Environmental Lactic Acid Bacteria Strains in the Traditional Production of Organic Cheeses from Unpasteurized Cow’s Milk, 2022, 27, 1420-3049, 1097, 10.3390/molecules27031097 | |
| 81. | Sneh Punia Bangar, Shweta Suri, Monica Trif, Fatih Ozogul, Organic acids production from lactic acid bacteria: A preservation approach, 2022, 46, 22124292, 101615, 10.1016/j.fbio.2022.101615 | |
| 82. | Agne Vasiliauskaite, Justina Mileriene, Epp Songisepp, Ida Rud, Sandra Muizniece-Brasava, Inga Ciprovica, Lars Axelsson, Liis Lutter, Elvidas Aleksandrovas, Ene Tammsaar, Joana Salomskiene, Loreta Serniene, Mindaugas Malakauskas, Application of Edible Coating Based on Liquid Acid Whey Protein Concentrate with Indigenous Lactobacillus helveticus for Acid-Curd Cheese Quality Improvement, 2022, 11, 2304-8158, 3353, 10.3390/foods11213353 | |
| 83. | Felix Shih-Hsiang Hsiao, Clara Ajeng Artdita, Shih-Yao Lin, Yu-Hsiang Yu, Yeong-Hsiang Cheng, Mixed Solid-State Fermentation of Okara and Copra Meal by Probiotics with Non-Starch Polysaccharide Enzymes and Its Effects on the Growth Performance and Ileal Microbiota in Broilers, 2022, 8, 2311-5637, 478, 10.3390/fermentation8100478 | |
| 84. | MaryClaire Chamberlain, Sarah O'Flaherty, Natalia Cobián, Rodolphe Barrangou, Metabolomic Analysis of Lactobacillus acidophilus, L. gasseri, L. crispatus, and Lacticaseibacillus rhamnosus Strains in the Presence of Pomegranate Extract, 2022, 13, 1664-302X, 10.3389/fmicb.2022.863228 | |
| 85. | Ann L. Power, Daniel G. Barber, Sophie R. M. Groenhof, Sariqa Wagley, Ping Liu, David A. Parker, John Love, The Application of Imaging Flow Cytometry for Characterisation and Quantification of Bacterial Phenotypes, 2021, 11, 2235-2988, 10.3389/fcimb.2021.716592 | |
| 86. | Lucía Vázquez, Ana Belén Flórez, Javier Rodríguez, Baltasar Mayo, Heterologous expression of equol biosynthesis genes from Adlercreutzia equolifaciens , 2021, 368, 1574-6968, 10.1093/femsle/fnab082 | |
| 87. | Hsean Ren Loi, Sahar Abbasiliasi, Pandian Bothi Raja, Mohd Shamzi Mohamed, Wen-Nee Tan, Hui Suan Ng, John Chi-Wei Lan, Joo Shun Tan, Biosynthesis of silver nanoparticles using nitrate reductase produced by Lactobacillus plantarum CAM 4: Characterization and in vitro evaluation of its antimicrobial efficiency, 2023, 376, 01677322, 121476, 10.1016/j.molliq.2023.121476 | |
| 88. | Kritika Sharma, Sarita Bhawanani, Deepak Sharma, Gunjan Goel, Selection of indigenous Lacticaseibacillus paracasei CD 4 for production of gluten-free traditional fermented product Bhaturu, 2022, 36, 0890-5436, 76, 10.1080/08905436.2021.2007395 | |
| 89. | Sara Tejedor-Sanz, Eric T Stevens, Siliang Li, Peter Finnegan, James Nelson, Andre Knoesen, Samuel H Light, Caroline M Ajo-Franklin, Maria L Marco, Extracellular electron transfer increases fermentation in lactic acid bacteria via a hybrid metabolism, 2022, 11, 2050-084X, 10.7554/eLife.70684 | |
| 90. | Aicha Yasmine Belarbi, Otávio G. G. de Almeida, Veronica Gatto, Sandra Torriani, Beatriz del Rio, Victor Ladero, Begoña Redruello, Farid Bensalah, Miguel A. Alvarez, Investigating the biotechnological potential of lactic acid bacteria strains isolated from different Algerian dairy and farm sources, 2022, 204, 0302-8933, 10.1007/s00203-022-02828-7 | |
| 91. | Mohammadhassan Gholami-Shabani, Masoomeh Shams-Ghahfarokhi, Mehdi Razzaghi-Abyaneh, 2023, 10.5772/intechopen.109729 | |
| 92. | Irene Martín, Alicia Rodríguez, Josué Delgado, Juan J. Córdoba, Strategies for Biocontrol of Listeria monocytogenes Using Lactic Acid Bacteria and Their Metabolites in Ready-to-Eat Meat- and Dairy-Ripened Products, 2022, 11, 2304-8158, 542, 10.3390/foods11040542 | |
| 93. | Santosh Kumar Tiwari, Bacteriocin-Producing Probiotic Lactic Acid Bacteria in Controlling Dysbiosis of the Gut Microbiota, 2022, 12, 2235-2988, 10.3389/fcimb.2022.851140 | |
| 94. | Katarzyna Petka, Paweł Sroka, Tomasz Tarko, Aleksandra Duda-Chodak, The Acrylamide Degradation by Probiotic Strain Lactobacillus acidophilus LA-5, 2022, 11, 2304-8158, 365, 10.3390/foods11030365 | |
| 95. | Ahmed Adebisi Otunba, Akinniyi Adediran Osuntoki, Wahab Okunowo, Daniel Kolawole Olukoya, Benjamin Ayodipupo Babalola, Characterization of novel bacteriocin PB2 and comprehensive detection of the pediocin gene ped-A1 from Pediococcus pentosaceus PB2 strain isolated from a sorghum-based fermented beverage in Nigeria, 2022, 36, 2215017X, e00772, 10.1016/j.btre.2022.e00772 | |
| 96. | Mónica María Durango-Zuleta, Mayra Fuentes-Vanegas, José Uriel Sepúlveda-Valencia, Claudia Ximena Moreno Herrera, Isolation, identification, and antimicrobial activity of lactic acid bacteria associated with two traditional Colombian types of cheese: Quesillo and double-cream cheese, 2022, 171, 00236438, 114119, 10.1016/j.lwt.2022.114119 | |
| 97. | Xianqi Peng, Abdelaziz Ed-Dra, Min Yue, Whole genome sequencing for the risk assessment of probiotic lactic acid bacteria, 2022, 1040-8398, 1, 10.1080/10408398.2022.2087174 | |
| 98. | Seda Hacıoglu, Buket Kunduhoglu, Probiotic Characteristics of Lactobacillus brevis KT38-3 Isolated from an Artisanal Tulum Cheese, 2021, 41, 2636-0772, 967, 10.5851/kosfa.2021.e49 | |
| 99. | J.I.I. Fugaban, J.E. Vazquez Bucheli, B. Kim, W.H. Holzapfel, S.D. Todorov, Safety and beneficial properties of bacteriocinogenic Pediococcus acidilactici and Pediococcus pentosaceus isolated from silage , 2021, 73, 0266-8254, 725, 10.1111/lam.13562 | |
| 100. | Oluwole Steve Ijarotimi, Opeyemi Rachael Fagoroye, Timilehin David Oluwajuyitan, Jute seed bioactive compounds: amino acids, polyphenolics, antioxidants and hydrolyzing enzymes inhibitory property, 2023, 3, 27725669, 183, 10.1016/j.jfutfo.2022.12.010 | |
| 101. | Elena Bartkiene, Egle Zokaityte, Vytaute Starkute, Ernestas Mockus, Dovile Klupsaite, Justina Lukseviciute, Alina Bogomolova, Audrone Streimikyte, Fatih Ozogul, Biopreservation of Wild Edible Mushrooms (Boletus edulis, Cantharellus, and Rozites caperata) with Lactic Acid Bacteria Possessing Antimicrobial Properties, 2022, 11, 2304-8158, 1800, 10.3390/foods11121800 | |
| 102. | Amélia Delgado, Nadia Chammem, Manel Issaoui, Emna Ammar, 2022, Chapter 10-1, 978-3-030-63961-7, 1, 10.1007/978-3-030-63961-7_10-1 | |
| 103. | Haritha Meruvu, Sebnem Tellioglu Harsa, Lactic acid bacteria: isolation–characterization approaches and industrial applications, 2022, 1040-8398, 1, 10.1080/10408398.2022.2054936 | |
| 104. | Urszula Zarzecka, Anna Zadernowska, Wioleta Chajęcka-Wierzchowska, Patryk Adamski, High-pressure processing effect on conjugal antibiotic resistance genes transfer in vitro and in the food matrix among strains from starter cultures, 2023, 388, 01681605, 110104, 10.1016/j.ijfoodmicro.2023.110104 | |
| 105. | Sawsen Hadef, Tayeb Idoui, Mohamed Sifour, Magali Genay, Annie Dary-Mourot, Screening of Wild Lactic Acid Bacteria from Algerian Traditional Cheeses and Goat Butter to Develop a New Probiotic Starter Culture, 2022, 1867-1306, 10.1007/s12602-022-10000-2 | |
| 106. | Dipanwita Bhattacharya, Pramod Kumar Nanda, Mirian Pateiro, José M. Lorenzo, Pubali Dhar, Arun K. Das, Lactic Acid Bacteria and Bacteriocins: Novel Biotechnological Approach for Biopreservation of Meat and Meat Products, 2022, 10, 2076-2607, 2058, 10.3390/microorganisms10102058 | |
| 107. | Aileen Pua, Vivien Chia Yen Tang, Rui Min Vivian Goh, Jingcan Sun, Benjamin Lassabliere, Shao Quan Liu, Ingredients, Processing, and Fermentation: Addressing the Organoleptic Boundaries of Plant-Based Dairy Analogues, 2022, 11, 2304-8158, 875, 10.3390/foods11060875 | |
| 108. | Wuyundalai Bao, Yuxing He, Jinghe Yu, Xiaofeng Yang, Mingchao Liu, Rimutu Ji, Diversity analysis and gene function prediction of bacteria and fungi of Bactrian camel milk and naturally fermented camel milk from Alxa in Inner Mongolia, 2022, 169, 00236438, 114001, 10.1016/j.lwt.2022.114001 | |
| 109. | Dorota Zielińska, Katarzyna Marciniak-Lukasiak, Marcelina Karbowiak, Piotr Lukasiak, Effects of Fructose and Oligofructose Addition on Milk Fermentation Using Novel Lactobacillus Cultures to Obtain High-Quality Yogurt-like Products, 2021, 26, 1420-3049, 5730, 10.3390/molecules26195730 | |
| 110. | Melda ONUR, Harun ÖNLÜ, Farklı Gıda Ürünlerinden İzole Edilen Laktik Asit Bakterilerinin Bazı Probiyotik Özelliklerinin Belirlenmesi, 2022, 2148-2683, 10.31590/ejosat.1041277 | |
| 111. | Xiaojie Zhou, Zhiqi Liu, Le Xie, Liangyi Li, Wenhua Zhou, Liangzhong Zhao, The Correlation Mechanism between Dominant Bacteria and Primary Metabolites during Fermentation of Red Sour Soup, 2022, 11, 2304-8158, 341, 10.3390/foods11030341 | |
| 112. | Chrysa Anagnostopoulou, Konstantinos N. Kontogiannopoulos, Maria Gaspari, Maria Silvia Morlino, Andreana N. Assimopoulou, Panagiotis G. Kougias, Valorization of household food wastes to lactic acid production: A response surface methodology approach to optimize fermentation process, 2022, 296, 00456535, 133871, 10.1016/j.chemosphere.2022.133871 | |
| 113. | Birsen Yilmaz, Sneh Punia Bangar, Noemi Echegaray, Shweta Suri, Igor Tomasevic, Jose Manuel Lorenzo, Ebru Melekoglu, João Miguel Rocha, Fatih Ozogul, The Impacts of Lactiplantibacillus plantarum on the Functional Properties of Fermented Foods: A Review of Current Knowledge, 2022, 10, 2076-2607, 826, 10.3390/microorganisms10040826 | |
| 114. | Caroline Isabel Kothe, Nacer Mohellibi, Pierre Renault, Revealing the microbial heritage of traditional Brazilian cheeses through metagenomics, 2022, 157, 09639969, 111265, 10.1016/j.foodres.2022.111265 | |
| 115. | Pallabi Banerjee, Imteyaz Qamar, 2022, 9780323857932, 93, 10.1016/B978-0-323-85793-2.00002-3 | |
| 116. | Ronit Suissa, Rela Oved, Harsh Maan, Uzi Hadad, Omri Gilhar, Michael M. Meijler, Omry Koren, Ilana Kolodkin-Gal, Context-dependent differences in the functional responses of Lactobacillaceae strains to fermentable sugars, 2022, 13, 1664-302X, 10.3389/fmicb.2022.949932 | |
| 117. | Ana Belén Flórez, Lucía Vázquez, Javier Rodríguez, Baltasar Mayo, Phenotypic and Safety Assessment of the Cheese Strain Lactiplantibacillus plantarum LL441, and Sequence Analysis of its Complete Genome and Plasmidome, 2022, 24, 1422-0067, 605, 10.3390/ijms24010605 | |
| 118. | Luís Cláudio Lima de Jesus, Tales Fernando da Silva, Rafael de Assis Glória, Andria dos Santos Freitas, Monique Ferrary Américo, Lucas Jorge da Silva Fernandes, Gabriela Munis Campos, Gabriel Camargos Gomes, Rhayane Cristina Viegas Santos, Rodrigo Dias de Oliveira Carvalho, Debmalya Barh, Vasco Azevedo, 2022, 9780128222386, 373, 10.1016/B978-0-12-822238-6.00008-X | |
| 119. | Dayanidhi Satish Kumar, Palanisamy Venkatachalam, Probing of an Appreciable Antimicrobial Compound Producing Lactobacillus Strain from Milk Products of Thanjavur Region, Tamil Nadu and its Enhanced Production, 2022, 19, 24562602, 917, 10.13005/bbra/3041 | |
| 120. | Fanny Canon, Marie-Bernadette Maillard, Marie-Hélène Famelart, Anne Thierry, Valérie Gagnaire, Mixed dairy and plant-based yogurt alternatives: Improving their physical and sensorial properties through formulation and lactic acid bacteria cocultures, 2022, 5, 26659271, 665, 10.1016/j.crfs.2022.03.011 | |
| 121. | Eugénie Kayitesi, Ogheneyoma Onojakpor, Siphosanele Mafa Moyo, Highlighting the Impact of Lactic-Acid-Bacteria-Derived Flavours or Aromas on Sensory Perception of African Fermented Cereals, 2023, 9, 2311-5637, 111, 10.3390/fermentation9020111 | |
| 122. | Jiahui Liang, Michelle Ji Yeon Yoo, Brent Seale, Gianpaolo Grazioli, Nutritional and Volatile Characterisation of Milk Inoculated with Thermo-Tolerant Lactobacillus bulgaricus through Adaptive Laboratory Evolution, 2021, 10, 2304-8158, 2944, 10.3390/foods10122944 | |
| 123. | Patrycja Cichońska, Małgorzata Ziarno, Legumes and Legume-Based Beverages Fermented with Lactic Acid Bacteria as a Potential Carrier of Probiotics and Prebiotics, 2021, 10, 2076-2607, 91, 10.3390/microorganisms10010091 | |
| 124. | Aabid Manzoor Shah, Najeebul Tarfeen, Hassan Mohamed, Yuanda Song, Fermented Foods: Their Health-Promoting Components and Potential Effects on Gut Microbiota, 2023, 9, 2311-5637, 118, 10.3390/fermentation9020118 | |
| 125. | Hirosuke Sugahara, Keitaro Nagayama, Shiori Ikeda, Tatsuhiko Hirota, Yasunori Nakamura, D- and l-amino acid concentrations in culture broth of Lactobacillus are highly dependent on the phylogenetic group of Lactobacillus, 2021, 27, 24055808, 101073, 10.1016/j.bbrep.2021.101073 | |
| 126. | Mehran Sayadi, Ali Mojaddar Langroodi, Dornoush Jafarpour, Impact of zein coating impregnated with ginger extract and Pimpinella anisum essential oil on the shelf life of bovine meat packaged in modified atmosphere, 2021, 15, 2193-4126, 5231, 10.1007/s11694-021-01096-1 | |
| 127. | Mehrsa Emkani, Bonastre Oliete, Rémi Saurel, Effect of Lactic Acid Fermentation on Legume Protein Properties, a Review, 2022, 8, 2311-5637, 244, 10.3390/fermentation8060244 | |
| 128. | Urszula Zarzecka, Wioleta Chajęcka-Wierzchowska, Anna Zadernowska, Microorganisms from starter and protective cultures - Occurrence of antibiotic resistance and conjugal transfer of tet genes in vitro and during food fermentation, 2022, 153, 00236438, 112490, 10.1016/j.lwt.2021.112490 | |
| 129. | Yizengaw Mengesha, Alemu Tebeje, Belay Tilahun, James Owusu-Kwarteng, A Review on Factors Influencing the Fermentation Process of Teff (Eragrostis teff) and Other Cereal-Based Ethiopian Injera, 2022, 2022, 2314-5765, 1, 10.1155/2022/4419955 | |
| 130. | Morgan Le Rouzic, Pauline Bruniaux, Cyril Raveschot, François Krier, Vincent Phalip, Rozenn Ravallec, Benoit Cudennec, François Coutte, 2022, 10.5772/intechopen.104958 | |
| 131. | Jiakuan Niu, Xiao Liu, Junying Xu, Fen Li, Jincan Wang, Xixi Zhang, Xu Yang, Lin Wang, Sen Ma, Defeng Li, Xiaoyan Zhu, Chengzhang Wang, Yinghua Shi, Yalei Cui, Ilenys M. Perez-Diaz, Effects of Silage Diet on Meat Quality through Shaping Gut Microbiota in Finishing Pigs, 2023, 11, 2165-0497, 10.1128/spectrum.02416-22 | |
| 132. | Nazan Kavas, Functional probiotic yoghurt production with royal jelly fortification and determination of some properties, 2022, 28, 1878450X, 100519, 10.1016/j.ijgfs.2022.100519 | |
| 133. | Amira M. G. Darwish, Marwa G. Allam, Enaam S. Shokery, Eman H. E. Ayad, Muhammad Hussnain Siddique, Functional products fortified with probiotic LAB isolated from Egyptian dairy sources showed hypolipidemic effects in Albino rats, 2022, 17, 1932-6203, e0263241, 10.1371/journal.pone.0263241 | |
| 134. | Kemal Sener, Banu Arslan, Sultan Ozselcuk, Ramazan Guven, Resistant Lactic Acidemia Due to Accidental Cheese Starter Culture Ingestion, 2022, 60, 07356757, 228.e1, 10.1016/j.ajem.2022.07.046 | |
| 135. | Jegadeesh Raman, Jeong-Seon Kim, Kyeong Rok Choi, Hyunmin Eun, Dongsoo Yang, Young-Joon Ko, Soo-Jin Kim, Application of Lactic Acid Bacteria (LAB) in Sustainable Agriculture: Advantages and Limitations, 2022, 23, 1422-0067, 7784, 10.3390/ijms23147784 | |
| 136. | D.B.T. Amadarshanie, T.L. Gunathilaka, Rajitha M. Silva, S.B. Navaratne, L. Dinithi C. Peiris, Functional and antiglycation properties of cow milk set yogurt enriched with Nyctanthes arbor-tristis L. flower extract, 2022, 154, 00236438, 112910, 10.1016/j.lwt.2021.112910 | |
| 137. | A Djukic-Vuković, D Mladenovic, B Lakicevic, L Mojovic, Lactic acid bacteria: from food preservation to active packaging, 2021, 854, 1755-1307, 012025, 10.1088/1755-1315/854/1/012025 | |
| 138. | Yanni Pan, Yujing Ning, Jing Hu, Zhiying Wang, Xiufeng Chen, Xin Zhao, Mateusz Maciejczyk, The Preventive Effect of Lactobacillus plantarum ZS62 on DSS-Induced IBD by Regulating Oxidative Stress and the Immune Response, 2021, 2021, 1942-0994, 1, 10.1155/2021/9416794 | |
| 139. | Vera Ganina, Natalia Mashentseva, Inna Ionova, Bacteriophages of Lactic Acid Bacteria, 2022, 52, 2074-9414, 361, 10.21603/2074-9414-2022-2-2371 | |
| 140. | Poonam Bansal, Raman Kumar, Suman Dhanda, Characterization of starter cultures and nutritional properties of Pediococcus acidilactici NCDC 252: A potential probiotic of dairy origin , 2022, 46, 0145-8892, 10.1111/jfpp.16817 | |
| 141. | Lucía Diez-Gutiérrez, Leire San Vicente, Jessica Sáenz, Argitxu Esquivel, Luis Javier R. Barron, María Chávarri, Biosynthesis of gamma-aminobutyric acid by Lactiplantibacillus plantarum K16 as an alternative to revalue agri-food by-products, 2022, 12, 2045-2322, 10.1038/s41598-022-22875-w | |
| 142. | M. Ibarlucea-Jerez, M.C. Canivenc-Lavier, E. Beuvier, P. Barbet, F. Menetrier, E. Neyraud, H. Licandro, Persistence of fermented food bacteria in the oral cavity of rats after one week of consumption, 2022, 107, 07400020, 104087, 10.1016/j.fm.2022.104087 | |
| 143. | Shuai Guo, Meixuan Chen, Ting Wu, Kailong Liu, Heping Zhang, Jicheng Wang, Probiotic Bifidobacterium animalis ssp. lactis Probio-M8 improves the properties and organic acid metabolism of fermented goat milk, 2022, 105, 00220302, 9426, 10.3168/jds.2022-22003 | |
| 144. | Mirjana Ž. Grujović, Katarina G. Mladenović, Teresa Semedo‐Lemsaddek, Marta Laranjo, Olgica D. Stefanović, Sunčica D. Kocić‐Tanackov, Advantages and disadvantages of non‐starter lactic acid bacteria from traditional fermented foods: Potential use as starters or probiotics, 2022, 21, 1541-4337, 1537, 10.1111/1541-4337.12897 | |
| 145. | Hafize Fidan, Tuba Esatbeyoglu, Vida Simat, Monica Trif, Giulia Tabanelli, Tina Kostka, Chiara Montanari, Salam A. Ibrahim, Fatih Özogul, Recent developments of lactic acid bacteria and their metabolites on foodborne pathogens and spoilage bacteria: Facts and gaps, 2022, 47, 22124292, 101741, 10.1016/j.fbio.2022.101741 | |
| 146. | Guillermo Eduardo Sedó Molina, Radhakrishna Shetty, Hang Xiao, Anders Peter Wätjen, Miguel Tovar, Claus Heiner Bang-Berthelsen, Development of a novel lactic acid bacteria starter culture approach: From insect microbiome to plant-based fermentations, 2022, 167, 00236438, 113797, 10.1016/j.lwt.2022.113797 | |
| 147. | Hee Seo, Hyunbin Seong, Ga Yun Kim, Yu Mi Jo, Seong Won Cheon, Youngju Song, Byung Hee Ryu, Hee Kang, Nam Soo Han, Development of Anti-inflammatory Probiotic Limosilactobacillus reuteri EFEL6901 as Kimchi Starter: in vitro and In vivo Evidence, 2021, 12, 1664-302X, 10.3389/fmicb.2021.760476 | |
| 148. | Epp Songisepp, Jelena Stsepetova, Merle Rätsep, Liina Kuus, Anneli Piir, Kalle Kilk, Marika Mikelsaar, Polyfunctional metabolic properties of the human strain Lactiplantibacillus plantarum Inducia (DSM 21379): Experimental and clinical approaches, 2022, 92, 17564646, 105064, 10.1016/j.jff.2022.105064 | |
| 149. | Javier Rodríguez, Lucía Vázquez, Ana Belén Flórez, Baltasar Mayo, Phenotype testing, genome analysis, and metabolic interactions of three lactic acid bacteria strains existing as a consortium in a naturally fermented milk, 2022, 13, 1664-302X, 10.3389/fmicb.2022.1000683 | |
| 150. | Renpeng Du, Liansheng Yu, Ningxin Yu, Wenxiang Ping, Gang Song, Jingping Ge, Characterization of exopolysaccharide produced by Levilactobacillus brevis HDE-9 and evaluation of its potential use in dairy products, 2022, 217, 01418130, 303, 10.1016/j.ijbiomac.2022.07.057 | |
| 151. | Justina Mileriene, Loreta Serniene, Beatrice Kasparaviciene, Lina Lauciene, Neringa Kasetiene, Gintare Zakariene, Milda Kersiene, Daiva Leskauskaite, Jonas Viskelis, Yiannis Kourkoutas, Mindaugas Malakauskas, Exploring the Potential of Sustainable Acid Whey Cheese Supplemented with Apple Pomace and GABA-Producing Indigenous Lactococcus lactis Strain, 2023, 11, 2076-2607, 436, 10.3390/microorganisms11020436 | |
| 152. | Nazan Kavas, Yogurt-like product from lupine (Lupinus albus L.) milk as an alternative to dairy products, 2022, 2308-4057, 377, 10.21603/2308-4057-2022-2-546 | |
| 153. | Ahmed Osman, Clara Berenike Hartung, Jan Berend Lingens, Kerstin Rohn, Tom Schreiner, Marwa Fawzy Elmetwaly Ahmed, Julia Hankel, Amr Abd El-Wahab, Christian Visscher, Fermentation Characteristics of Rye and Sorghum Depending on Water:Feed Ratio, 2022, 8, 2311-5637, 155, 10.3390/fermentation8040155 | |
| 154. | Márcia C. Coelho, Francisco Xavier Malcata, Célia C. G. Silva, Lactic Acid Bacteria in Raw-Milk Cheeses: From Starter Cultures to Probiotic Functions, 2022, 11, 2304-8158, 2276, 10.3390/foods11152276 | |
| 155. | R Malaka, F Maruddin, S Baco, M Ridwan, W Hakim, I L Maria, A Alimuddin, Z Dwyana, Determination of the expiration time of Dangke ripening cheese through physico-chemical and microbiological analysis, 2021, 788, 1755-1307, 012094, 10.1088/1755-1315/788/1/012094 | |
| 156. | Heena Sharma, Fatih Ozogul, Elena Bartkiene, João Miguel Rocha, Impact of lactic acid bacteria and their metabolites on the techno-functional properties and health benefits of fermented dairy products, 2021, 1040-8398, 1, 10.1080/10408398.2021.2007844 | |
| 157. | Tulsi Kumari Joishy, Mojibur Rohman Khan, 2023, Chapter 17, 978-981-19-5040-7, 327, 10.1007/978-981-19-5041-4_17 | |
| 158. | Giuseppe Mannino, Graziella Serio, Raimondo Gaglio, Gabriele Busetta, Lorenza La Rosa, Antonino Lauria, Luca Settanni, Carla Gentile, Phytochemical Profile and Antioxidant, Antiproliferative, and Antimicrobial Properties of Rubus idaeus Seed Powder, 2022, 11, 2304-8158, 2605, 10.3390/foods11172605 | |
| 159. | Eva-H. Dulf, Dan C. Vodnar, Alex Danku, Adrian Gheorghe Martău, Bernadette-Emőke Teleky, Francisc V. Dulf, Mohamed Fawzy Ramadan, Ovidiu Crisan, Mathematical Modeling and Optimization of Lactobacillus Species Single and Co-Culture Fermentation Processes in Wheat and Soy Dough Mixtures, 2022, 10, 2296-4185, 10.3389/fbioe.2022.888827 | |
| 160. | Rintaro Sato, Motoyuki Ikeda, Tomonari Tanaka, Hitomi Ohara, Yuji Aso, Production of R- and S-1,2-propanediol in engineered Lactococcus lactis, 2021, 11, 2191-0855, 10.1186/s13568-021-01276-8 | |
| 161. | Hock Wei Tang, Pongsathon Phapugrangkul, Hafizuddin Mohamed Fauzi, Joo Shun Tan, Lactic Acid Bacteria Bacteriocin, an Antimicrobial Peptide Effective Against Multidrug Resistance: a Comprehensive Review, 2022, 28, 1573-3149, 10.1007/s10989-021-10317-6 | |
| 162. | Mei-Ying Huang, Chia-Yi Lo, Cheng-Yu Lai, Jong-Ding Yu, Po-Tsang Lee, Dietary supplementation of synbiotic Leuconostoc mesenteroide B4 and dextran improves immune regulation and disease resistance of Penaeus vannamei against Vibrio parahaemolyticus, 2023, 132, 10504648, 108498, 10.1016/j.fsi.2022.108498 | |
| 163. | Atieh Darbandi, Arezoo Asadi, Marzieh Mahdizade Ari, Elnaz Ohadi, Malihe Talebi, Masoume Halaj Zadeh, Amir Darb Emamie, Roya Ghanavati, Maryam Kakanj, Bacteriocins: Properties and potential use as antimicrobials, 2022, 36, 0887-8013, 10.1002/jcla.24093 | |
| 164. | Xinyang Sun, Simiao Wu, Wen Li, Filiz Koksel, Yifei Du, Lei Sun, Yong Fang, Qiuhui Hu, Fei Pei, The effects of cooperative fermentation by yeast and lactic acid bacteria on the dough rheology, retention and stabilization of gas cells in a whole wheat flour dough system – A review, 2023, 135, 0268005X, 108212, 10.1016/j.foodhyd.2022.108212 | |
| 165. | Javier Rodríguez, Ana González-Guerra, Lucía Vázquez, Raúl Fernández-López, Ana Belén Flórez, Fernando de la Cruz, Baltasar Mayo, Isolation and phenotypic and genomic characterization of Tetragenococcus spp. from two Spanish traditional blue-veined cheeses made of raw milk, 2022, 371, 01681605, 109670, 10.1016/j.ijfoodmicro.2022.109670 | |
| 166. | Simon Sauer, Leon Dlugosch, Felix Milke, Thorsten Brinkhoff, Dietmar R. Kammerer, Florian C. Stintzing, Meinhard Simon, Succession of Bacterial and Fungal Communities during Fermentation of Medicinal Plants, 2022, 8, 2311-5637, 383, 10.3390/fermentation8080383 | |
| 167. | Yu Eun Cheong, Jungyeon Kim, Yong-Su Jin, Kyoung Heon Kim, Elucidation of the fucose metabolism of probiotic Lactobacillus rhamnosus GG by metabolomic and flux balance analyses, 2022, 360, 01681656, 110, 10.1016/j.jbiotec.2022.11.002 | |
| 168. | Charles Obinwanne Okoye, Yongli Wang, Lu Gao, Yanfang Wu, Xia Li, Jianzhong Sun, Jianxiong Jiang, The performance of lactic acid bacteria in silage production: A review of modern biotechnology for silage improvement, 2023, 266, 09445013, 127212, 10.1016/j.micres.2022.127212 | |
| 169. | Kirsi Savijoki, Paola San-Martin-Galindo, Katriina Pitkänen, Minnamari Edelmann, Annika Sillanpää, Cim van der Velde, Ilkka Miettinen, Jayendra Z. Patel, Jari Yli-Kauhaluoma, Mataleena Parikka, Adyary Fallarero, Pekka Varmanen, Food-Grade Bacteria Combat Pathogens by Blocking AHL-Mediated Quorum Sensing and Biofilm Formation, 2022, 12, 2304-8158, 90, 10.3390/foods12010090 | |
| 170. | Sreejita Ghosh, Moupriya Nag, Dibyajit Lahiri, Tanmay Sarkar, Siddhartha Pati, Zulhisyam Abdul Kari, Nilesh P. Nirmal, Hisham Atan Edinur, Rina Rani Ray, Engineered Biofilm: Innovative Nextgen Strategy for Quality Enhancement of Fermented Foods, 2022, 9, 2296-861X, 10.3389/fnut.2022.808630 | |
| 171. | Ingrid Teixeira Akamine, Felipe R. P. Mansoldo, Alane Beatriz Vermelho, Probiotics in the Sourdough Bread Fermentation: Current Status, 2023, 9, 2311-5637, 90, 10.3390/fermentation9020090 | |
| 172. | Subhrakantra Jena, Smita Hasini Panda, 2023, 9780323983419, 85, 10.1016/B978-0-323-98341-9.00024-4 | |
| 173. | Nuthathai Sutthiwong, Supaporn Lekavat, Laurent Dufossé, Involvement of Versatile Bacteria Belonging to the Genus Arthrobacter in Milk and Dairy Products, 2023, 12, 2304-8158, 1270, 10.3390/foods12061270 | |
| 174. | Gengan Du, Yudie Qing, Huanzi Wang, Na Wang, Tianli Yue, Yahong Yuan, Effects of Tibetan kefir grain fermentation on the physicochemical properties, phenolics, enzyme activity, and antioxidant activity of Lycium barbarum (Goji berry) juice, 2023, 53, 22124292, 102555, 10.1016/j.fbio.2023.102555 | |
| 175. | Olaide Olawunmi Ajibola, Raymond Thomas, Babatunde Femi Bakare, Selected fermented indigenous vegetables and fruits from Malaysia as potential sources of natural probiotics for improving gut health, 2023, 12, 22134530, 1493, 10.1016/j.fshw.2023.02.011 | |
| 176. | Amélia Delgado, Nadia Chammem, Manel Issaoui, Emna Ammar, 2023, Chapter 10, 978-3-030-91380-9, 197, 10.1007/978-3-030-91381-6_10 | |
| 177. | Cristina Mihaela Nicolescu, Marius Bumbac, Claudia Lavinia Buruleanu, Elena Corina Popescu, Sorina Geanina Stanescu, Andreea Antonia Georgescu, Siramona Maria Toma, Biopolymers Produced by Lactic Acid Bacteria: Characterization and Food Application, 2023, 15, 2073-4360, 1539, 10.3390/polym15061539 | |
| 178. | Joana F. Fangueiro, Nelson Mota de Carvalho, Filipa Antunes, Inês F. Mota, Manuela Estevez Pintado, Ana Raquel Madureira, Patrícia Santos Costa, Lignin from sugarcane bagasse as a prebiotic additive for poultry feed, 2023, 01418130, 124262, 10.1016/j.ijbiomac.2023.124262 | |
| 179. | John Samelis, Charikleia Tsanasidou, Loulouda Bosnea, Charikleia Ntziadima, Ilias Gatzias, Athanasia Kakouri, Dimitrios Pappas, Pilot-Scale Production of Traditional Galotyri PDO Cheese from Boiled Ewes’ Milk Fermented with the Aid of Greek Indigenous Lactococcus lactis subsp. cremoris Starter and Lactiplantibacillus plantarum Adjunct Strains, 2023, 9, 2311-5637, 345, 10.3390/fermentation9040345 | |
| 180. | Diana Ibeth Romero-Mota, Joaquín Estrada-García, Alejandro Alvarado-Lassman, Juan Manuel Méndez-Contreras, Growth kinetics of Lactobacillus acidophilus During the Anaerobic Biotransformation Process of Agro-Sugarcane Waste, 2023, 1877-2641, 10.1007/s12649-023-02100-z | |
| 181. | Guillermo Ortiz Charneco, Paul P. de Waal, Irma M.H. van Rijswijck, Noël N.M.E. van Peij, Douwe van Sinderen, Jennifer Mahony, Bacteriophages in the Dairy Industry: A Problem Solved?, 2023, 14, 1941-1413, 367, 10.1146/annurev-food-060721-015928 | |
| 182. | Kambhampati Vivek, Chandrasekar Venkitasamy, 2023, Chapter 3, 978-981-19-9102-8, 71, 10.1007/978-981-19-9103-5_3 | |
| 183. | Bianca de Oliveira Hosken, Gilberto Vinícius Melo Pereira, Thamylles Thuany Mayrink Lima, João Batista Ribeiro, Walter Coelho Pereira de Magalhães Júnior, José Guilherme Prado Martin, Underexplored Potential of Lactic Acid Bacteria Associated with Artisanal Cheese Making in Brazil: Challenges and Opportunities, 2023, 9, 2311-5637, 409, 10.3390/fermentation9050409 | |
| 184. | Yueqi Wang, Qian Chen, Laihao Li, Shengjun Chen, Yongqiang Zhao, Chunsheng Li, Huan Xiang, Yanyan Wu, Dongxiao Sun‐Waterhouse, Transforming the fermented fish landscape: Microbiota enable novel, safe, flavorful, and healthy products for modern consumers, 2023, 1541-4337, 10.1111/1541-4337.13208 | |
| 185. | Thisari A Bandara, Srimali P Munasinghe‐Arachchige, Charitha J Gamlath, Fermented whey beverages: A review of process fundamentals, recent developments and nutritional potential, 2023, 1364-727X, 10.1111/1471-0307.12993 | |
| 186. | Pawade Mohit Manoj, Jenekar Rahi Mohan, Bhosale Yuvraj Khasherao, Rafeeya Shams, Kshirod K. Dash, Fruit based probiotic functional beverages: A review, 2023, 14, 26661543, 100729, 10.1016/j.jafr.2023.100729 | |
| 187. | Galina Sviridenko, Olga Shukhalova, Denis Mamykin, Development and Acid Formation of Lactococci at Technically Significant Temperatures: Comparative Analysis, 2023, 1019-8946, 71, 10.21603/1019-8946-2023-6-18 | |
| 188. | Özge Kahraman-Ilıkkan, Comparative genomics of four lactic acid bacteria identified with Vitek MS (MALDI-TOF) and whole-genome sequencing, 2024, 299, 1617-4615, 10.1007/s00438-024-02129-2 | |
| 189. | John Loughrin, Getahun Agga, Nanh Lovanh, Simple Sugars Alter the Odorant Composition of Dairy Cow Manure, 2024, 11, 2076-3298, 145, 10.3390/environments11070145 | |
| 190. | Xi Wang, Fucan Li, Xiaorui Cai, Yanling Huang, Haitao Shi, Exploring the combination of wilting and different types of additives to improve silage quality of highland alfalfa: Fermentation quality, nutritional values, molecular structural features, and ruminal degradability, 2024, 318, 03778401, 116123, 10.1016/j.anifeedsci.2024.116123 | |
| 191. | Volodymyr Vovkotrub, Inga Kowalewska, Ewa Czerniawska-Piątkowska, Olha Iakubchak, Julia Hryb, Modern methods of raw meat processing to reduce microbial contamination, 2024, 15, 2663967X, 55, 10.31548/veterinary3.2024.55 | |
| 192. | ||
| 193. | Sha-sha Zheng, Ying-ying Hu, Li-jun Tan, Liu Yang, Chun-yu Wang, Bao-cai Xu, Innovative insights into dry fermented sausages flavor: Unraveling the impact of varied lactobacillus genera-driven fermentation, 2024, 60, 22124292, 104331, 10.1016/j.fbio.2024.104331 | |
| 194. | Yoiner K. Lapiz-Culqui, Jegnes Benjamín Meléndez-Mori, José Jesús Tejada-Alvarado, Denny Cortez, Eyner Huaman, Victor M. Núñez Zarantes, Manuel Oliva, Study of the physicochemical characteristics, antimicrobial activity, and in vitro multiplication of wild blackberry species from the Peruvian highlands, 2024, 14, 2045-2322, 10.1038/s41598-024-54058-0 | |
| 195. | Zhenyu Liu, Rong Hu, Lunjie Huang, Yunhao Lu, Zhenghong Xu, Yuanlong Chi, Lactic acid bacteria with weak post-acidification potential applied for low-salt paocai fermentation: A perspective from screening to molecular mechanism, 2024, 206, 00236438, 116531, 10.1016/j.lwt.2024.116531 | |
| 196. | Gokul Priya Thangavelu, Anand Raj Dhanapal, Ramkumar Samynathan, Baskar Venkidasamy, Muthu Thiruvengadam, Andrey Nagdalian, Mohammad Ali Shariati, 2024, 9780443153464, 259, 10.1016/B978-0-443-15346-4.00010-0 | |
| 197. | Hocine Remini, Yasmine Remini-Sahraoui, Tassadit Benbara, Djamila Sadoun, From farm to cheeseboard: Harnessing the biopreserving performance and enhancing safety of Lactococcus lactis KJ660075 in goat's milk cheese, 2024, 157, 09586946, 105977, 10.1016/j.idairyj.2024.105977 | |
| 198. | Xueqi Lu, Mengying Sun, Yuqing Chen, Dashuai He, Yanfeng Tuo, Guangqing Mu, Yinglong Song, Effect of the quorum sensing signal molecule auto-inducer-2 on fermentation performance of Lactobacillus delbrueckii subsp. Bulgaricus DPUL-F36, 2024, 62, 22124292, 105346, 10.1016/j.fbio.2024.105346 | |
| 199. | Tracy Ann Bruce-Tagoe, Shyju Bhaskar, Ruchita Rao Kavle, Jaison Jeevanandam, Caleb Acquah, Godfred Ohemeng-Boahen, Dominic Agyei, Michael K. Danquah, Advances in aptamer-based biosensors for monitoring foodborne pathogens, 2024, 61, 0022-1155, 1252, 10.1007/s13197-023-05889-8 | |
| 200. | Xiang-ao Li, Yumeng Sui, Jiasheng Lu, Jing Ren, Baohua Kong, Yongjie Li, Qian Chen, Weiwei Yang, Compensative role of autochthonous lactic acid bacteria in physical properties and taste profiles of dry sausage with partial substitution of NaCl by KCl, 2024, 199, 00236438, 116115, 10.1016/j.lwt.2024.116115 | |
| 201. | Kübra Küçükgöz, Marcin Kruk, Danuta Kołożyn-Krajewska, Monika Trząskowska, Investigating the Probiotic Potential of Vegan Puree Mixture: Viability during Simulated Digestion and Bioactive Compound Bioaccessibility, 2024, 16, 2072-6643, 561, 10.3390/nu16040561 | |
| 202. | Yuliya Pronina, Talgat Kulazhanov, Zhanar Nabiyeva, Olga Belozertseva, Anastasiya Burlyayeva, Alberto Cepeda, Erik Askarbekov, Gulzhan Urazbekova, Elmira Bazylkhanova, Development of a Technology for Protein-Based, Glueless Belevskaya Pastille with Study of the Impact of Probiotic Sourdough Dosage and Technological Parameters on Its Rheological Properties, 2023, 12, 2304-8158, 3700, 10.3390/foods12193700 | |
| 203. | Sachin Kumar, Sourabh Kumar, Swati Mitharwal, Abhishek Chandra, Prabhat Kumar Nema, Effect of different concentrations of thermoprotectant on microencapsulation of Lactobacillus rhamnosus GG by spray-drying, and its effect on physicochemical properties and viability, 2023, 30, 2231-7546, 1066, 10.47836/ifrj.30.4.22 | |
| 204. | Natsag Lkhagvasuren, Gil-Ha Kim, Batchimeg Namshir, Woan Sub Kim, Antibacterial Activity against Pathogenic Bacteria of Lactiplantibacillus argentratensis Isolated from Blueberries, 2023, 41, 2733-4554, 191, 10.22424/jdsb.2023.41.4.191 | |
| 205. | Carmen Miramontes-Corona, Abraham Cetina-Corona, María Esther Macías-Rodríguez, Alfredo Escalante, Rosa Isela Corona-González, Guillermo Toriz, Lactic Acid Bacterial Fermentation of Esterified Agave Fructans in Simulated Physicochemical Colon Conditions for Local Delivery of Encapsulated Drugs, 2024, 10, 2311-5637, 478, 10.3390/fermentation10090478 | |
| 206. | Charu Tripathi, Jaya Malhotra, Jasvinder Kaur, Employing Food and Industrial Microbiology to Accelerate Sustainable Development Goals, 2022, 1, 25835327, 22, 10.59118/IFJF3014 | |
| 207. | José Alejandro Valenzuela, Lucía Vázquez, Javier Rodríguez, Ana Belén Flórez, Olga M. Vasek, Baltasar Mayo, Phenotypic, Technological, Safety, and Genomic Profiles of Gamma-Aminobutyric Acid-Producing Lactococcus lactis and Streptococcus thermophilus Strains Isolated from Cow’s Milk, 2024, 25, 1422-0067, 2328, 10.3390/ijms25042328 | |
| 208. | Xuefei Shao, Huhu Wang, Xiangyu Song, Na Xu, Linlin Cai, Jian Sun, Xinglian Xu, Decoding the flavor regulation mechanism of fermented sausages inoculated with indigenous strains via metagenomic and GC-MS analysis, 2024, 206, 00236438, 116604, 10.1016/j.lwt.2024.116604 | |
| 209. | Turkson Antwi Boasiako, Aregbe Afusat Yinka, Xiong Yuqing, Isaac Duah Boateng, Yongkun Ma, Tri-cultured lactic-acetic acid co-fermentation improves stored jujube puree functionality, physicochemical, volatile compounds, and sensory characteristics, 2024, 57, 22124292, 103534, 10.1016/j.fbio.2023.103534 | |
| 210. | Mengying Sun, Jiang Yu, Yinglong Song, Xinling Li, Guangqing Mu, Yanfeng Tuo, Fermented milk by Lactobacillus delbrueckii, Lacticaseibacillus paracasei, and Kluyveromyces marxianus shows special physicochemical and aroma formation during the storage, 2023, 55, 22124292, 103025, 10.1016/j.fbio.2023.103025 | |
| 211. | T. Jayasree Joshi, Salini S.V, Lakshmi Mohan, P. Nandagopal, Jobil J. Arakal, Functional metabolites of probiotic lactic acid bacteria in fermented dairy products, 2024, 3, 29498244, 100341, 10.1016/j.foohum.2024.100341 | |
| 212. | Negin Ghazanfari, Fereshteh Falah, Farideh Tabatabaei Yazdi, Behrooz Alizadeh Behbahani, Alireza Vasiee, Development and characterization of gamma-aminobutyric acid (GABA)-enriched functional yogurt using Limosilactobacillus fermentum 4–17, 2024, 4, 27725022, 100557, 10.1016/j.afres.2024.100557 | |
| 213. | K. V. Moiseenko, A. V. Shabaev, O. A. Glazunova, O. S. Savinova, T. V. Fedorova, Fatty Acid Profiles Change and the Volatile Organic Compounds Formation During the Cow’S Milk Fermentation with Probiotic Lacticaseibacillus paracasei Strains, 2023, 59, 0555-1099, 483, 10.31857/S0555109923050136 | |
| 214. | Federica Montagano, Francesca Dell’Orco, Roberta Prete, Aldo Corsetti, Health benefits of fermented olives, olive pomace and their polyphenols: a focus on the role of lactic acid bacteria, 2024, 11, 2296-861X, 10.3389/fnut.2024.1467724 | |
| 215. | K. E. Vivekanandan, R. Kasimani, P. Vinoth Kumar, S. Meenatchisundaram, William Arputha Sundar, Overview of cloning in lactic acid bacteria: Expression and its application of probiotic potential in inflammatory bowel diseases, 2024, 71, 0885-4513, 881, 10.1002/bab.2584 | |
| 216. | Giuseppina Tatulli, Laura Ruth Cagliani, Francesca Sparvoli, Milena Brasca, Roberto Consonni, NMR-Based Metabolomic Study on Phaseolus vulgaris Flour Fermented by Lactic Acid Bacteria and Yeasts, 2023, 28, 1420-3049, 4864, 10.3390/molecules28124864 | |
| 217. | Weina Song, Huifei Yi, Fei Lu, Yu Deng, Minpeng Zhu, Junwei Wang, Xiuhong Zhao, Zhigang Xiao, Yifan Zhang, Correlation between microbial communities and flavor compounds in Suantangzi dough from Liaoning Province, China, 2025, 464, 03088146, 141892, 10.1016/j.foodchem.2024.141892 | |
| 218. | Cécile Philippe, Jeffrey K Cornuault, Alessandra G de Melo, Rachel Morin-Pelchat, Alice P Jolicoeur, Sylvain Moineau, The never-ending battle between lactic acid bacteria and their phages, 2023, 47, 1574-6976, 10.1093/femsre/fuad035 | |
| 219. | Tuba Zorlu Ünlü, Semra Topuz, Mustafa Bayram, Cemal Kaya, Evaluation of antioxidant activity and some physicochemical characteristics of pickled vine (Vitis vinifera L.) leaves, 2024, 28, 2587-1358, 459, 10.29050/harranziraat.1344099 | |
| 220. | Graciela A. Miranda-Mejía, Sandra Teresita Martín del Campo-Barba, Teresita Arredondo-Ochoa, Viridiana Tejada-Ortigoza, Mariana Morales-de la Peña, Low-intensity pulsed electric fields pre-treatment on yogurt starter culture: Effects on fermentation time and quality attributes, 2024, 95, 14668564, 103708, 10.1016/j.ifset.2024.103708 | |
| 221. | D L Rukmi, Z E Fitri, L N Sahenda, Characteristics of kefir based on goat’s milk with different starter combinations, 2023, 1168, 1755-1307, 012031, 10.1088/1755-1315/1168/1/012031 | |
| 222. | Tiago de Melo Nazareth, Elisa Soriano Pérez, Carlos Luz, Giuseppe Meca, Juan Manuel Quiles, Comprehensive Review of Aflatoxin and Ochratoxin A Dynamics: Emergence, Toxicological Impact, and Advanced Control Strategies, 2024, 13, 2304-8158, 1920, 10.3390/foods13121920 | |
| 223. | Emma Mani-López, Nelly Ramírez-Corona, Aurelio López-Malo, Latilactobacillus sakei as a starter culture to ferment pepper fruits, 2024, 2, 29498244, 100233, 10.1016/j.foohum.2024.100233 | |
| 224. | V. Manasa, R. Gobinath, Kiran Kumar, S. Vijay kumar, P. C. Latha, Amol Phule, 2024, Chapter 14, 978-3-031-70568-7, 239, 10.1007/978-3-031-70569-4_14 | |
| 225. | Samson A. Oyeyinka, Marina Corrado, Brittany Hazard, Bukola A. Onarinde, 2023, Chapter 18, 978-3-031-35842-5, 431, 10.1007/978-3-031-35843-2_18 | |
| 226. | Rodrigo Sigala‐Robles, María del Carmen Estrada‐Montoya, MarÍa J. Torres‐Llanez, Lourdes Santiago‐López, Adrián Hernández‐Mendoza, Belinda Vallejo‐Cordoba, Verónica Mata‐Haro, Abraham Wall‐Medrano, Aarón F. González‐Córdova, Tracking the metabolite footprint of four lactic acid bacteria in semiskimmed milk: A chemometric analysis, 2024, 77, 1364-727X, 1171, 10.1111/1471-0307.13127 | |
| 227. | Junli Liu, Wei Zhao, Aixia Zhang, Pengliang Li, Jingke Liu, Dynamics and functionalities of bacterial community during foxtail millet dough fermentation by metagenomic analysis, 2024, 4, 27725669, 343, 10.1016/j.jfutfo.2023.11.006 | |
| 228. | Ajay Kumar, Rohit Ruhal, Rashmi Kataria, 2023, 9781394166213, 83, 10.1002/9781394167043.ch3 | |
| 229. | Shuai Guo, Yue Sun, Ting Wu, Lai-Yu Kwok, Jicheng Wang, Heping Zhang, Metabolic profiling and growth characteristics of a spaceflight-induced mutant of Lacticaseibacillus rhamnosus: Unveiling enhanced carbohydrate and amino acid metabolism for improved probiotic potential, 2024, 58, 22124292, 103758, 10.1016/j.fbio.2024.103758 | |
| 230. | Haotian Cai, Lei Tao, Xianyuan Zhou, Yu Liu, Di Sun, Qingbao Ma, Zhongjie Yu, Wei Jiang, Lactic acid bacteria in fermented fish: Enhancing flavor and ensuring safety, 2024, 16, 26661543, 101206, 10.1016/j.jafr.2024.101206 | |
| 231. | Anindita Deb Pal, Anasuya Pal, 2024, 9780443139321, 47, 10.1016/B978-0-443-13932-1.00026-X | |
| 232. | Jiangli Wu, Wenkang Hu, Zhengbin Yang, Xuefeng Zeng, Ziru Dai, Effect of flours addition on the physicochemical and metabolome in Suanjiang, a Chinese traditional fermentation coagulant, 2023, 53, 22124292, 102716, 10.1016/j.fbio.2023.102716 | |
| 233. | Sushmita Das, Maloyjo Joyraj Bhattacharjee, Ashis K. Mukherjee, Mojibur Rohman Khan, Selection of a multi-species starter culture for mustard seed fermentation to enhance polyunsaturated fatty acids and improve gastrointestinal health markers, 2024, 59, 22124292, 104109, 10.1016/j.fbio.2024.104109 | |
| 234. | N. E. Posokina, A. I. Zakharova, Modern biological methods of processing plant raw materials used to increase its storage capacity, 2024, 7, 2618-7272, 298, 10.21323/2618-9771-2024-7-2-298-304 | |
| 235. | Shanshan Zhao, Jinzhu Yue, Yue Wang, Junhua Shao, Zijing Li, Mohan Li, The regulation of volatile flavor compounds in fermented meat products mediated by microorganisms: A review, 2024, 62, 22124292, 105180, 10.1016/j.fbio.2024.105180 | |
| 236. | Qinglan Xia, Yumeng Lei, Jiadun Wang, Qiang Wang, Probiotic management and inflammatory factors as a novel treatment in cirrhosis: A systematic review and meta-analysis, 2023, 18, 2391-5412, 10.1515/biol-2022-0741 | |
| 237. | Jahnavi Kumari Singh, Palanisamy Bruntha Devi, G. Bhanuprakash Reddy, Amit K. Jaiswal, Digambar Kavitake, Prathapkumar Halady Shetty, Biosynthesis, classification, properties, and applications of Weissella bacteriocins, 2024, 15, 1664-302X, 10.3389/fmicb.2024.1406904 | |
| 238. | Amenan Clémentine Kouakou-Kouamé, Florent Kouadio N’guessan, Didier Montet, Marcellin Koffi Djè, 2023, 9780323919302, 239, 10.1016/B978-0-323-91930-2.00009-2 | |
| 239. | Abiola Folakemi Olaniran, Christianah Oluwakemi Erinle, Olubukola David Olaniran, Clinton Emeka Okonkwo, Adeyemi Ayotunde Adeyanju, Abiola Ezekiel Taiwo, 2024, 9780323983402, 47, 10.1016/B978-0-323-98340-2.00020-1 | |
| 240. | Yue Sun, Xin Su, Lixia Zhao, Tiansong Sun, Wenjun Liu, Carbon metabolism of a novel isolate from Lacticaseibacillus rhamnosus Probio-M9 derived through space mutant, 2024, 135, 1365-2672, 10.1093/jambio/lxae205 | |
| 241. | Aliakbar Gholamhosseinpour, Seyed Mohammad Bagher Hashemi, Fatemeh Safari, Kaouther Kerboua, Impact of ultrasonicated Lactobacillus delbrueckii subsp. bulgaricus, Streptococcus thermophilus and Lactiplantibacillus plantarum AF1 on the safety and bioactive properties of stirred yoghurt during storage, 2024, 102, 13504177, 106726, 10.1016/j.ultsonch.2023.106726 | |
| 242. | D J S Siregar, E Julianti, M Tafsin, D Suryanto, Antibacterial activity of lactic acid bacteria from black soldier fly (Hermetia illucens) larvae fed with empty fruit bunch and tofu waste, 2024, 1352, 1755-1307, 012011, 10.1088/1755-1315/1352/1/012011 | |
| 243. | Karina Edith Motato Rocha, Valentina Gonzalez-Montero, María Orfilia Román-Morales, Identification of microorganisms in wet coffee fermentation Coffea arabica Var Catimor and Castillo in Jardín, Antioquia-Colombia, using culture-dependent methods, 2024, 31, 01214004, 10.17533/udea.vitae.v31n1a351373 | |
| 244. | Screening For Potential Exopolysaccharide Producers From Lactobacillus spp Isolated From Locally Fermented Milk (Nono), 2022, 7, 2814-1822, 84, 10.47430/ujmr.2271.014 | |
| 245. | Carlos Gordillo-Andia, Jonathan Almirón, Jaime E. Barreda-Del-Carpio, Francine Roudet, Danny Tupayachy-Quispe, María Vargas, Influence of Kluyveromyces lactis and Enterococcus faecalis on Obtaining Lactic Acid by Cheese Whey Fermentation, 2024, 14, 2076-3417, 4649, 10.3390/app14114649 | |
| 246. | Babak Haghshenas, Amir Kiani, Saeideh Mansoori, Ehsan Mohammadi-noori, Yousef Nami, Probiotic properties and antimicrobial evaluation of silymarin-enriched Lactobacillus bacteria isolated from traditional curd, 2023, 13, 2045-2322, 10.1038/s41598-023-37350-3 | |
| 247. | Alkatuzzakia Akhi, Tanvir Ahmed, Rowshon Ara, Md Rahmatuzzaman Rana, Response surface optimization of thermo-sonication conditions and taro mucilage concentrations for the preparation of soy yogurt, 2024, 15, 26661543, 100918, 10.1016/j.jafr.2023.100918 | |
| 248. | Konstantin V. Moiseenko, Olga A. Glazunova, Tatyana V. Fedorova, Fermentation of Rice, Oat, and Wheat Flour by Pure Cultures of Common Starter Lactic Acid Bacteria: Growth Dynamics, Sensory Evaluation, and Functional Properties, 2024, 13, 2304-8158, 2414, 10.3390/foods13152414 | |
| 249. | Meryem Kübra Satılmış, Hale İnci Öztürk, Talha Demirci, Begüm Denktaş, Nihat Akın, Revealing the proteolytic characteristics of lactobacillus, lacticaseibacillus, and lactiplantibacillus isolates by in vitro and in situ perspectives, 2023, 55, 22124292, 103086, 10.1016/j.fbio.2023.103086 | |
| 250. | Yijin Yang, Yongjun Xia, Guangqiang Wang, Xin Song, Li Ni, Lianzhong Ai, Screening appropriate lactic acid bacteria as adjunct starter to enhance characteristic flavor and sensory profiles of Huangjiu (Chinese rice wine), 2024, 62, 22124292, 105300, 10.1016/j.fbio.2024.105300 | |
| 251. | Shikai Yan, Pan Huang, Leilei Yu, Fengwei Tian, Jianxin Zhao, Wei Chen, Qixiao Zhai, Metabolomic analysis reveals Ligilactobacillus salivarius CCFM 1266 fermentation improves dairy product quality, 2024, 188, 09639969, 114309, 10.1016/j.foodres.2024.114309 | |
| 252. | Luana Faria Silva, Tássila Nakata Sunakozawa, Diego Alves Monteiro, Tiago Casella, Ana Carolina Conti, Svetoslav Dimitrov Todorov, Ana Lúcia Barretto Penna, Potential of Cheese-Associated Lactic Acid Bacteria to Metabolize Citrate and Produce Organic Acids and Acetoin, 2023, 13, 2218-1989, 1134, 10.3390/metabo13111134 | |
| 253. | Shujuan Yang, Mei Bai, Weichi Liu, Weicheng Li, Zhi Zhong, Lai-Yu Kwok, Gaifang Dong, Zhihong Sun, Predicting Lactobacillus delbrueckii subsp. bulgaricus-Streptococcus thermophilus interactions based on a highly accurate semi-supervised learning method, 2024, 1674-7305, 10.1007/s11427-023-2569-7 | |
| 254. | Giovanna Lo Vecchio, Eleonora Di Salvo, Laura De Maria, Vincenzo Nava, Rossana Rando, Teresa Gervasi, Nicola Cicero, Opuntia ficus indica cladode as fermentation feedstock for lactic acid production by Lactobacillus acidophilus LA 5 , 2023, 1478-6419, 1, 10.1080/14786419.2023.2284253 | |
| 255. | M GOWTHAM, D DEKA, Isolation, molecular characterization and antibiogram of Lactic acid bacteria from dairy cattle sources of Mizoram, India, 2024, 94, 2394-3327, 203, 10.56093/ijans.v94i3.139233 | |
| 256. | Mastaneh Ghasemi Amirlo, Mansour Bayat, Alireza Iranbakhsh, Mahshad Khalilian, Effects of Bacteriocin Extracted from Lactobacillus plantarum on Treatment-Resistant Escherichia coli Bacteria Isolated from Humans and Livestock, 2024, 1, 2950-5488, 10.5812/jmb-153862 | |
| 257. | Kouadio Jean Eric-Parfait Kouamé, Awa Fanny Massounga Bora, Xiaodong Li, Lu Liu, Ibourahema Coulibaly, Yue Sun, Muhammad Hussain, New insights into functional cereal foods as an alternative for dairy products: A review, 2023, 55, 22124292, 102840, 10.1016/j.fbio.2023.102840 | |
| 258. | Talitha Meneguelli, Nikolai Kolba, Arundhati Misra, Ana Dionísio, Ana Pelissari Kravchychyn, Bárbara Da Silva, Hercia Stampini Duarte Martino, Helen Hermsdorff, Elad Tako, Intra-Amniotic Administration of Cashew Nut (Anacardium occidentale L.) Soluble Extract Improved Gut Functionality and Morphology In Vivo (Gallus gallus), 2023, 15, 2072-6643, 2378, 10.3390/nu15102378 | |
| 259. | Bibi Nabihah Abdul Hakim, Ng Jia Xuan, Siti Nur Hazwani Oslan, A Comprehensive Review of Bioactive Compounds from Lactic Acid Bacteria: Potential Functions as Functional Food in Dietetics and the Food Industry, 2023, 12, 2304-8158, 2850, 10.3390/foods12152850 | |
| 260. | Tetiana Dyrda-Terniuk, Viorica Railean, Aleksandra Bogumiła Florkiewicz, Justyna Walczak-Skierska, Mateusz Kolankowski, Joanna Rudnicka, Dorota Białczak, Paweł Pomastowski, The impact of Lactiplantibacillus plantarum on the cream composition: Insight into changes of vitamin D3 content and fatty acid composition, 2025, 161, 09586946, 106118, 10.1016/j.idairyj.2024.106118 | |
| 261. | Mei-Ying Huang, Bich Ngoc Truong, Tan Phat Nguyen, Huei-Jen Ju, Po-Tsang Lee, Synergistic effects of combined probiotics Bacillus pumilis D5 and Leuconostoc mesenteroide B4 on immune enhancement and disease resistance in Litopenaeus vannamei, 2024, 155, 0145305X, 105158, 10.1016/j.dci.2024.105158 | |
| 262. | Shujuan Yang, Mei Bai, Lai-Yu Kwok, Zhi Zhong, Zhihong Sun, The intricate symbiotic relationship between lactic acid bacterial starters in the milk fermentation ecosystem, 2023, 1040-8398, 1, 10.1080/10408398.2023.2280706 | |
| 263. | Yining Dong, Elham Chidar, Salwa Karboune, Investigation of in situ and ex situ mode of lactic acid bacteria incorporation and the effect on dough extensibility, bread texture and flavor quality during shelf-life, 2024, 24, 25901575, 101857, 10.1016/j.fochx.2024.101857 | |
| 264. | K. V. Moiseenko, A. V. Shabaev, O. A. Glazunova, O. S. Savinova, T. V. Fedorova, Changes in Fatty Acid Profiles and the Formation of Volatile Organic Compounds During Fermentation of Cow’s Milk with Probiotic Lacticaseibacillus paracasei Strains, 2023, 59, 0003-6838, 636, 10.1134/S0003683823050137 | |
| 265. | Fernanda Alvarenga Lima Barroso, Luís Cláudio Lima de Jesus, Tales Fernando da Silva, Andria dos Santos Freitas, Monique Ferrary Américo, Lucas Jorge da Silva Fernandes, Rafael de Assis Gloria, Gabriela Munis Campos, Rodrigo Dias de Oliveira Carvalho, Túlio Marcos Santos, Juliana Guimarães Laguna, Vasco Ariston de Carvalho Azevedo, 2023, 9780323919302, 1, 10.1016/B978-0-323-91930-2.00002-X | |
| 266. | Abeer Majeed Salih, Shaimaa A. M. Ali, Evaluation of Probiotic Properties of Lactic Acid Bacteria Isolated from Dairy Products, 2023, 1158, 1755-1307, 112016, 10.1088/1755-1315/1158/11/112016 | |
| 267. | Sagnik Sarkar, Shankar Prasad Sha, Kriti Ghatani, Metabolomics of ethnic fermented foods and beverages: understanding new aspects through Omic techniques, 2023, 7, 2571-581X, 10.3389/fsufs.2023.1040567 | |
| 268. | Shanshan Zhao, Yuhang Sai, Wanting Liu, Huiwen Zhao, Xue Bai, Wanying Song, Yan Zheng, Xiqing Yue, Flavor Characterization of Traditional Fermented Soybean Pastes from Northeast China and Korea, 2023, 12, 2304-8158, 3294, 10.3390/foods12173294 | |
| 269. | Nimra Arshad, Saeed Akhtar, Tariq Ismail, Wisha Saeed, Muhammad Qamar, Fatih Özogul, Elena Bartkiene, João Miguel Rocha, The Comparative Effect of Lactic Acid Fermentation and Germination on the Levels of Neurotoxin, Anti-Nutrients, and Nutritional Attributes of Sweet Blue Pea (Lathyrus sativus L.), 2023, 12, 2304-8158, 2851, 10.3390/foods12152851 | |
| 270. | Kristina Kondrotiene, Paulina Zavistanaviciute, Jurgita Aksomaitiene, Aleksandr Novoslavskij, Mindaugas Malakauskas, Lactococcus lactis in Dairy Fermentation—Health-Promoting and Probiotic Properties, 2023, 10, 2311-5637, 16, 10.3390/fermentation10010016 | |
| 271. | Shumin Lin, Xinxia Zhang, Junren Wang, Ting Li, Li Wang, Effect of lactic acid bacteria fermentation on bioactive components of black rice bran (Oryza sativa L.) with different milling fractions, 2024, 58, 22124292, 103684, 10.1016/j.fbio.2024.103684 | |
| 272. | Anastasia Palatzidi, Olga Nikoloudaki, Maria Garcia Torreiro, Carolina Matteucci, Giovanna Ferrentino, Matteo Mario Scampicchio, Raffaella Di Cagno, Marco Gobbetti, Novel formulations for developing fresh hybrid cheese analogues utilizing fungal-fermented brewery side-stream flours, 2024, 9, 26659271, 100829, 10.1016/j.crfs.2024.100829 | |
| 273. | Xuan Li, Gaiming Zhao, Yangyi Zheng, Yi Wang, Xueyuan Bai, Fuqiang Li, Yue Gu, Chaozhi Zhu, Effects of single fermentation of Lactobacillus sakei and compound fermentation with Staphylococcus carnosus on the metabolomics of beef sausages, 2025, 464, 03088146, 141728, 10.1016/j.foodchem.2024.141728 | |
| 274. | Albert Krastanov, Philip J. Yeboah, Namesha Dulari Wijemanna, Abdulhakim S. Eddin, Raphael D. Ayivi, Salam A. Ibrahim, 2023, Chapter 7, 978-1-83768-092-4, 10.5772/intechopen.109034 | |
| 275. | Nicholas Horlacher, Indrawati Oey, Dominic Agyei, Learning from Tradition: Health-Promoting Potential of Traditional Lactic Acid Fermentation to Drive Innovation in Fermented Plant-Based Dairy Alternatives, 2023, 9, 2311-5637, 452, 10.3390/fermentation9050452 | |
| 276. | Gabriella J. Gephart, Ahmed G. Abdelhamid, Ahmed E. Yousef, Comparative genomics and phenotypic assessment of lactic acid bacteria isolated from artisanal cheese as potential starter cultures, 2024, 210, 00236438, 116849, 10.1016/j.lwt.2024.116849 | |
| 277. | Daniel Asfaw Kitessa, Review on effect of fermentation on physicochemical properties, anti-nutritional factors and sensory properties of cereal-based fermented foods and beverages, 2024, 74, 1869-2044, 10.1186/s13213-024-01763-w | |
| 278. | Mengying Sun, Jiang Yu, Yinglong Song, Xinling Li, Guangqing Mu, Yanfeng Tuo, Metabolomic analysis of fermented milk with Lactobacillus delbrueckii subsp. bulgaricus, Lacticaseibacillus paracasei cocultured with Kluyveromyces marxianus during storage, 2023, 54, 22124292, 102901, 10.1016/j.fbio.2023.102901 | |
| 279. | Mei Bai, Shujuan Yang, Qian Zhao, Dan Wang, Ting Zhang, Lai-Yu Kwok, Zhihong Sun, Fermentation characteristics of Lactobacillus delbrueckii subsp. bulgaricus T50 and Streptococcus thermophilus S10 complex starter: Enhancing fermentation performance, metabolic interaction, and storage stability, 2024, 208, 00236438, 116716, 10.1016/j.lwt.2024.116716 | |
| 280. | Siyu Liu, Jiaqi Luo, Xiayu Liu, Ying Shi, Qihe Chen, Integrative liquid chromatography–tandem mass spectrometry metabolomics and high-throughput sequencing technology reveal physicochemical characteristics and bacterial diversity of traditionally pickled mustard tuber from different regions of China, 2024, 8, 2399-1399, 10.1093/fqsafe/fyae022 | |
| 281. | Hyejin Jeon, Kippeum Lee, Joo-Yun Kim, Jae-Jung Shim, Jung-Lyoul Lee, Effect of Lactobacillus curvatus HY7602-Fermented Antler on Sarcopenia in Mice, 2023, 9, 2311-5637, 429, 10.3390/fermentation9050429 | |
| 282. | Kamil Foss, Małgorzata Starowicz, Lucyna Kłębukowska, Tomasz Sawicki, Effect of lactic acid fermentation of red beetroot juice on volatile compounds profile and content, 2023, 249, 1438-2377, 2401, 10.1007/s00217-023-04304-y | |
| 283. | Linna Guo, Xuekai Wang, Huilong Chen, Xiaomei Li, Yi Xiong, Hongzhang Zhou, Gang Xu, Fuyu Yang, Kuikui Ni, Exploring the fermentation quality, bacterial community and metabolites of alfalfa ensiled with mugwort residues and Lactiplantibacillus pentosus, 2023, 10, 2196-5641, 10.1186/s40538-023-00472-x | |
| 284. | Nooshzad Ahansaz, Armin Tarrah, Shadi Pakroo, Viviana Corich, Alessio Giacomini, Lactic Acid Bacteria in Dairy Foods: Prime Sources of Antimicrobial Compounds, 2023, 9, 2311-5637, 964, 10.3390/fermentation9110964 | |
| 285. | Yves Theoneste Murindangabo, Marek Kopecký, Kristýna Perná, Thi Giang Nguyen, Petr Konvalina, Miloslava Kavková, Prominent use of lactic acid bacteria in soil-plant systems, 2023, 189, 09291393, 104955, 10.1016/j.apsoil.2023.104955 | |
| 286. | F. I. Brigante, P. Solovyev, L. Bontempo, Nuclear Magnetic Resonance Applications in Fermented Foods and Plant-Based Beverages: Challenges and Opportunities, 2024, 40, 8755-9129, 3370, 10.1080/87559129.2024.2355271 | |
| 287. | Ronit Suissa, Tsviya Olender, Sergey Malitsky, Ofra Golani, Sondra Turjeman, Omry Koren, Michael M. Meijler, Ilana Kolodkin-Gal, Metabolic inputs in the probiotic bacterium Lacticaseibacillus rhamnosus contribute to cell-wall remodeling and increased fitness, 2023, 9, 2055-5008, 10.1038/s41522-023-00431-2 | |
| 288. | Silvia Ruta, Matthew Murray, Zoe Kampff, Brian McDonnell, Gabriele Andrea Lugli, Marco Ventura, Massimo Todaro, Luca Settanni, Douwe van Sinderen, Jennifer Mahony, Microbial Ecology of Pecorino Siciliano PDO Cheese Production Systems, 2023, 9, 2311-5637, 620, 10.3390/fermentation9070620 | |
| 289. | Larysa Bal-Prylypko, Svitlana Danylenko, Olena Mykhailova, Liana Nedorizanyuk, Alla Bovkun, Nataliia Slobodyanyuk, Alina Omelian, Anastasiia Ivaniuta, Influence of starter cultures on microbiological and physical-chemical parameters of dry-cured products, 2024, 18, 1337-0960, 313, 10.5219/1960 | |
| 290. | Hosam Elhalis, Xin Yi See, Raffael Osen, Xin Hui Chin, Yvonne Chow, The potentials and challenges of using fermentation to improve the sensory quality of plant-based meat analogs, 2023, 14, 1664-302X, 10.3389/fmicb.2023.1267227 | |
| 291. | M. S. Kanochkina, L. A. Ivanova, A. D. Konovalova, O. N. Levin, Features of the selection of starter cultures in the production of functional fermented milk products, 2023, 26, 1997-4736, 511, 10.21443/1560-9278-2023-26-4-511-528 | |
| 292. | Vikram Kumar, Ananya Rana, Prajakta Jagtap, Tejpal Dhewa, Neetu Kumra Taneja, 2023, 9781119808961, 21, 10.1002/9781394229116.ch2 | |
| 293. | Huaixiang Tian, Juanjuan Xiong, Haiyan Yu, Chen Chen, Xinman Lou, Flavor optimization in dairy fermentation: From strain screening and metabolic diversity to aroma regulation, 2023, 141, 09242244, 104194, 10.1016/j.tifs.2023.104194 | |
| 294. | Thomas Bintsis, Photis Papademas, The Application of Protective Cultures in Cheese: A Review, 2024, 10, 2311-5637, 117, 10.3390/fermentation10030117 | |
| 295. | Şehriban Oğuz, Seval Andiç, Isolation, identification, and characterization of thermophilic lactic acid bacteria isolated from whey of Kars Kashar cheeses, 2024, 117, 0003-6072, 10.1007/s10482-024-01982-w | |
| 296. | Yi Zhou, Qixian Feng, Yan Li, Yue Qi, Fulin Yang, Jing Zhou, Adding rumen microorganisms to improve fermentation quality, enzymatic efficiency, and microbial communities of hybrid Pennisetum silage, 2024, 410, 09608524, 131272, 10.1016/j.biortech.2024.131272 | |
| 297. | Jianwei Zang, Bingxu Yan, Haoyun Hu, Zebo Liu, Daobang Tang, Yuanzhi Liu, Jiguang Chen, Yonggang Tu, Zhongping Yin, RETRACTED: The current advances, challenges, and future trends of plant-based yogurt, 2024, 149, 09242244, 104531, 10.1016/j.tifs.2024.104531 | |
| 298. | Jielin Luo, Wending Chen, Yibo Pan, Qianqian He, Jianxia Sun, Weibin Bai, Unraveling the color evolution and metabolic pathways of pelargonidin-3-O-glucoside during lactic acid fermentation of the strawberry juice color simulation system: A novel perspective through untargeted metabolomics, 2025, 464, 03088146, 141740, 10.1016/j.foodchem.2024.141740 | |
| 299. | Mehmet Arif Icer, Sena Özbay, Duygu Ağagündüz, Bayram Kelle, Elena Bartkiene, João Miguel F. Rocha, Fatih Ozogul, The Impacts of Acidophilic Lactic Acid Bacteria on Food and Human Health: A Review of the Current Knowledge, 2023, 12, 2304-8158, 2965, 10.3390/foods12152965 | |
| 300. | Maeve Swinehart, Linda J. Harris, Nathan M. Anderson, Yaohua Feng, U.S. Consumer Practices of Homemade Nut-based Dairy Analogs and Soaked Nuts, 2023, 86, 0362028X, 100132, 10.1016/j.jfp.2023.100132 | |
| 301. | H.G. Batikyan, S.S. Mirzabekyan, N.H. Harutyunyan, A.Z. Pepoyan, ԿԱԹՆԱԹԹՎԱՅԻՆ ՆՈՐ ՊՐՈԲԻՈՏԻԿԱՅԻՆ ՇՏԱՄՆԵՐԻ ՀԻՄԱՆ ՎՐԱ ՍՏԱՑՎԱԾ ՅՈԳՈՒՐՏՆԵՐԻ ԿԵՆՍԱԱՆՎՏԱՆԳՈՒԹՅԱՆ ՄԻ ՇԱՐՔ ՑՈՒՑԱՆԻՇՆԵՐ, 2023, 2579-2822, 91, 10.52276/25792822-2023.1-91 | |
| 302. | Yuli Haryani, Nadrah Abd Halid, Goh Sur Guat, M A R Nor-Khaizura, Asyraf Hatta, Suriana Sabri, Son Radu, Hanan Hasan, Characterization, molecular identification, and antimicrobial activity of lactic acid bacteria isolated from selected fermented foods and beverages in Malaysia, 2023, 370, 1574-6968, 10.1093/femsle/fnad023 | |
| 303. | Xinjie Wang, Hongliang Lou, Xue Chen, Lijun Bu, Jiawei Chen, Huadong Xie, Investigation of the role of jiaotou in the processing of Jinhua Dajiao steamed bread using metagenomic and metabolomic analyses , 2024, 22, 1947-6337, 10.1080/19476337.2024.2375255 | |
| 304. | Mohammad Yaghoubi Khanghahi, Sabrina Strafella, Pasquale Filannino, Fabio Minervini, Carmine Crecchio, Importance of Lactic Acid Bacteria as an Emerging Group of Plant Growth-Promoting Rhizobacteria in Sustainable Agroecosystems, 2024, 14, 2076-3417, 1798, 10.3390/app14051798 | |
| 305. | Ahmed Radhi Jabbar, Ali Hussein Salman, Effect of Using Three Bacterial Isolates of Lactic Acid Bacteria Lactobacillus acidophilus 4453, Bifidobacterium bifidum 5144 and Streptococcus thermophilus 5935 as Probiotics on Thyroid Hormones and Liver Enzymes of Common Carp Fingerlings Cyprinus carpio Linnaeus (1758), 2023, 1225, 1755-1307, 012055, 10.1088/1755-1315/1225/1/012055 | |
| 306. | Daniel Abarquero, Ana Belén Flórez, María Eugenia Tornadijo, José María Fresno, Advantages and disadvantages of autochthonous enterococci strains for their potential use in cheese ripening: a preliminary study, 2024, 59, 0950-5423, 5675, 10.1111/ijfs.17295 | |
| 307. | Weiwei He, Hanne Christine Bertram, Jun-Yi Yin, Shao-Ping Nie, Lactobacilli and Their Fermented Foods as a Promising Strategy for Enhancing Bone Mineral Density: A Review, 2024, 72, 0021-8561, 17730, 10.1021/acs.jafc.4c03218 | |
| 308. | Ibaratkan Kurbanova, Lina Lauciene, Kristina Kondrotiene, Gintare Zakariene, Vitalijs Radenkovs, Sandra Kiselioviene, Alvija Salaseviciene, Agne Vasiliauskaite, Mindaugas Malakauskas, Mukarama Musulmanova, Loreta Serniene, Physicochemical, Sensory, and Microbiological Analysis of Fermented Drinks Made from White Kidney Bean Extract and Cow’s Milk Blends during Refrigerated Storage, 2024, 12, 2076-2607, 1832, 10.3390/microorganisms12091832 | |
| 309. | Archna Singh, Avijit Mazumder, Saumya Das, Pankaj Kumar Tyagi, M. V. N. L. Chaitanya, Probiotics in Action: Enhancing Immunity and Combatting Diseases for Optimal Health, 2024, 2320-3358, 1153, 10.18311/jnr/2024/35894 | |
| 310. | Dhananga Senanayake, Peter J. Torley, Jayani Chandrapala, Netsanet Shiferaw Terefe, Microbial Fermentation for Improving the Sensory, Nutritional and Functional Attributes of Legumes, 2023, 9, 2311-5637, 635, 10.3390/fermentation9070635 | |
| 311. | Rui Liu, A promising area of research in medicine: recent advances in properties and applications of Lactobacillus-derived exosomes, 2024, 15, 1664-302X, 10.3389/fmicb.2024.1266510 | |
| 312. | Jin Yong Kang, Moeun Lee, Jung Hee Song, Eun Ji Choi, So Yeong Mun, Daun Kim, Seul Ki Lim, Namhee Kim, Bo Yeon Park, Ji Yoon Chang, Organic acid type in kimchi is a key factor for determining kimchi starters for kimchi fermentation control, 2024, 10, 24058440, e36860, 10.1016/j.heliyon.2024.e36860 | |
| 313. | Mary S. Kalamaki, Myrsini N. Kakagianni, Apostolos S. Angelidis, Shifts in ovine (Ovis aries) bulk-tank milk microbiota as a function of cold-storage temperature and duration, 2024, 158, 09586946, 106032, 10.1016/j.idairyj.2024.106032 | |
| 314. | Núria Ferrer-Bustins, Jean Carlos Correia Peres Costa, Fernando Pérez-Rodríguez, Belén Martín, Sara Bover-Cid, Anna Jofré, The Antilisterial Effect of Latilactobacillus sakei CTC494 in Relation to Dry Fermented Sausage Ingredients and Temperature in Meat Simulation Media, 2024, 10, 2311-5637, 326, 10.3390/fermentation10060326 | |
| 315. | Bahman Panahi, Behnaz Dehganzad, Yousef Nami, CRISPR-Cas systems feature and targeting phages diversity in Lacticaseibacillus rhamnosus strains, 2023, 14, 1664-302X, 10.3389/fmicb.2023.1281307 | |
| 316. | Yun Ji Kang, Min Jae Kim, Tae Jin Kim, Jeong Hwan Kim, Characterization of Two Mannitol-Producing Leuconostoc Strains from Pa-Kimchi and Their Application for Juice and Yogurt Fermentation, 2023, 33, 1017-7825, 780, 10.4014/jmb.2301.01015 | |
| 317. | Sayen Merlin Sophia Sylvester, Sanjivkumar Muthusamy, Nagajothi Kasilingam, Parameswari Alagarsamy, 2024, Chapter 5, 978-1-0716-3420-2, 45, 10.1007/978-1-0716-3421-9_5 | |
| 318. | Ankit Bihola, Heena Sharma, M. B. Chaudhary, M. R. Bumbadiya, Deepak Kumar, Shaikh Adil, Recent developments in cheese technologies, 2024, 8755-9129, 1, 10.1080/87559129.2024.2426024 | |
| 319. | ||
| 320. | ||
| 321. | ||
| 322. | Mohammed A. Falih, Ammar B. Altemimi, Qausar Hamed Alkaisy, Farhang H. Awlqadr, Tarek Gamal Abedelmaksoud, Sajed Amjadi, Mohamad Ali Hesarinejad, Enhancing safety and quality in the global cheese industry: A review of innovative preservation techniques, 2024, 10, 24058440, e40459, 10.1016/j.heliyon.2024.e40459 | |
| 323. | Zubair Hashmi, Ibrahim Maina Idriss, Dawar Khalid, Syed Hassan Abbas, Syed Osama Ali, Mir Muhammad Bozdar, Tanzeel Usman, Muhammad Sameer Hamid, Nadeem Hussain Solangi, 2024, Chapter 6, 978-3-031-71130-5, 89, 10.1007/978-3-031-71131-2_6 | |
| 324. | Asif Ahmad, Shiza Atif, Khunsha Younas, Nabisab Mujawar Mubarak, 2024, Chapter 7, 978-3-031-71130-5, 131, 10.1007/978-3-031-71131-2_7 | |
| 325. | Christian Kosisochukwu Anumudu, Taghi Miri, Helen Onyeaka, Multifunctional Applications of Lactic Acid Bacteria: Enhancing Safety, Quality, and Nutritional Value in Foods and Fermented Beverages, 2024, 13, 2304-8158, 3714, 10.3390/foods13233714 | |
| 326. | ||
| 327. | ||
| 328. | ||
| 329. | ||
| 330. | ||
| 331. | ||
| 332. | ||
| 333. | Ardhendu Pal, Koushik Mondal, Soumen Mandal, Soumyadipta Chakraborty, Indrayani Patra, Manik Pradhan, LED-based broadband cavity-enhanced spectrometer for high-sensitive optical detection of diacetyl in gas phase, 2024, 136, 0973-7103, 10.1007/s12039-024-02324-z | |
| 334. | Domenico Giuffrè, Angelo Maria Giuffrè, Fermentation Technology and Functional Foods, 2024, 16, 1945-0494, 10.31083/j.fbe1601008 | |
| 335. | ||
| 336. | ||
| 337. | ||
| 338. | ||
| 339. | ||
| 340. | ||
| 341. | ||
| 342. | ||
| 343. | ||
| 344. | ||
| 345. | ||
| 346. | ||
| 347. | ||
| 348. | ||
| 349. | Gangavarapu Khaleel, Vijay Singh Sharanagat, Srishti Upadhyay, Shivani Desai, Kshitiz Kumar, Atul Dhiman, Rajat Suhag, Sustainable Approach Toward Biodegradable Packaging Through Naturally Derived Biopolymers: An Overview, 2024, 2520-1034, 10.1007/s41783-024-00180-3 | |
| 350. | ||
| 351. | ||
| 352. | ||
| 353. | ||
| 354. | ||
| 355. | ||
| 356. | ||
| 357. | ||
| 358. | ||
| 359. | ||
| 360. | ||
| 361. | ||
| 362. | ||
| 363. | ||
| 364. | Ahmed M. Abd El Tawab, Qinhua Liu, Gang Xu, Xuefeng Han, Feed additives strategies to control methanogenesis in ruminants, Review, 2024, 27, 2344-4592, 90, 10.2478/azibna-2024-0017 | |
| 365. | ||
| 366. | ||
| 367. | ||
| 368. | ||
| 369. | ||
| 370. | ||
| 371. | ||
| 372. | Mallari Praveen, Simone Brogi, Microbial Fermentation in Food and Beverage Industries: Innovations, Challenges, and Opportunities, 2025, 14, 2304-8158, 114, 10.3390/foods14010114 | |
| 373. | Mustafa Atasever, Halit Mazlum, Biochemical Processes During Cheese Ripening, 2024, 19, 2822-3608, 174, 10.17094/vetsci.1609184 | |
| 374. | ||
| 375. | ||
| 376. | ||
| 377. | ||
| 378. | ||
| 379. | ||
| 380. | ||
| 381. | Shailesh S. Sawant, Hye-Young Park, Eun-Young Sim, Hong-Sik Kim, Hye-Sun Choi, Microbial Fermentation in Food: Impact on Functional Properties and Nutritional Enhancement—A Review of Recent Developments, 2025, 11, 2311-5637, 15, 10.3390/fermentation11010015 | |
| 382. | ||
| 383. | ||
| 384. | ||
| 385. | ||
| 386. | ||
| 387. | ||
| 388. | ||
| 389. | ||
| 390. | ||
| 391. | ||
| 392. | ||
| 393. | ||
| 394. | ||
| 395. | ||
| 396. | Claudia Teso-Pérez, Areli López-Gazcón, Juan Manuel Peralta-Sánchez, Manuel Martínez-Bueno, Eva Valdivia, María Esther Fárez-Vidal, Antonio M. Martín-Platero, Bacteriocin-Producing Enterococci Modulate Cheese Microbial Diversity, 2024, 87, 0095-3628, 10.1007/s00248-025-02491-7 | |
| 397. | Katarzyna Waszkowiak, Agnieszka Makowska, Beata Mikołajczak, Kamila Myszka, Véronique J. Barthet, Magdalena Zielińska-Dawidziak, Dominik Kmiecik, Michalina Truszkowska, Fermenting of Flaxseed Cake with Lactiplantibacillus plantarum K06 to Increase its Application as Food Ingredient - the Effect on Changes in Protein and Phenolic Profiles, Cyanogenic Glycoside Degradation, and Functional Properties, 2025, 00236438, 117419, 10.1016/j.lwt.2025.117419 | |
| 398. | Diana Molina, Evelyn Angamarca, George Cătălin Marinescu, Roua Gabriela Popescu, Gabriela N. Tenea, Integrating Metabolomics and Genomics to Uncover Antimicrobial Compounds in Lactiplantibacillus plantarum UTNGt2, a Cacao-Originating Probiotic from Ecuador, 2025, 14, 2079-6382, 123, 10.3390/antibiotics14020123 | |
| 399. | Lu Feng, Jingxia Yang, Liping Sun, Xiaoyan Zhu, Wei Lan, Guangqing Mu, Xuemei Zhu, Changes of Unique Flavor Substances and Metabolic Pathway Brought by Lacticaseibacillus rhamnosus WH. FH-19 Fermented Milk during Fermentation and Storage Stage: HS-SPME-GC-MS and HPLC-MS-based Analysis, 2025, 22124292, 105974, 10.1016/j.fbio.2025.105974 | |
| 400. | ||
| 401. | ||
| 402. | ||
| 403. | ||
| 404. | ||
| 405. | ||
| 406. | Darly Silvana Parrado Saboya, Sebastián Lacheros, Juan Carlos Serrato, Evaluación de la producción de ácido láctico a partir de un clúster de microorganismos nativos de una biorrefinería colombiana, 2024, 26, 1909-8758, 8, 10.15446/rev.colomb.biote.v26n2.112366 | |
| 407. | ||
| 408. | ||
| 409. | ||
| 410. | ||
| 411. | ||
| 412. | ||
| 413. | ||
| 414. | ||
| 415. | Tanja Žugić Petrović, Vladimir M. Tomović, Katarina G. Marković, Teresa Semedo-Lemsaddek, Mirjana Ž. Grujović, Probiotics and Honey: Boosting Functional Properties in Dry Fermented Sausages, 2025, 13, 2076-2607, 349, 10.3390/microorganisms13020349 | |
| 416. | Lucas Filipe Almeida, Solimar Gonçalves Machado, Ramila Cristiane Rodrigues, Maria do Carmo Gouveia Peluzio, Tiago Antônio de Oliveira Mendes, Valéria Monteze Guimarães, Ronald de Vries, Gabriela Piccolo Maitan-Alfenas, Biotechnology approach for conversion of agro-industrial wastes into emerging source of xylooligosaccharides, 2025, 2190-6815, 10.1007/s13399-025-06584-8 | |
| 417. | ||
| 418. | ||
| 419. | ||
| 420. | ||
| 421. | ||
| 422. | ||
| 423. | ||
| 424. | Md. Tanvir Islam, M. Shaminur Rahman, Susmita Roy Chowdhury, Tanay Chakrovarty, S. M. Kador, Md. Mazharul Islam, Khondoker Tanjim Islam, Mohammad Imtiaj Uddin Bhuiyan, Ovinu Kibria Islam, Microbial diversity, functional attributes, and nutritional proficiency of yogurts produced in Bangladesh, 2025, 5, 2731-4286, 10.1007/s44187-025-00274-0 | |
| 425. | Mehtap Çiftçi, Nilgün Öncül, ARI POLENİ İLE ZENGİNLEŞTİRİLMİŞ PROBİYOTİK YOĞURTLARIN BAZI FİZİKOKİMYASAL ÖZELLİKLERİNİN BELİRLENMESİ, 2025, 50, 1300-3070, 131, 10.15237/gida.GD25013 | |
| 426. | Jiasheng Lu, Yumeng Sui, Xin Liu, Jiawang Wang, Jiatong Li, Baohua Kong, Qian Chen, Weiwei Yang, Effect of exogenous DPD on fermentation characteristics and flavour formation of Lactiplantibacillus plantarum HRB1 in vitro and in a dry sausage model: insights from the quorum sensing system, 2025, 00236438, 117516, 10.1016/j.lwt.2025.117516 | |
| 427. | ||
| 428. | ||
| 429. | ||
| 430. | ||
| 431. | ||
| 432. | ||
| 433. | ||
| 434. | Patrick Othuke Akpoghelie, Great Iruoghene Edo, Ali B.M. Ali, Emad Yousif, Khalid Zainulabdeen, Joseph Oghenewogaga Owheruo, Endurance Fegor Isoje, Ufuoma Augustina Igbuku, Arthur Efeoghene Athan Essaghah, Raghda S. Makia, Dina S. Ahmed, Huzaifa Umar, Ahmed A. Alamiery, Lactic acid bacteria: Nature, Characterization, Mode of action, Products and Applications, 2025, 13595113, 10.1016/j.procbio.2025.02.010 | |
| 435. | Anastasia Palatzidi, Olga Nikoloudaki, Ali Zein Alabiden Tlais, Emanuele Zannini, James A. O'Mahony, Effie Tsakalidou, Marco Gobbetti, Raffaella Di Cagno, Fermented Plant-Based Cream Cheese Analogues Formulated Using Legume Flours and Avocado pulp, 2025, 26668335, 100580, 10.1016/j.fufo.2025.100580 | |
| 436. | Nurhazwani Sa’aid, Joo Shun Tan, From probiotic fermentation to functional drinks: a review on fruit juices with lactic acid bacteria and prebiotics, 2025, 1082-6068, 1, 10.1080/10826068.2025.2467441 | |
| 437. | ||
| 438. | ||
| 439. | ||
| 440. | ||
| 441. | ||
| 442. | ||
| 443. | ||
| 444. | Mahdieh Iranmanesh, Mitesh Patel, Malvi Surti, Naheed Mojgani, 2025, Chapter 6, 978-981-97-9722-6, 145, 10.1007/978-981-97-9723-3_6 | |
| 445. | Tchouli Noufeu, Yueqin Li, Ndeye Fatou Toure, Hui Yao, Xiaoqun Zeng, Qiwei Du, Daodong Pan, Overview of Glycometabolism of Lactic Acid Bacteria During Freeze-Drying: Changes, Influencing Factors, and Application Strategies, 2025, 14, 2304-8158, 743, 10.3390/foods14050743 | |
| 446. | ||
| 447. | ||
| 448. | ||
| 449. | ||
| 450. | ||
| 451. | ||
| 452. | ||
| 453. | Xiaolu Zhou, Ziqian Zhu, Zihan Sun, Jiayi Xu, Xubiao Meng, Huixian Wang, Ruimin Wang, Fang Chen, Xiaosong Hu, Jiachao Zhang, The fermentation of carambola juice with lactic acid bacteria improves its flavor, bioactive properties, and metabolic composition, 2025, 22124292, 106307, 10.1016/j.fbio.2025.106307 | |
| 454. | ||
| 455. | ||
| 456. | ||
| 457. | ||
| 458. | ||
| 459. | ||
| 460. | ||
| 461. | ALİ SAĞLAM, Meltem AŞAN ÖZÜSAĞLAM, Chokeberry Extract: Inhibitory Activity on Some Lactic Acid Bacteria and the Growth Stimulative Effect on Limosilactobacillus fermentum MA-7, 2025, 6, 2706-9915, 1, 10.47419/bjbabs.v6i1.283 | |
| 462. | Lucie K. Tintrop, Marco Meola, Mireille T. Stern, Monika Haueter, Noam Shani, Hélène Berthoud, Barbara Guggenbühl Gasser, Pascal Fuchsmann, Analytical Mapping of Swiss Hard Cheese to Highlight the Distribution of Volatile Compounds, Aroma, and Microbiota, 2025, 0021-8561, 10.1021/acs.jafc.4c10980 | |
| 463. | Chaosheng Liao, Mingjie Zhang, Pan Wang, Xiaolong Tang, Minghong You, Changbing Zhang, Guofu Jia, Wenlong Gou, Ning Mao, Yixiao Xie, Chao Chen, Shiqie Bai, Ping Li, Advancing lactic acid Fermentation: Effects of micro aeration and herbal waste on red clover bioconversion, 2025, 509, 13858947, 161427, 10.1016/j.cej.2025.161427 | |
| 464. | ||
| 465. | ||
| 466. | ||
| 467. | ||
| 468. | ||
| 469. | ||
| 470. | ||
| 471. | ||
| 472. | ||
| 473. | ||
| 474. | ||
| 475. | ||
| 476. | ||
| 477. | ||
| 478. | Archna Singh, Avijit Mazumder, Saumya Das, Anmol Kanda, Pankaj Kumar Tyagi, MVNL Chaitanya, Harnessing the Power of Probiotics: Boosting Immunity and Safeguarding against Various Diseases and Infections, 2025, 20, 27724344, 5, 10.2174/0127724344308638240530065552 | |
| 479. | ||
| 480. | ||
| 481. | ||
| 482. | ||
| 483. | ||
| 484. | ||
| 485. | ||
| 486. | Shedrack Thomas Mgeni, Herieth Rhodes Mero, Lewis Atugonza Mtashobya, Jovine Kamuhabwa Emmanuel, Utilizing fruit wastes as a sustainable feedstock for bioethanol production: A Review, 2025, 27727831, 100188, 10.1016/j.cles.2025.100188 | |
| 487. | Slavica Vesković, 2025, Chapter 4, 978-3-031-85088-2, 133, 10.1007/978-3-031-85089-9_4 | |
| 488. | Min Li, Wei Zhao, Huimin Lv, Qiong Wu, Jicheng Wang, Zhihong Sun, Genetic, epigenetic, and metabolic remodeling of Lacticaseibacillus paracasei PC-01 in response to space conditions, 2025, 22124292, 106454, 10.1016/j.fbio.2025.106454 | |
| 489. | ||
| 490. | ||
| 491. | ||
| 492. | ||
| 493. | ||
| 494. | ||
| 495. | ||
| 496. | ||
| 497. | ||
| 498. | ||
| 499. | ||
| 500. | ||
| 501. | ||
| 502. | ||
| 503. | ||
| 504. | ||
| 505. | ||
| 506. | ||
| 507. | ||
| 508. | ||
| 509. | ||
| 510. | Daniel Kuhn, Caroline Schmitz, Gabriela Rabaioli Rama, Manuela Araujo Costa, Priscilla Romina De Gregorio, José Matías Irazoqui, Ariel Fernando Amadio, Angiolella Lombardi, Vera Lúcia Milani Martins, Daiane Heidrich, Simone Beux, Daniel Neutzling Lehn, Lucélia Hoehne, Claucia Fernanda Volken de Souza, Exploring endogenous lactic acid bacteria potential: Isolation to genetic insights on aromatic compounds, 2025, 131, 07400020, 104800, 10.1016/j.fm.2025.104800 | |
| 511. | Abdelaziz Elbarbary, Jun Jin, Kangning Li, Hazem Golshany, Abdullah S. Seddiek, Ibrahim A. Bakry, Xingguo Wang, Understanding the flavor dynamics of high-fat dairy products: Insights into mechanisms, aroma profiles, and sensory evaluation, 2025, 09639969, 116504, 10.1016/j.foodres.2025.116504 | |
| 512. | Yuxin Gan, Jinxi Cui, Aoxuan Nie, Yuxia Yang, Xiuhong Zhao, Revealing the influence of Lacticaseibacillus paracasei C5 on the flavor formation of bread dough by metagenomics and flavouromics, 2025, 437, 01681605, 111220, 10.1016/j.ijfoodmicro.2025.111220 | |
| 513. | ||
| 514. | ||
| 515. | ||
| 516. | ||
| 517. | ||
| 518. | ||
| 519. | ||
| 520. | Maosi Fan, Xuelian He, Yating Cao, Kalekristos Yohannes Woldemariam, Min Cai, Zhengkai Wang, Yushan Jiao, Wensheng Tang, Xiaoming Wei, Yingli Liu, Jing Wang, Sustainable Microbial Fermentation of Plant Proteins: Potential, Biological Resources, Fermentation Mechanisms, Applications and Challenges in Food Industry, 2025, 22124292, 106727, 10.1016/j.fbio.2025.106727 | |
| 521. | O C Nwinyi, Z. G Dango, Probiotics Potentials of Fermented Rice for Sustainable Health and Well-being, 2025, 1492, 1755-1307, 012003, 10.1088/1755-1315/1492/1/012003 | |
| 522. | ||
| 523. | ||
| 524. | ||
| 525. | ||
| 526. | ||
| 527. | ||
| 528. | ||
| 529. | ||
| 530. | ||
| 531. | ||
| 532. | ||
| 533. | ||
| 534. | ||
| 535. | ||
| 536. | Batchimeg Namshir, Gil-Ha Kim, Natsag Lkhagvasuren, Seon-A Jeong, Narangerel Mijid, Woan-Sub Kim, Fermentation and Functional Properties of Plant-Derived Limosilactobacillus fermentum for Dairy Applications, 2025, 11, 2311-5637, 286, 10.3390/fermentation11050286 | |
| 537. | Monisha Nath, Ankita Gon, Arnab Chakraborty, Soma Das, 2025, Chapter 3, 978-3-031-85204-6, 51, 10.1007/978-3-031-85205-3_3 | |
| 538. | Abdullah Ahmed Butt, Hafiza Saima, 2025, Chapter 11, 978-3-031-85204-6, 247, 10.1007/978-3-031-85205-3_11 | |
| 539. | Rajdeep Mohanta, Souvik Chakraborty, Payal Maiti, 2025, Chapter 10, 978-3-031-85204-6, 229, 10.1007/978-3-031-85205-3_10 | |
| 540. | ||
| 541. | ||
| 542. | ||
| 543. | ||
| 544. | ||
| 545. | ||
| 546. | Martina Banić, Katarina Butorac, Nina Čuljak, Jasna Novak, Andreja Leboš Pavunc, Diana Nejašmić, Ljiljana Zovko, Katarina Tonković, Jagoda Šušković, Blaženka Kos, A comparative HS-SPME-GC–MS-based volatile fingerprint analysis of newly developed milk beverages fermented with autochthonous and commercial cultures, 2025, 488, 03088146, 144845, 10.1016/j.foodchem.2025.144845 | |
| 547. | ||
| 548. | ||
| 549. | ||
| 550. | ||
| 551. | ||
| 552. | ||
| 553. | ||
| 554. | ||
| 555. | Jiangyang Zhai, Wenjing Zhen, Mirco Corazzin, Jianjun Tian, Yue Gu, Impact of autoinducer-2 activity on quality characteristics and bacterial community of fermented sausage, 2025, 440, 01681605, 111285, 10.1016/j.ijfoodmicro.2025.111285 | |
| 556. | Rohit Das, Buddhiman Tamang, Anil Bhattarai, Ishfaq Nabi Najar, Novel L-asparaginase from Paucilactobacillus vaccinostercus: Insights into anti-cancer potential using metagenomic, molecular docking and molecular dynamics simulation, 2025, 7, 29501946, 100390, 10.1016/j.microb.2025.100390 | |
| 557. | Gizem Tiryaki, Emine Nakilcioğlu, Meyve Bazlı Probiyotiklere Genel Bir Bakış, 2025, 12, 2458-7575, 344, 10.35193/bseufbd.1453071 | |
| 558. | ||
| 559. | ||
| 560. | ||
| 561. | ||
| 562. | ||
| 563. | ||
| 564. | ||
| 565. | Arshad Mehmood, Maurizio Battino, Xiumin Chen, 1-Deoxynojirimycin: a comprehensive review of sources, biosynthesis pathways, strategies to enhance its production, and anti-diabetic activities, 2025, 2042-6496, 10.1039/D4FO04954C | |
| 566. | Reona Murata, Youn Young Shim, Young Jun Kim, Martin J. T. Reaney, Timothy J. Tse, Exploring lactic acid bacteria in food, human health, and agriculture, 2025, 1040-8398, 1, 10.1080/10408398.2025.2493236 | |
| 567. | Bilal Murtaza, Ling-ling Guo, Lili Wang, Xiaoyu Li, Liaqat Zeb, Bowen Jin, Ji-bin Li, Yongping Xu, Innovative probiotic fermentation approach for zearalenone detoxification in dried distiller’s grains, 2025, 16, 1664-302X, 10.3389/fmicb.2025.1533515 | |
| 568. | ||
| 569. | ||
| 570. |
Julius Nickelsen, Olaf Stotz. Do fund managers in the Chinese mutual fund market deliver positive risk-adjusted returns? Yes, but it is mainly observed for local fund managers[J]. Quantitative Finance and Economics, 2023, 7(4): 595-621. doi: 10.3934/QFE.2023029
| Student R. | Student G. | |||||
| Examination stage | Ⅰ | Ⅳ | Ⅴ | Ⅰ | Ⅳ | Ⅴ |
| Left hemisphere activation index | 97 | 158 | 21 | 14 | 27 | 30 |
| Left hemisphere dominance | 42% | 90% | 33% | 18% | 30% | 70% |
| Right hemisphere activation index | 38 | 20 | 100 | 30 | 39 | 22 |
| Right hemisphere dominance | 33% | 10% | 42% | 82% | 70% | 70% |
| KL/R | 0.4 | 0.7 | -0.6 | -0.3 | -0.2 | 0.5 |
| KA/P | 0.7 | 0.8 | 0.7 | -0.3 | -0.07 | 0.3 |
| Heart-rate (bpm) | 73 | 85 | 69 | 105 | 125 | 95 |
| FAMai | 6.0 | 4.5 | 2.2 | 5.3 | ||
| Hemispheric activation indices are in conditional units (Appendix 2). Ⅰ, Ⅳ, Ⅴ—stage of experiment; KL/R—bilateral asymmetry index; KA/P—anterio-posterior asymmetry index; FAMai—FAM-test averaged scale index. Subject R. received an excellent evaluation, subject G.—poor evaluation | ||||||
DownLoad: CSV| Measurement time | Average FAM scores in general program | Average FAM scores in differential program |
| Regular day | 5.24 ± 0.22 | 5.09 ± 0.19 |
| Pre-exam | 5.10 ± 0.25 | 4.85 ± 0.17 |
| Post-exam | 4.99 ± 0.25 | 4.95 ± 0.29. |
| FAM: Feeling, activity mood (test) | ||
DownLoad: CSV| Student R. | Student G. | |||||
| Examination stage | Ⅰ | Ⅳ | Ⅴ | Ⅰ | Ⅳ | Ⅴ |
| Left hemisphere activation index | 97 | 158 | 21 | 14 | 27 | 30 |
| Left hemisphere dominance | 42% | 90% | 33% | 18% | 30% | 70% |
| Right hemisphere activation index | 38 | 20 | 100 | 30 | 39 | 22 |
| Right hemisphere dominance | 33% | 10% | 42% | 82% | 70% | 70% |
| KL/R | 0.4 | 0.7 | -0.6 | -0.3 | -0.2 | 0.5 |
| KA/P | 0.7 | 0.8 | 0.7 | -0.3 | -0.07 | 0.3 |
| Heart-rate (bpm) | 73 | 85 | 69 | 105 | 125 | 95 |
| FAMai | 6.0 | 4.5 | 2.2 | 5.3 | ||
| Hemispheric activation indices are in conditional units (Appendix 2). Ⅰ, Ⅳ, Ⅴ—stage of experiment; KL/R—bilateral asymmetry index; KA/P—anterio-posterior asymmetry index; FAMai—FAM-test averaged scale index. Subject R. received an excellent evaluation, subject G.—poor evaluation | ||||||
| Measurement time | Average FAM scores in general program | Average FAM scores in differential program |
| Regular day | 5.24 ± 0.22 | 5.09 ± 0.19 |
| Pre-exam | 5.10 ± 0.25 | 4.85 ± 0.17 |
| Post-exam | 4.99 ± 0.25 | 4.95 ± 0.29. |
| FAM: Feeling, activity mood (test) | ||
