Loading [Contrib]/a11y/accessibility-menu.js
Search Advanced

AIMS Agriculture and Food

2021, Volume 6, Issue 3: 864-878. doi: 10.3934/agrfood.2021052
Previous Article Next Article
Research article

Physicochemical, functional properties and antioxidant activity of protein extract from spent coffee grounds using ultrasonic-assisted extraction

  • 1.
    Department of Applied Biology, Faculty of Sciences and Liberal Arts, Rajamangala University of Technology Isan, Nakhon Ratchasima, 30000 Thailand
  • 2.
    Department of Food Engineering, Faculty of Engineering at Kamphaengsaen, Kasetsart University, Kamphaengsaen Campus, Nakhon Pathom, 73140 Thailand

  • Spent coffee grounds, the residue from coffee brewing, are still underutilized even though they contain several useful organic compounds including proteins. To valorize the spent coffee grounds, the spent coffee ground protein was investigated using ultrasonic-assisted extraction as a pretreatment to conventional extraction. The pretreatments involved different ultrasound amplitudes (40%, 60% and 80%) and extraction times (10, 20 and 30 min) and their effects on the physicochemical and functional properties including antioxidant activity of protein extract. It was found that the protein content extracted was increased approximately 2 times, compared to the initial spent coffee grounds. Furthermore, the ultrasonic-assisted extraction affected the physicochemical properties, functional properties and antioxidant activity of the protein extract. The 80% amplitude for 10 min extraction time improved the foaming capacity, foaming stability, emulsifying activity index and the emulsifying stability index of protein extract. The pretreatment at 20 min extraction time provided the highest antioxidant activity (933.92-976.03 mM Trolox eq/g protein extract) and the highest total phenolic content (267.66-304.81 mg GAE/g protein extract). Nonetheless, protein extract using ultrasonic-assisted extraction resulted in higher total phenolic content and antioxidant activity without changes in the protein structure as confirmed by changes in FT-IR spectra and SDS-PAGE profiles. Thus, the spent coffee ground protein can be an interesting and alternative plant protein with functional properties for food application. Moreover, this work showed the feasibility to reduce waste and the food waste valorization.

    Citation: Namfon Samsalee, Rungsinee Sothornvit. Physicochemical, functional properties and antioxidant activity of protein extract from spent coffee grounds using ultrasonic-assisted extraction[J]. AIMS Agriculture and Food, 2021, 6(3): 864-878. doi: 10.3934/agrfood.2021052

    Related Papers:

    [1] Namfon Samsalee, Rungsinee Sothornvit . Different novel extraction techniques on chemical and functional properties of sugar extracts from spent coffee grounds. AIMS Agriculture and Food, 2022, 7(4): 897-915. doi: 10.3934/agrfood.2022055
    [2] Naima Belguedj, Ghayth Rigane, Ridha Ben Salem, Khodir Madani . Conventional and eco-friendly aqueous extraction methods of date palm fruit compounds: Optimization, comparison, characterization of the date pulp extract and value-added potential. AIMS Agriculture and Food, 2025, 10(1): 218-246. doi: 10.3934/agrfood.2025012
    [3] Albert Nugraha, Asadin Briliantama, M Umar Harun, Li Sing-Chung, Chin Xuan Tan, Vuanghao Lim, Amir Husni, Widiastuti Setyaningsih . Ultrasound-assisted extraction of phenolic compounds from ear mushrooms (Auricularia auricula-judae): Assessing composition and antioxidant activity during fruiting body development. AIMS Agriculture and Food, 2024, 9(4): 1134-1150. doi: 10.3934/agrfood.2024059
    [4] Marlin Marlin, Marulak Simarmata, Umi Salamah, Waras Nurcholis . Effect of nitrogen and potassium application on growth, total phenolic, flavonoid contents, and antioxidant activity of Eleutherine palmifolia. AIMS Agriculture and Food, 2022, 7(3): 580-593. doi: 10.3934/agrfood.2022036
    [5] Pham Thi Thu Ha, Nguyen Thi Bao Tran, Nguyen Thi Ngoc Tram, Vo Hoang Kha . Total phenolic, total flavonoid contents and antioxidant potential of Common Bean (Phaseolus vulgaris L.) in Vietnam. AIMS Agriculture and Food, 2020, 5(4): 635-648. doi: 10.3934/agrfood.2020.4.635
    [6] Olukemi Osukoya, Adewale Fadaka, Olusola Adewale, Oluwatobi Oluloye, Oluwafemi Ojo, Basiru Ajiboye, Deborah Adewumi, Adenike Kuku . In vitro anthelmintic and antioxidant activities of the leaf extracts of Theobroma cacao L.. AIMS Agriculture and Food, 2019, 4(3): 568-577. doi: 10.3934/agrfood.2019.3.568
    [7] Thornthan Sawangwan, Chompoonuth Porncharoennop, Harit Nimraksa . Antioxidant compounds from rice bran fermentation by lactic acid bacteria. AIMS Agriculture and Food, 2021, 6(2): 578-587. doi: 10.3934/agrfood.2021034
    [8] Ebrahim Falahi, Zohre Delshadian, Hassan Ahmadvand, Samira Shokri Jokar . Head space volatile constituents and antioxidant properties of five traditional Iranian wild edible plants grown in west of Iran. AIMS Agriculture and Food, 2019, 4(4): 1034-1053. doi: 10.3934/agrfood.2019.4.1034
    [9] María Cámara-Ruiz, José María García Beltrán, Francisco Antonio Guardiola, María Ángeles Esteban . In vitro and in vivo effects of purslane (Portulaca oleracea L.) on gilthead seabream (Sparus aurata L.). AIMS Agriculture and Food, 2020, 5(4): 799-824. doi: 10.3934/agrfood.2020.4.799
    [10] Patrick A. Blamo Jr, Hong Ngoc Thuy Pham, The Han Nguyen . Maximising phenolic compounds and antioxidant capacity from Laurencia intermedia using ultrasound-assisted extraction. AIMS Agriculture and Food, 2021, 6(1): 32-48. doi: 10.3934/agrfood.2021003

  • Spent coffee grounds, the residue from coffee brewing, are still underutilized even though they contain several useful organic compounds including proteins. To valorize the spent coffee grounds, the spent coffee ground protein was investigated using ultrasonic-assisted extraction as a pretreatment to conventional extraction. The pretreatments involved different ultrasound amplitudes (40%, 60% and 80%) and extraction times (10, 20 and 30 min) and their effects on the physicochemical and functional properties including antioxidant activity of protein extract. It was found that the protein content extracted was increased approximately 2 times, compared to the initial spent coffee grounds. Furthermore, the ultrasonic-assisted extraction affected the physicochemical properties, functional properties and antioxidant activity of the protein extract. The 80% amplitude for 10 min extraction time improved the foaming capacity, foaming stability, emulsifying activity index and the emulsifying stability index of protein extract. The pretreatment at 20 min extraction time provided the highest antioxidant activity (933.92-976.03 mM Trolox eq/g protein extract) and the highest total phenolic content (267.66-304.81 mg GAE/g protein extract). Nonetheless, protein extract using ultrasonic-assisted extraction resulted in higher total phenolic content and antioxidant activity without changes in the protein structure as confirmed by changes in FT-IR spectra and SDS-PAGE profiles. Thus, the spent coffee ground protein can be an interesting and alternative plant protein with functional properties for food application. Moreover, this work showed the feasibility to reduce waste and the food waste valorization.


    1. Introduction

    Since 1997, genetic testing of BRCA1 and BRCA2 has been offered to selected women in various clinical contexts, internationally. For the vast majority of women (~80%), these tests are uninformative as they do not identify pathogenic mutation in either of these genes. Today commercial and public diagnostic testing facilities are including a larger number of “breast cancer susceptibility genes” identified by continued research, in a single test, at considerably reduced cost [1,2].

    The transition of massively parallel sequencing (or next generation sequencing) into molecular diagnostics has enabled a technical revolution in the way that molecular diagnostic testing can be performed. It is now a reality that a gene-panel test can be applied at the same, or lower, laboratory cost than the single-gene analyses that have been conducted for the past two decades.

    Today, many public and commercial (including direct-to-the-public) testing facilities are using these panels to provide tests for genetic susceptibility to breast (and other) cancer(s). In several areas of clinical genetics, such as Sudden Cardiac Death, panel testing is now considered standard of care [3].

    The genes currently included in commercial breast cancer susceptibility gene panels (in addition to BRCA1 and BRCA2) vary between laboratory/company, are numerous, and range from breast cancer predisposition genes that are now well characterised (e.g. PALB2, ATM, CHEK2) to genes that are putative breast cancer predisposition genes and lack extensive (sometimes any) validation (e.g. BARD1, BRIP1) [1]. It is not infrequent that women obtain these tests before attending genetic clinic, and come to clinic seeking advice. These gene-panel tests pose considerable challenge to clinical genetic services, as very little is known about the cancer risks associated with almost all of the observed genetic variation [1,4].How can this data currently be interpreted and what initiatives are likely to improve these interpretations in the future?

    2. Rare variants and BRCA1 and BRCA2

    Clinical genetics services embraced testing for rare genetic variants (minor allele frequency <1%) in BRCA1 and BRCA2 very shortly after these genes were identified and genetic tests have demonstrated clinical validity and utility. Research has since defined the (average) penetrance of protein truncating mutations in these genes (BRCA1, 67% (95% CI = 36-83); BRCA2, 43% (95% CI = 14-62) to age 70 years) [5]. More recent international collaboration has enabled a broader appreciation of the spectrum of risks associated with some of the genetic variation occurring in BRCA1 and BRCA2 that has challenged and changed some of the assumptions made nearly two decades ago. Most notable observations are the characterisation of genetic variants associated with more moderate risk of breast cancer (e.g. BRCA1, R1699Q, 25% (95% CI=10-40%) to age 70 years [6,7]) and variants associated with very small increase in risk of breast cancer (e.g. BRCA2, K3326*, OR 1.26 (95% CI=1.14-1.39) p = 5.7 x 10-6) [8,9].

    3. Additional genes included on gene panel tests

    At the time of writing, the definition of, or at least the clinical, diagnostic and research community’s interpretation of, what is and what is not a breast cancer susceptibility gene is somewhat variable. A review of the numerous breast cancer susceptibility gene panels currently available reveals that 18 genes are consistently included. In addition to BRCA1 and BRCA2, these are ATM, BARD1, BRIP1, CDH1, CHEK2, FANCM, MRE11A, MUTYH, NBN, NF1, PALB2, PTEN, RAD50, RAD51C, STK11 and TP53 (Table 1). The evidence for mutations in these genes being associated with breast cancer risk is variable and has been extensively reviewed elsewhere (e.g. [1]). Although the reasons for the inclusion of some of these genes are inconsistent, they are the genes for which women are being tested and more information is required, both related to breast cancer risk and the risk for a range of other cancers which may not have been considered by testing clinicians.

    Table 1. Breast cancer susceptibility genes commonly included in gene panel testing.
    Gene NameProtein FunctionMagnitude of Breast Cancer RiskRef
    PALB2Homologous recombination DNA repairAverage cumulative risk 35%[10]
    (95% CI = 26%-46%) by age 70
    ATMHomologous recombination DNA repairAverage cumulative risk 52% [50]
    (95% CI = 28-80%) by age 70
    ATM c.7271T>G only
    BARD1Essential to BRCA1 stabilityUnknown[51]
    Homologous recombination DNA repair
    BRIP1Binds to BRCA1 2-fold (not replicated)[52]
    Homologous recombination DNA repair
    CDH1E-Cadherin, cell to cell adhesionUnknown [53]
    CHEK2Responds to DNA damage Approx. 2-fold (based on one mutation *1100delC)[23]
    Involved in cell cycle arrest
    NBN/NBS1Part of MRE11/RAD50 double strand break repair complex3-fold (population specific studies)[54]
    MRE11APart of MRE11/RAD50 double strand break repair complexUnknown [55]
    RAD50Part of MRE11/RAD50 double strand break repair complexUnknown [55]
    MUTYHBase excision repair<2[56]
    NF1Control of cell division5-fold under age 50 years [57]
    (95% CI = 2.4-8.8)
    PTENA hydrolases, acting on phosphoric monoester bondsUnknown[58,59]
    RAD51CRecombination DNA repair and meiotic recombination. Unknown[60,61]
    STK11Serine/Threonine kinaseRelative risk 20.3[62]
    Regulates cell polarity
    TP53DNA stability Unknown[63,64]
    XRCC2Homologous recombination DNA repairUnknown[65]
    RINT1RAD50-interacting protein involved in G2-M checkpointOR 3.24; 95% CI = 1.29-8.17; [66]
    P = 0.013
    FANCMRepairs DNA at stalled replication forksOR 1.86, 95% CI = 1.26-2.75[67]
    FANCM c.5101C>T only
    OR: Odds Ratio
    CI: Confidence Interval
     | Show Table
    DownLoad: CSV

    PALB2 is now regarded as a bona fide breast cancer predisposition gene and is justifiably included on current breast cancer predisposition gene testing panels [10]. PALB2 is an exemplar gene for the acquisition of appropriate data, from which new clinical guidelines were written and genetic information was translated into clinical genetics practice, as described below.

    4. PALB2: demonstrating the capacity of international collaborations

    Mutations in PALB2 make a small contribution to heritable breast cancer susceptibility in most populations [10,11,12,13,14,15,16,17,18]. To consider penetrance of a larger number of PALB2 genetic variants and a larger number of families, the PALB2 Interest Group embarked on a collaborative effort that collected data from 362 members of 154 families who had deleterious truncating, splice, or deletion mutations in PALB2. The average cumulative risk of breast cancer was estimated to be 14% (95% CI = 9%-20%) by age 50 and 35% (95% CI = 26%-46%) by age 70 [10]. Thus, all published estimates of penetrance of PALB2 mutations are comparable to the risk associated with BRCA2 mutations: 45% (95% CI = 31-56%) [5].

    However, unlike BRCA1 and BRCA2, there is no evidence that missense variants in PALB2 as a group are associated with risk of breast cancer [19]. On a variant-by-variant basis, it is difficult to assess this category of variants and provide any information for use in clinical genetics for the individual.

    It is apparent that large international collaborative studies are required to provide the evidence on which two fundamental criteria can be met for the majority of genes included in breast cancer susceptibility panel tests - that is, i) validating the genes as bona fide breast cancer predisposition genes, with clear clinical utility and ii) interpreting the variation, on a variant-by-variant basis in terms of their likely “pathogenicity”. Neither of these fundamental steps have been achieved for the majority of genes included on the panels. There is therefore a need to extend international efforts that are currently trying to classify rare variants identified in BRCA1 andBRCA2 to include rare variants identified in PALB2 and other susceptibility genes, to assist the clinical management of the individuals who carry them.

    5. The challenge of interpreting missense variants

    It is now generally accepted that protein-truncating variants in tumour suppressor genes, with the exception of those occurring in the last coding exon, are associated with loss of function and pathogenicity. This type of variant dominates the spectra of BRCA1 and BRCA2 mutations that are classified as pathogenic. This attitude is reflected in variant classification schemas that generally require evidence against pathogenicity to move any protein-truncating genetic variant from a pathogenic class allocation. Conversely, classification schemas generally require several lines of evidence for pathogenicity before a missense variant can be classified (that is, outside of the “default” unclassified variant category) [20].

    Early work in the context of estimating breast cancer risk associated with protein truncating mutations in BRCA1 and BRCA2 demonstrated that protein-truncating mutations (as a group, on average) and missense mutations (as a group, on average) are associated with at least as high risk for breast cancer (83% (95% CI = 40-100%) to age 70 years) [21]. Similarly, it has been demonstrated that for genes such as ATM and CHEK2, the breast cancer risk fraction contributed by missense variants is as high, if not higher, than protein-truncating variants [22,23]. Missense substitutions may result in a variant protein with function that is entirely normal through to completely disrupted, thus these groups of missense variants are highly likely to be made up of mutations with differing levels of associated risks (some probably have no associated breast cancer risk) ― but which ones are associated with high, perhaps very high, risk? This is a critical question and one that is not limited to the classification of BRCA1 and BRCA2 genetic variants when attempting to personalise genetic information for women attending clinical genetics services seeking advice for risk management.

    To personalise heritable risk due to breast cancer predisposition gene mutations, average risk across a group of variants is insufficient, and the provision of variant specific risk estimation is required. Currently we rely on assumptions that have enabled generalisations across mutation types that have proven validity and utility for some groups of mutations (e.g. protein-truncating mutations) but the classification of missense variants poses a great challenge to this process. As a consequence, in clinical genetic testing, missense variants are generally reported as unclassified variants (UVs) or variants of unknown significance (VUSs) and are not informative for the patients. Clinicians seek clarity, since the use of variants in practice demands certainty.

    6. In-silico assessment of missense variants

    A large number of methodologies and tools are available to analyse missense variants and their effects on cellular localisation, aggregation, folding aggregation, stability and functional effects. These methods include sequence- and structure-based analyses and are reviewed in Thusberg and Vihinen, 2009 [24].

    In regards to in-silico pathogenicity prediction of missense substitutions, it has been demonstrated since the 1960s that conservation of specific sequences during evolution is indicative of functional constraints and that pathogenic missense substitutions tend to occur at evolutionary-conserved positions [25,26]. In-silico pathogenicity prediction methods use sequence and/or structural information to assess the functional consequence of a missense substitution on protein function. All evolutionary history-based methods rely on i) the construction of a multiple sequence alignment (MSA), preferably including orthologous sequences for increased accuracy [27] and ii) the assessment of the fitness of the missense variants relative to the pattern observed in the evolutionary history, using positional conservation measures and/or probabilistic scoring algorithms. Some methods such as SIFT and PMUT (a web-based tool for the annotation of pathological mutations on proteins) are based on phylogenic information computed along with sequence

    weights [28,29]. Other methods rely on a pre-calculated phylogenic tree (LRT, [30]) or combine structural information with the MSA to increase prediction accuracy (PolyPhen2 [31]). Align-GVGD and SNAP (screening for non-acceptable polymorphisms)combine information about the biophysical characteristics of the wild-type and substituted residue with evolutionary information [32,33]. Most tools return a prediction on whether a missense variant is pathogenic or not; Align-GVGD provides a ranking of missense substitutions into seven classes, from least likely (C0) to most likely (C65) pathogenic.

    7. The integrated evaluation of unclassified variants

    The first quantitative classification model for UVs was described by Goldgar et al. (2004) and relied on personal and family cancer history to calculate a likelihood ratio in favour of

    pathogenicity [34]. The current integrated evaluation approach (or multifactorial method), developed by the Breast cancer Information Core (BIC) over the last decade, relies on a Bayesian framework combining a sequence analysis-based prior probability in favour of pathogenicity with likelihood ratios in favour of pathogenicity derived from four types of observational data: co-segregation of UVs with cancer phenotype, with known pathogenic mutations, and tumour immuhistochemistry and histological grade [35,36,37]. The prior probability in favour of pathogenicity is computed for each class of variants output by the in-silico program Align-GVGD calibrated using personal and family history data from Myriad Genetics Laboratory. The result of the integrated evaluation is a posterior probability in favour of pathogenicity, which is a continuous variable ranging from 0.00 to 1.00 supplemented by a five-category classification table that provides a clinically useful translation from the posterior probability to a qualitative system meant for use by clinical cancer geneticists and genetic counsellors [20]. At the third Human Variome Project (HVP) meeting (UNESCO, Paris 2010), this classification table, also referred to as the “IARC 5-class” table, was accepted as an HVP standard.

    8. ENIGMA: The Evidence-based Network for the Interpretation of Germline Mutant Alleles

    Although the classification of BRCA1 and BRCA2 variants has greatly benefited from empirical data obtained from ~90,000 patients screened at Myriad Genetics Laboratories, the interpretation of UVs in BRCA1 and BRCA2 remains complex. The Evidence-based Network for the Interpretation of Germline Mutant Alleles (ENIGMA) is an international consortium that was established to address the challenge of classifying UVs in BRCA1 and BRCA2 [38]. Reclassification efforts are more advanced for BRCA1 and BRCA2 than for other genes. Vallee et al. (2012) have extracted 248 BRCA1 and BRCA2 missense substitutions and have created a database of former UVs (Ex-UVs) following re-assessment of all the missense substitutions under the updated multifactorial evaluation model [39].

    However, with testing of other breast cancer susceptibility genes becoming more widespread, ENIGMA and other similar international collaborations will have to try to address the issue of accumulation of UVs in the expended set of genes included in gene panels. Application of the integrated evaluation approach will be more problematic for intermediate-riskgenes/mutations because they are likely to have weaker segregation patterns and summary family cancer history than high-risk genes/mutations.

    In addition, variants are individually rare and the magnitude of risk conferred by variant alleles can vary widely. The assessment of UVs in these genes will require a classification model that integrates functional data into the multifactorial models.

    9. Functional assays

    Functional assays revolve around the concept that since inherited sequence alterations causing the loss of function of tumour suppressor genes are usually associated with cancer predisposition, detecting a decrease of tumour suppressor activity likely indicates elevated cancer predisposition. Consequently, laboratory tests are designed to quantify any alterations in the activity of a tumour suppressor variant [40]. A number of functional assays have been developed for BRCA1 and BRCA2 [6,41], and for ATM, CHEK2 and TP53 missense variants [42,43,44]. Iversen et al. (2011) and Guidugli et al. (2013) have developed functional assays that include recalibration with neutral and pathogenic mutations in the BRCT and DNA binding domains of BRCA1 and BRCA2, respectively [45,46].

    These assays can be used to classify UVs occurring in these regions and will assist in classifying variants when little family history is available for the integrated evaluation. However, calibrated assays do not exist for most domains or functions of most genes. Variant classification models will only be enhanced by the integration of functional assays once i) these assays achieve sufficient accuracy, reproducibility and efficiency to contribute to UVs classification and ii) the assay outputs can properly be recalibrated into odds ratios in favour of pathogenicity. In the absence of robust missense classification models, a large fraction of the genetic variants identified during gene panel testing will remain in the UVs category, which might lead to missing a considerable fraction of bona fide genetic risk.

    10. Classification for clinical reporting and consistent clinical interpretation and management

    Efforts to classify rare variants identified in cancer predisposition genes have been ongoing for some time. Some increased consistency of interpretation and reporting has been achieved by efforts to align with other standardised reporting systems used in oncology [37]. Indeed, it is anticipated that in parallel to a shift from single-gene to panel-gene testing, there will be necessary changes to the testing process that will involve an increased clinical contribution from non-geneticists. This oncogenetic model of genetic testing may see genetic testing conducted as routine by multidisciplinary teams that only refer individuals with “actionable” mutations to clinical genetic specialists [47]. This new model can only be successful with consistent interpretation and reporting of genetic variation observed in panel testing but presently still lacks the evidence-base from which this can be done.

    This brings us back to the two key elements of this discussion: the need to validate the genes on these panels as bona fide breast cancer predisposition genes with known clinical utility, and identify and develop methods to interpret the variation, on a variant-by-variant basis in terms of their likely “pathogenicity”.

    11. What is being done now?

    A number of large translational research initiatives are currently addressing the key questions raised in this discussion. There is well-founded optimism within these multi-disciplinary studies that data will be generated quickly on the necessary scale to start to make definitive analyses related to the assessment of these genes as breast cancer predisposition genes. This is in part due to the established networks of researchers that have track records of successful collaboration within other related networks such as The PALB2 interest group [12] and The Breast Cancer Association Consortium [48], the recognition of the importance of this challenge by a number of key funding bodies and the developing engagement with commercial testing facilities. Key initiatives in this area have been recently funded by the European Commission (BRIDGES; Horizon 2020), The National Institute of Health (USA), The National Health and Medical Research Council (Australia) and the National Breast Cancer Foundation (Australia). Sequence analysis of (what will shortly be) hundreds of thousands of women (from across the breast cancer risk spectrum) will provide data to enable these genes to be assessed as breast cancer susceptibility genes and to greatly advance our capacity to assess variants on a variant-by-variant basis to increase the precision of personal risk estimation and risk management.

    Large international collaborations have also identified a large number of common genetic variants individually associated with small increments in breast cancer risk, both for carriers and for non-carriers of high-risk variants (e.g. [8]). These discoveries have illustrated the complexity and diversity of factors involved in creating the genetic breast cancer risk spectrum. While these variants are not necessarily causal, they are many, and so can be used to identify women at different absolute risk. This is important information to incorporate into penetrance estimations and personalised breast cancer risk modeling. Extensive research effort is being put to characterising the biological pathways influenced by these common genetic variants [49]. However, this discussion has focused on the efforts being brought to the issues around classification of rare genetic variants in breast cancer predisposition genes rather than common genetic variants, which have some complementary but also differing issues around clinical translatability/utility.

    12. Conclusion

    Currently available gene-panel tests pose considerable challenge to clinical genetic services, as very little is known about the cancer risk associated with almost all of the observed variation in these genes. Large internationally set and linked studies are responding to produce the data required to i) validate the genes on these panels (and those likely to be added in the future) as bona fide breast cancer predisposition genes and ii) interpret the variation, on a variant-by-variant basis, in terms of their likely pathogenicity. This information can then be linked to established system for classification of variant for clinical reporting to enable consistent interpretation and clinical management.

    This information is required urgently as clinicians must have robust data with proven utility before using genetic test results as the basis of personalised risk assessment and often irreversible risk management (that includes mastectomy and bilateral salpingo-oophorectomy). The potential for gene-panel testing to improve the health outcomes of those at high risk of breast cancer can not be realised until the magnitude of the risks (penetrance) associated with variants in these genes are understood and incorporated into current personalised risk assessment models.

    Acknowledgements

    M.C.S is a National Health and Medical Research Council Senior Research Fellow. J.S. is a recipient of a Department of Pathology, The University of Melbourne, Honours student scholarship.

    Conflict of interest

    The authors have no conflict of interest to declare.



    [1] Passos CP, Rudnitskaya A, Neves JM, et al. (2019) Structural features of spent coffee grounds water-soluble polysaccharides: towards tailor-made microwave assisted extractions. Carbohydr Polym 214: 53-61. doi: 10.1016/j.carbpol.2019.02.094
    [2] Mussatto SI, Ballesteros LF, Martins S, et al. (2011) Extraction of antioxidant phenolic compounds from spent coffee grounds. Sep Purif Technol 83: 173-179. doi: 10.1016/j.seppur.2011.09.036
    [3] Ballesteros LF, Teixeira JA, Mussatto SI (2014) Chemical, functional, and structural properties of spent coffee grounds and coffee silverskin. Food Bioproc Tech 7: 3493-3503. doi: 10.1007/s11947-014-1349-z
    [4] Chittapalo T, Noomhorm A (2009) Ultrasonic assisted alkali extraction of protein from defatted rice bran and properties of the protein concentrates. Int J Food Sci Technol 44: 1843-1849. doi: 10.1111/j.1365-2621.2009.02009.x
    [5] Rodsamran P, Sothornvit R (2018) Physicochemical and functional properties of protein concentrate from by-product of coconut processing. Food Chem 241: 364-371. doi: 10.1016/j.foodchem.2017.08.116
    [6] Zhu Z, Zhu W, Yi J, et al. (2018) Effects of sonication on the physicochemical and functional properties of walnut protein isolate. Food Res Int 106: 853-861. doi: 10.1016/j.foodres.2018.01.060
    [7] Shevkani K, Singh N (2015) Relationship between protein characteristics and film-forming properties of kidney bean, field pea and amaranth protein isolates. Int J Food Sci Tech 50: 1033-1043. doi: 10.1111/ijfs.12733
    [8] Tao X, Cai Y, Liu T, et al. (2019) Effects of pretreatments on the structure and functional properties of okara protein. Food Hydrocolloid 90: 394-402. doi: 10.1016/j.foodhyd.2018.12.028
    [9] Rodsamran P, Sothornvit R (2019) Extraction of phenolic compounds from lime peel waste using ultrasonic-assisted and microwave-assisted extractions. Food Biosci 28: 66-73. doi: 10.1016/j.fbio.2019.01.017
    [10] Kamal H, Le CF, Salter AM, et al. (2021) Extraction of protein from food waste: An overview of current status and opportunities. Compr Rev Food Sci Food Saf 20: 2455-2475. doi: 10.1111/1541-4337.12739
    [11] Karki B, Lamsal BP, Jung S, et al. (2010) Enhancing protein and sugar release from defatted soy flakes using ultrasound technology. J Food Eng 96: 270-278. doi: 10.1016/j.jfoodeng.2009.07.023
    [12] Preece KE, Hooshyar N, Krijgsman AJ, et al. (2017) Intensification of protein extraction from soybean processing materials using hydrodynamic cavitation. Innov Food Sci Emerg Tec 41: 47-55. doi: 10.1016/j.ifset.2017.01.002
    [13] Wen L, Álvarez C, Zhang Z, et al. (2020) Optimisation and characterisation of protein extraction from coffee silverskin assisted by ultrasound or microwave techniques. Biomass Convers Biorefin s13399-020-00712-2.
    [14] Connolly A, Cermeño M, Crowley D, et al. (2019) Characterisation of the in vitro bioactive properties of alkaline and enzyme extracted brewers' spent grain protein hydrolysates. Int Food Res J 121: 524-532. doi: 10.1016/j.foodres.2018.12.008
    [15] Association of Official Analytical Chemists (2000) Official Methods of Analysis of AOAC International. 17 Eds., Association of Official Analytical Chemists, Gaithersburg, WD, USA.
    [16] Pearce KN, Kinsella JE (1978) Emulsifying properties of proteins: Evaluation of a turbidimetric technique. J Agric Food Chem 26: 716-723. doi: 10.1021/jf60217a041
    [17] Samsalee N, Sothornvit R (2017) Modification and characterisation of porcine plasma protein with natural agents as potential cross-linkers. Int J Food Sci Tech 52: 964-971. doi: 10.1111/ijfs.13360
    [18] Geremu M, Tola YB, Sualeh A (2016) Extraction and determination of total polyphenols and antioxidant capacity of red coffee(Coffee arabica L.) pulp of wet processing plants. Chem Biol Technol 3: 2-6.
    [19] Xue F, Wu Z, Tong J, et al. (2017) Effect of combination of high-intensity ultrasound treatment and dextran glycosylation on structural and interfacial properties of buckwheat protein isolates. Biosci Biotechnol Biochem 81: 1891-1898. doi: 10.1080/09168451.2017.1361805
    [20] Jambrak AR, Mason TJ, Lelas V, et al. (2008) Effect of ultrasound treatment on solubility and foaming properties of whey protein suspensions. J Food Eng 86: 281-287. doi: 10.1016/j.jfoodeng.2007.10.004
    [21] Zhang H, Claver IP, Zhu KX, et al. (2011) The effect of ultrasound on the functional properties of wheat gluten. Molecules 16: 4231-4240. doi: 10.3390/molecules16054231
    [22] Boye J, Zare F, Pletch A (2010) Pulse protein: Processing, characterization, functional properties and applications in food and feed. Food Res Int 43: 414-431. doi: 10.1016/j.foodres.2009.09.003
    [23] Charoensuk D, Brannan RG, Chanasattru W, et al. (2018) Physicochemical and emulsifying properties of mung bean protein isolate as influenced by succinylation. Int J Food Prop 21: 1633-1645. doi: 10.1080/10942912.2018.1502200
    [24] Bau MTS, Mazzafera P, Santoro LG (2001) Seed storage proteins in coffee. R Bras Fisiol Veg 13: 33-40. doi: 10.1590/S0103-31312001000100004
    [25] Zhang QT, Tu ZC, Xiao H, et al. (2014) Influence of ultrasonic treatment on the structure and emulsifying properties of peanut protein isolate. Food Bioprod Process 92: 30-37. doi: 10.1016/j.fbp.2013.07.006
    [26] Roselló-Soto E, Barba FJ, Parniakov O, et al. (2015) High voltage electrical discharges, pulsed electric field, and ultrasound assisted extraction of protein and phenolic compounds from olive kernel. Food Bioproc Tech 8: 885-894. doi: 10.1007/s11947-014-1456-x
    [27] Chen S, Zeng Z, Hu N, et al. (2018) Simultaneous optimization of the ultrasound-assisted extraction for phenolic compounds content and antioxidant activity of Lycium ruthenicum Murr. fruit using response surface methodology. Food Chem 242: 1-8.
    [28] Batista MJ, Ávila AF, Franca AS, et al. (2020) Polysaccharide-rich fraction of spent coffee grounds as promising biomaterial for films fabrication. Carbohydr Polym 233: 115851. doi: 10.1016/j.carbpol.2020.115851
    [29] Zhao X, Zhu H, Zhang B, et al. (2015) XRD, SEM, and XPS analysis of soybean protein powders obtained through extraction involving reverse micelles. J Am Oil Chem Soc 92: 975-983. doi: 10.1007/s11746-015-2657-9
    [30] Dong W, Wang D, Hu R, et al. (2020) Chemical composition, structural and functional properties of soluble dietary fiber obtained from coffee peel using different extraction methods. Food Res Int 136: 109497. doi: 10.1016/j.foodres.2020.109497

  • This article has been cited by:

    1. D. E. Vilkhovskiy, A survey of steganalysis methods in the papers of foreign authors, 2020, 2222-8799, 75, 10.24147/2222-8772.2020.4.75-102
    2. Jaeyoung Kim, Hanhoon Park, Jong-Il Park, CNN-based image steganalysis using additional data embedding, 2020, 79, 1380-7501, 1355, 10.1007/s11042-019-08251-3
    3. Mukesh Dalal, Mamta Juneja, Steganography and Steganalysis (in digital forensics): a Cybersecurity guide, 2021, 80, 1380-7501, 5723, 10.1007/s11042-020-09929-9
    4. Sanghoon Kang, Hanhoon Park, Jong-Il Park, CNN-Based Ternary Classification for Image Steganalysis, 2019, 8, 2079-9292, 1225, 10.3390/electronics8111225
    5. Avishka Thushan Padmasiri, Saman Hettiarachchi, 2021, Impact on JPEG Image Steganalysis using Transfer Learning, 978-1-6654-4429-3, 234, 10.1109/ICIAfS52090.2021.9605924
    6. Xiaochen Liu, Weidong He, Yinghui Zhang, Shixuan Yao, Ze Cui, Effect of dual-convolutional neural network model fusion for Aluminum profile surface defects classification and recognition, 2021, 19, 1551-0018, 997, 10.3934/mbe.2022046
    7. Hamza Kheddar, Mustapha Hemis, Yassine Himeur, David Megías, Abbes Amira, Deep learning for steganalysis of diverse data types: A review of methods, taxonomy, challenges and future directions, 2024, 581, 09252312, 127528, 10.1016/j.neucom.2024.127528
    8. Numrena Farooq, Roohie Naaz Mir, Image Steganalysis using Deep Convolution Neural Networks: A Literature Survey, 2024, 14, 22103279, 247, 10.2174/0122103279296370240529075507
    9. Laila Tul Badar, Barbara Carminati, Elena Ferrari, A comprehensive survey on stegomalware detection in digital media, research challenges and future directions, 2025, 01651684, 109888, 10.1016/j.sigpro.2025.109888
  • Reader Comments
  • © 2021 the Author(s), licensee AIMS Press. This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0)
通讯作者: 陈斌, bchen63@163.com
  • 1. 

    沈阳化工大学材料科学与工程学院 沈阳 110142

  1. 本站搜索
  2. 百度学术搜索
  3. 万方数据库搜索
  4. CNKI搜索
AIMS Agriculture and Food
1.3 3.9

Metrics

Article views(5301) PDF downloads(512) Cited by(17)

Preview PDF
Download XML
Export Citation
Article outline
Abstract
References

Figures and Tables

Figures(6)  /  Tables(1)

Other Articles By Authors

Related pages

Tools

Copyright © AIMS Press

/

DownLoad:  Full-Size Img  PowerPoint
Return
Return

Catalog