This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Amgarten D., Braga L.P.P., da Silva A.M., Setubal J.C.: MARVEL, a Tool for prediction of bacteriophage sequences in meta-genomic bins. Front. Genet. 9, 304 (2018)AmgartenD.BragaL.P.P.da SilvaA.M.SetubalJ.C.:MARVEL, a Tool for prediction of bacteriophage sequences in meta-genomic bins.Front. Genet.9,304(2018)Search in Google Scholar
Amsel R., Totten P.A., Spiegel C.A., Chen K.C., Eschenbach D., Holmes K.K.: Nonspecific vaginitis. Diagnostic criteria and microbial and epidemiologic associations. Am. J. Med. 74, 14–22 (1983)AmselR.TottenP.A.SpiegelC.A.ChenK.C.EschenbachD.HolmesK.K.:Nonspecific vaginitis. Diagnostic criteria and microbial and epidemiologic associations.Am. J. Med.74,14–22(1983)Search in Google Scholar
Ankerst M., Breunig M.M., Kriegel H.P., Sander J.: OPTICS: ordering points to identify the clustering structure. ACM SIG-MOD, 1, 49–60 (1999)AnkerstM.BreunigM.M.KriegelH.P.SanderJ.:OPTICS: ordering points to identify the clustering structure.ACM SIG-MOD,1,49–60(1999)Search in Google Scholar
Asgari E., Garakani K., McHardy A.C., Mofrad M.R.K.: Micro-Pheno: predicting environments and host phenotypes from 16S rRNA gene sequencing using a k-mer based representation of shallow sub-samples. Bioinformatics, 34, 32–42 (2018)AsgariE.GarakaniK.McHardyA.C.MofradM.R.K.:Micro-Pheno: predicting environments and host phenotypes from 16S rRNA gene sequencing using a k-mer based representation of shallow sub-samples.Bioinformatics,34,32–42(2018)Search in Google Scholar
Atlas R.M., Bartha R.: Microbial ecology: fundamentals and applications. Acta Ecol. Sin. 70, 977 (1981)AtlasR.M.BarthaR.:Microbial ecology: fundamentals and applications.Acta Ecol. Sin.70,977(1981)Search in Google Scholar
Arrieta A.B. & Díaz-Rodríguez N. et al.: Explainable artificial intelligence (XAI): concepts, taxonomies, opportunities and challenges toward responsible AI. Inf. Fusion, 58, 82–115 (2020)ArrietaA.B. & Díaz-RodríguezN..:Explainable artificial intelligence (XAI): concepts, taxonomies, opportunities and challenges toward responsible AI.Inf. Fusion,58,82–115(2020)Search in Google Scholar
Beck D., Foster J.A.: Machine learning techniques accurately classify microbial communities by bacterial vaginosis characteristics. PLoS One, 9, e87830 (2014)BeckD.FosterJ.A.:Machine learning techniques accurately classify microbial communities by bacterial vaginosis characteristics.PLoS One,9,e87830(2014)Search in Google Scholar
Beck L.C., Granger C.L., Masi A.C., Stewart C.J.: Use of omic technologies in early life gastrointestinal health and disease: from bench to bedside. Expert Rev. Proteomics, 18, 247–259 (2021)BeckL.C.GrangerC.L.MasiA.C.StewartC.J.:Use of omic technologies in early life gastrointestinal health and disease: from bench to bedside.Expert Rev. Proteomics,18,247–259(2021)Search in Google Scholar
Belkin M., Niyogi P.: Laplacian eigenmaps for dimensionality reduction and data representation. Neural Comput. 15, 1373–1396 (2003)BelkinM.NiyogiP.:Laplacian eigenmaps for dimensionality reduction and data representation.Neural Comput.15,1373–1396(2003)Search in Google Scholar
Bourne D.G., Garren M., Work T.M., Rosenberg E., Smith G.W., Harvell C.D.: Microbial disease and the coral holobiont. Trends Microbiol. 17, 554–562 (2009)BourneD.G.GarrenM.WorkT.M.RosenbergE.SmithG.W.HarvellC.D.:Microbial disease and the coral holobiont.Trends Microbiol.17,554–562(2009)Search in Google Scholar
Bulgarelli D., Schlaeppi K., Spaepen S., Van Themaat E.V.L., Schulze-Lefert P.: Structure and functions of the bacterial microbiota of plants. Annu. Rev. Plant Biol. 64, 807–838 (2013)BulgarelliD.SchlaeppiK.SpaepenS.Van ThemaatE.V.L.Schulze-LefertP.:Structure and functions of the bacterial microbiota of plants.Annu. Rev. Plant Biol.64,807–838(2013)Search in Google Scholar
Chang H.X., Haudenshield J.S., Bowen C.R., Hartman G.L.: Metagenome-wide association study and machine learning prediction of bulk soil microbiome and crop productivity. Front. Microbiol. 8, 519 (2017)ChangH.X.HaudenshieldJ.S.BowenC.R.HartmanG.L.:Metagenome-wide association study and machine learning prediction of bulk soil microbiome and crop productivity.Front. Microbiol.8,519(2017)Search in Google Scholar
Chen X., Huang Y.A., You Z.H., Yan G.Y., Wang X.S.: A novel approach based on KATZ measure to predict associations of human microbiota with non-infectious diseases. Bioinformatics, 33, 733–739 (2017)ChenX.HuangY.A.YouZ.H.YanG.Y.WangX.S.:A novel approach based on KATZ measure to predict associations of human microbiota with non-infectious diseases.Bioinformatics,33,733–739(2017)Search in Google Scholar
Chen X., Yan C.C., Luo C., Ji W., Zhang Y., Dai Q.: Constructing lncRNA functional similarity network based on lncRNA-disease associations and disease semantic similarity. Sci. Rep. 5, 11338 (2015)ChenX.YanC.C.LuoC.JiW.ZhangY.DaiQ.:Constructing lncRNA functional similarity network based on lncRNA-disease associations and disease semantic similarity.Sci. Rep.5,11338(2015)Search in Google Scholar
Cheng Y.Z.: Mean shift, mode seeking, and clustering. IEEE Trans. Pattern Anal. Mach. Intell. 17, 790–799 (1995)ChengY.Z.:Mean shift, mode seeking, and clustering.IEEE Trans. Pattern Anal. Mach. Intell.17,790–799(1995)Search in Google Scholar
Cortes C., Vapnik V.: Support-vector networks. Mach. Learn. 20, 273–297 (1995)CortesC.VapnikV.:Support-vector networks.Mach. Learn.20,273–297(1995)Search in Google Scholar
Defays D.: Efficient algorithm for a complete link method. Comput. J. 20, 364–366 (1977)DefaysD.:Efficient algorithm for a complete link method.Comput. J.20,364–366(1977)Search in Google Scholar
Deng Z.L., Gottschick C., Bhuju S., Masur C., Abels C., Wagner-Dobler I.: Metatranscriptome analysis of the vaginal microbiota reveals potential mechanisms for protection against metronidazole in bacterial vaginosis. MSphere, 3, e00262–18 (2018)DengZ.L.GottschickC.BhujuS.MasurC.AbelsC.Wagner-DoblerI.:Metatranscriptome analysis of the vaginal microbiota reveals potential mechanisms for protection against metronidazole in bacterial vaginosis.MSphere,3,e00262–18(2018)Search in Google Scholar
Devlin J., Chang M.W., Lee K., Toutanova K.: Bert: pre-training of deep bidirectional transformers for language understanding. Hum. Lang. Technol. 7, 4171–4186 (2019)DevlinJ.ChangM.W.LeeK.ToutanovaK.:Bert: pre-training of deep bidirectional transformers for language understanding.Hum. Lang. Technol.7,4171–4186(2019)Search in Google Scholar
DiMucci D., Kon M., Segre D.: Machine learning reveals missing edges and putative interaction mechanisms in microbial ecosystem networks. Msystems, 3, e00181–18 (2018)DiMucciD.KonM.SegreD.:Machine learning reveals missing edges and putative interaction mechanisms in microbial ecosystem networks.Msystems,3,e00181–18(2018)Search in Google Scholar
Erev I., Roth A.E.: Predicting how people play games: reinforcement learning in experimental games with unique, mixed strategy equilibria. Am. Econ. Rev. 88, 848–881 (1998)ErevI.RothA.E.:Predicting how people play games: reinforcement learning in experimental games with unique, mixed strategy equilibria.Am. Econ. Rev.88,848–881(1998)Search in Google Scholar
Fan C.Y., Lei X. J., Guo L., Zhang A.D.: Predicting the associations between microbes and diseases by integrating multiple data sources and path based Het eSim scores. Neurocomputing, 323, 76–85 (2019)FanC.Y.LeiX. J.GuoL.ZhangA.D.:Predicting the associations between microbes and diseases by integrating multiple data sources and path based Het eSim scores.Neurocomputing,323,76–85(2019)Search in Google Scholar
Fisher R.A.: The use of multiple measurements in taxonomic problems. Ann. Eugenics, 7, 179–188 (1936)FisherR.A.:The use of multiple measurements in taxonomic problems.Ann. Eugenics,7,179–188(1936)Search in Google Scholar
Frank M.J., Seeberger L.C., O’reilly R.C.: By carrot or by stick: cognitive reinforcement learning in parkinsonism. Science, 306, 1940–1943 (2004)FrankM.J.SeebergerL.C.O’reillyR.C.:By carrot or by stick: cognitive reinforcement learning in parkinsonism.Science,306,1940–1943(2004)Search in Google Scholar
Freund Y.: Boosting a weak learning algorithm by majority. 3rd Annual workshop on computational learning theory, 1, 202–216 (1990)FreundY.:Boosting a weak learning algorithm by majority.3rd Annual workshop on computational learning theory,1,202–216(1990)Search in Google Scholar
Gillevet P., Sikaroodi M., Keshavarzian A., Mutlu E.A.: Quantitative assessment of the human gut microbiome using multitag pyrosequencing. Chem. Biodivers. 7, 1065–1075 (2010)GillevetP.SikaroodiM.KeshavarzianA.MutluE.A.:Quantitative assessment of the human gut microbiome using multitag pyrosequencing.Chem. Biodivers.7,1065–1075(2010)Search in Google Scholar
Greener J.G., Kandathil S.M., Moffat L., Jones D.T.: A guide to machine learning for biologists. Nat. Rev. Mol. Cell Biol. 23, 40–55 (2022)GreenerJ.G.KandathilS.M.MoffatL.JonesD.T.:A guide to machine learning for biologists.Nat. Rev. Mol. Cell Biol.23,40–55(2022)Search in Google Scholar
He X.F., Niyogi P.: Locality preserving projections. 17th Annual conference on neural information processing systems, 1, 153–160 (2003)HeX.F.NiyogiP.:Locality preserving projections.17th Annual conference on neural information processing systems,1,153–160(2003)Search in Google Scholar
Hinton G.E., Salakhutdinov R.R.: Reducing the dimensionality of data with neural networks. Science, 313, 504–507 (2006)HintonG.E.SalakhutdinovR.R.:Reducing the dimensionality of data with neural networks.Science,313,504–507(2006)Search in Google Scholar
Huang Y.A., You Z.H., Chen X., Huang Z.A., Zhang S.W., Yan G.Y.: Prediction of microbe-disease association from the integration of neighbor and graph with collaborative recommendation model. J. Transl. Med. 15, 209 (2017)HuangY.A.YouZ.H.ChenX.HuangZ.A.ZhangS.W.YanG.Y.:Prediction of microbe-disease association from the integration of neighbor and graph with collaborative recommendation model.J. Transl. Med.15,209(2017)Search in Google Scholar
Huang Z.A., Chen X., Zhu Z.X., Liu H.S., Yan G.Y., You Z.H., Wen Z.: PBHMDA: path-based human microbe-disease association prediction. Front. Microbiol. 8, 233 (2017)HuangZ.A.ChenX.ZhuZ.X.LiuH.S.YanG.Y.YouZ.H.WenZ.:PBHMDA: path-based human microbe-disease association prediction.Front. Microbiol.8,233(2017)Search in Google Scholar
Johnson H.R., Trinidad D.D., Guzman S., Khan Z., Parziale J.V., DeBruyn J.M., Lents N.H.: A machine learning approach for using the postmortem skin microbiome to estimate the postmortem interval. PLoS One, 11, e0167370 (2016)JohnsonH.R.TrinidadD.D.GuzmanS.KhanZ.ParzialeJ.V.DeBruynJ.M.LentsN.H.:A machine learning approach for using the postmortem skin microbiome to estimate the postmortem interval.PLoS One,11,e0167370(2016)Search in Google Scholar
Jones M.L., Ganopolsky J.G., Martoni C.J., Labbe A., Prakash S.: Emerging science of the human microbiome. Gut Microbes, 5, 446–457 (2014)JonesM.L.GanopolskyJ.G.MartoniC.J.LabbeA.PrakashS.:Emerging science of the human microbiome.Gut Microbes,5,446–457(2014)Search in Google Scholar
Jordan M.I., Mitchell T.M.: Machine learning: trends, perspectives, and prospects. Science, 349, 255–260 (2015)JordanM.I.MitchellT.M.:Machine learning: trends, perspectives, and prospects.Science,349,255–260(2015)Search in Google Scholar
Kaelbling L.P., Littman M.L., Moore A.W.: Reinforcement learning: a survey. J. Artif. Intell. Res. 4, 237–285 (1996)KaelblingL.P.LittmanM.L.MooreA.W.:Reinforcement learning: a survey.J. Artif. Intell. Res.4,237–285(1996)Search in Google Scholar
Katz L.: A new status index derived from sociometric analysis. Psychometrika, 18, 39–43 (1953)KatzL.:A new status index derived from sociometric analysis.Psychometrika,18,39–43(1953)Search in Google Scholar
Keerthi S.S., Ravindran B.: A tutorial survey of reinforcement learning. Sadhana Acad. Proc. Eng. Sci. 19, 851–889 (1994)KeerthiS.S.RavindranB.:A tutorial survey of reinforcement learning.Sadhana Acad. Proc. Eng. Sci.19,851–889(1994)Search in Google Scholar
Kira K., Rendell L.A.: A practical approach to feature selection. 19th International workshop on machine learning, 1, 249–256 (1992)KiraK.RendellL.A.:A practical approach to feature selection.19th International workshop on machine learning,1,249–256(1992)Search in Google Scholar
Kober J., Bagnell J.A., Peters J.: Reinforcement learning in robotics: a survey. Int. J. Robot. Res. 32, 1238–1274 (2013)KoberJ.BagnellJ.A.PetersJ.:Reinforcement learning in robotics: a survey.Int. J. Robot. Res.32,1238–1274(2013)Search in Google Scholar
Langille M.G.I. & Zaneveld J. et al.: Predictive functional profiling of microbial communities using 16S rRNA marker gene sequences. Nat. Biotechnol. 31, 814–821 (2013)LangilleM.G.I. & ZaneveldJ..:Predictive functional profiling of microbial communities using 16S rRNA marker gene sequences.Nat. Biotechnol.31,814–821(2013)Search in Google Scholar
Lecun Y., Bengio Y., Hinton G.: Deep learning. Nature, 521, 436–444 (2015)LecunY.BengioY.HintonG.:Deep learning.Nature,521,436–444(2015)Search in Google Scholar
Lecun Y., Boser B., Denker J.S., Henderson D., Howard R.E., Hubbard W., Jackel L.L.: Backpropagation applied to handwritten zip code recognition. Neural Comput. 1, 541–551 (1989)LecunY.BoserB.DenkerJ.S.HendersonD.HowardR.E.HubbardW.JackelL.L.:Backpropagation applied to handwritten zip code recognition.Neural Comput.1,541–551(1989)Search in Google Scholar
Lecun Y., Bottou L., Bengio Y., Haffner P.: Gradient-based learning applied to document recognition. Proc. IEEE, 86, 2278–2324 (1998)LecunY.BottouL.BengioY.HaffnerP.:Gradient-based learning applied to document recognition.Proc. IEEE,86,2278–2324(1998)Search in Google Scholar
Ley R.E., Turnbaugh P.J., Klein S., Gordon J.I.: Microbial ecology: human gut microbes associated with obesity. Nature, 444, 1022–1023 (2006)LeyR.E.TurnbaughP.J.KleinS.GordonJ.I.:Microbial ecology: human gut microbes associated with obesity.Nature,444,1022–1023(2006)Search in Google Scholar
Ley R.E., Turnbaugh P.J., Samuel K., Gordon J.I.: Microbial ecology: human gut microbes associated with obesity. Nature, 444, 1022–1023 (2006)LeyR.E.TurnbaughP.J.SamuelK.GordonJ.I.:Microbial ecology: human gut microbes associated with obesity.Nature,444,1022–1023(2006)Search in Google Scholar
Liang J., Luo W., Yu K., Xu Y., Chen J., Deng C., Ge R., Su H., Huang W., Wang G.: Multi-Omics revealing the response patterns of symbiotic microorganisms and host metabolism in Scleractinian coral Pavonaminuta to temperature stresses. Meta, 12, 18 (2021)LiangJ.LuoW.YuK.XuY.ChenJ.DengC.GeR.SuH.HuangW.WangG.:Multi-Omics revealing the response patterns of symbiotic microorganisms and host metabolism in Scleractinian coral Pavonaminuta to temperature stresses.Meta,12,18(2021)Search in Google Scholar
Liu B., Liu F., Wang X., Chen J., Fang L., Chou K.C.: Pse-in-One: a web server for generating various modes of pseudo components of DNA, RNA, and protein sequences. Nucleic Acids Res. 43, 65–71 (2015)LiuB.LiuF.WangX.ChenJ.FangL.ChouK.C.:Pse-in-One: a web server for generating various modes of pseudo components of DNA, RNA, and protein sequences.Nucleic Acids Res.43,65–71(2015)Search in Google Scholar
Mainali K.P. & Bewick S. et al.: Statistical analysis of co-occurrence patterns in microbial presenceabsence datasets. PLoS One, 12, e0187132 (2017)MainaliK.P. & BewickS..:Statistical analysis of co-occurrence patterns in microbial presenceabsence datasets.PLoS One,12,e0187132(2017)Search in Google Scholar
Malla M.A., Dubey A., Kumar A., Yadav S., Hashem A., Abdallah E.F.: Exploring the human microbiome: the potential future role of next-generation sequencing in disease diagnosis and treatment. Front. Immunol. 9, 2868 (2018)MallaM.A.DubeyA.KumarA.YadavS.HashemA.AbdallahE.F.:Exploring the human microbiome: the potential future role of next-generation sequencing in disease diagnosis and treatment.Front. Immunol.9,2868(2018)Search in Google Scholar
Mnih V. & Kavukcuoglu K. et al.: Human-level control through deep reinforcement learning. Nature, 518, 529–533 (2015)MnihV. & KavukcuogluK..:Human-level control through deep reinforcement learning.Nature,518,529–533(2015)Search in Google Scholar
Moran, M.A.: The global ocean microbiome. Science, 350, 8455 (2015)MoranM.A.:The global ocean microbiome.Science,350,8455(2015)Search in Google Scholar
Morris O.N., Cunningham J.C., Finneycrawley J.R., Jaques R.P., Kinoshita G.: Microbial insecticides in Canada: their registration and use in agriculture, forestry and public and animal health. Bull. Entomol. Soc. Canada, 18, 1–43 (1986)MorrisO.N.CunninghamJ.C.FinneycrawleyJ.R.JaquesR.P.KinoshitaG.:Microbial insecticides in Canada: their registration and use in agriculture, forestry and public and animal health.Bull. Entomol. Soc. Canada,18,1–43(1986)Search in Google Scholar
Murali A., Bhargava A., Wright E.S.: IDTAXA: a novel approach for accurate taxonomic classification of microbiome sequences. Microbiome, 6, 140 (2018)MuraliA.BhargavaA.WrightE.S.:IDTAXA: a novel approach for accurate taxonomic classification of microbiome sequences.Microbiome,6,140(2018)Search in Google Scholar
Nannipieri P., Ascher J., Ceccherini M.T., Landi L., Pietramellara G., Renella G.: Microbial diversity and soil functions. Eur. J. Soil Sci. 54, 655–670 (2010)NannipieriP.AscherJ.CeccheriniM.T.LandiL.PietramellaraG.RenellaG.:Microbial diversity and soil functions.Eur. J. Soil Sci.54,655–670(2010)Search in Google Scholar
Nowrousian M.: Next-generation sequencing techniques for eukaryotic microorganisms: sequencing-based solutions to biological problems. Eukaryot. Cell, 9, 1300–1310 (2010)NowrousianM.:Next-generation sequencing techniques for eukaryotic microorganisms: sequencing-based solutions to biological problems.Eukaryot. Cell,9,1300–1310(2010)Search in Google Scholar
Nugent R.P., Krohn M.A., Hillier S.L.: Reliability of diagnosing bacterial vaginosis is improved by a standardised method of gram stain interpretation. J. Clin. Microbiol. 29, 297–301 (1991)NugentR.P.KrohnM.A.HillierS.L.:Reliability of diagnosing bacterial vaginosis is improved by a standardised method of gram stain interpretation.J. Clin. Microbiol.29,297–301(1991)Search in Google Scholar
Oudah M., Henschel A.: Taxonomy-aware feature engineering for microbiome classification. BMC Bioinformatics, 19, 227 (2018)OudahM.HenschelA.:Taxonomy-aware feature engineering for microbiome classification.BMC Bioinformatics,19,227(2018)Search in Google Scholar
Pearson K.: On lines and planes of closest fit to systems of points in space. Philos. Mag. 2, 559–572 (1901)PearsonK.:On lines and planes of closest fit to systems of points in space.Philos. Mag.2,559–572(1901)Search in Google Scholar
Peng L.H., Yin J., Zhou L.Q., Liu M.X., Zhao Y.: Human microbe disease association prediction based on adaptive boosting. Front. Microbiol. 9, 2440 (2018)PengL.H.YinJ.ZhouL.Q.LiuM.X.ZhaoY.:Human microbe disease association prediction based on adaptive boosting.Front. Microbiol.9,2440(2018)Search in Google Scholar
Petrof E.O., Claud E.C., Gloor G.B., Allenvercoe E.: Microbial ecosystems therapeutics: a new paradigm in medicine? Benef. Microbes, 4, 53–65 (2012)PetrofE.O.ClaudE.C.GloorG.B.AllenvercoeE.:Microbial ecosystems therapeutics: a new paradigm in medicine?Benef. Microbes,4,53–65(2012)Search in Google Scholar
Quinlan J.R.: Induction of decision trees. Mach. Learn. 1, 81–106 (1986)QuinlanJ.R.:Induction of decision trees.Mach. Learn.1,81–106(1986)Search in Google Scholar
Quinlan J.R.: Bagging, boosting, and C4.5. 13th National Conference on Artificial Intelligence, 1, 725–730 (1996)QuinlanJ.R.:Bagging, boosting, and C4.5.13th National Conference on Artificial Intelligence,1,725–730(1996)Search in Google Scholar
Ravel J. & Gajer P. et al.: Vaginal microbiome of reproductive-age women. Proc. Natl. Acad. Sci. 108, 4680–4687 (2011)RavelJ. & GajerP..:Vaginal microbiome of reproductive-age women.Proc. Natl. Acad. Sci.108,4680–4687(2011)Search in Google Scholar
Reiff C., Kelly D.: Inflammatory bowel disease, gut bacteria and probiotic therapy. Int. J. Med. Microbiol. 300, 25–33 (2010)ReiffC.KellyD.:Inflammatory bowel disease, gut bacteria and probiotic therapy.Int. J. Med. Microbiol.300,25–33(2010)Search in Google Scholar
Roweis S.T., Saul L.K.: Nonlinear dimensionality reduction by locally linear embedding. Science, 290, 2323 (2000)RoweisS.T.SaulL.K.:Nonlinear dimensionality reduction by locally linear embedding.Science,290,2323(2000)Search in Google Scholar
Ruff W.E., Greiling T.M., Kriegel M.A.: Host-microbiota interactions in immune-mediated diseases. Nat. Rev. Microbiol. 18, 521–538 (2020)RuffW.E.GreilingT.M.KriegelM.A.:Host-microbiota interactions in immune-mediated diseases.Nat. Rev. Microbiol.18,521–538(2020)Search in Google Scholar
Rumelhart D.E., Hinton G.E., Williams R.J.: Learning representations by back-propagating errors. Nature, 323, 533–536 (1986)RumelhartD.E.HintonG.E.WilliamsR.J.:Learning representations by back-propagating errors.Nature,323,533–536(1986)Search in Google Scholar
Shi J.Y., Huang H., Zhang Y.N., Cao J.B., Yiu S.M.: BMCMDA: a novel model for predicting human microbe-disease associations via binary matrix completion. BMC Bioinformatics, 19, 169–176 (2018)ShiJ.Y.HuangH.ZhangY.N.CaoJ.B.YiuS.M.:BMCMDA: a novel model for predicting human microbe-disease associations via binary matrix completion.BMC Bioinformatics,19,169–176(2018)Search in Google Scholar
Shi J.Y., Li J.X., Lu H.M.: Predicting existing targets for new drugs base on strategies for missing interactions. BMC Bioinformatics, 17, 282 (2016)ShiJ.Y.LiJ.X.LuH.M.:Predicting existing targets for new drugs base on strategies for missing interactions.BMC Bioinformatics,17,282(2016)Search in Google Scholar
Sibley C.D., Parkins M.D., Rabin H.R., Kangmin D., Norgaard J.C., Surette M.G.: A polymicrobial perspective of pulmonary infections exposes an enigmatic pathogen in cystic fibrosis patients. Proc. Natl. Acad. Sci. 105, 15070–15075 (2008)SibleyC.D.ParkinsM.D.RabinH.R.KangminD.NorgaardJ.C.SuretteM.G.:A polymicrobial perspective of pulmonary infections exposes an enigmatic pathogen in cystic fibrosis patients.Proc. Natl. Acad. Sci.105,15070–15075(2008)Search in Google Scholar
Sibson R.: Slink-optimally efficient algorithm for single-link cluster method. Comput. J. 16, 30–34 (1973)SibsonR.:Slink-optimally efficient algorithm for single-link cluster method.Comput. J.16,30–34(1973)Search in Google Scholar
Smirnov E.A., Timoshenko D.M., Andrianov S.N.: Comparison of regularization methods for ImageNet classification with deep convolutional neural networks. 2nd AASRI CIB, 1, 89–94 (2013)SmirnovE.A.TimoshenkoD.M.AndrianovS.N.:Comparison of regularization methods for ImageNet classification with deep convolutional neural networks.2nd AASRI CIB,1,89–94(2013)Search in Google Scholar
Souza P.M.D.: Application of microbial a-amylase in industry – A review. Braz. J. Microbiol. 41, 850–861 (2010)SouzaP.M.D.:Application of microbial a-amylase in industry – A review.Braz. J. Microbiol.41,850–861(2010)Search in Google Scholar
Srinivasan S. & Hoffman N.G. et al.: Bacterial communities in women with bacterial vaginosis: high resolution phylogenetic analyses reveal relationships of microbiota to clinical criteria. PLoS One, 7, e37818 (2012)SrinivasanS. & HoffmanN.G..:Bacterial communities in women with bacterial vaginosis: high resolution phylogenetic analyses reveal relationships of microbiota to clinical criteria.PLoS One,7,e37818(2012)Search in Google Scholar
Statnikov A., Henaff M., Narendra V., Konganti K., Li Z.G., Yang L.Y., Pei Z, Blaser MJ, Aliferis CF, Alekseyenko AV.: A comprehensive evaluation of multicategory classification methods for microbiomic data. Microbiome, 1, 11 (2013)StatnikovA.HenaffM.NarendraV.KongantiK.LiZ.G.YangL.Y.PeiZBlaserMJAliferisCFAlekseyenkoAV.:A comprehensive evaluation of multicategory classification methods for microbiomic data.Microbiome,1,11(2013)Search in Google Scholar
Su R., Wu H., Xu B., Liu X., Wei L.: Developing a multi-dose computational model for drug-induced hepatotoxicity prediction based on toxicogenomics data. IEEE/ACM Trans. Comput. Biol. Bioinform. 16, 1231–1239 (2018)SuR.WuH.XuB.LiuX.WeiL.:Developing a multi-dose computational model for drug-induced hepatotoxicity prediction based on toxicogenomics data.IEEE/ACM Trans. Comput. Biol. Bioinform.16,1231–1239(2018)Search in Google Scholar
Sujatha S. & Hoffman N.G. et al.: Bacterial communities in women with bacterial vaginosis: high resolution phylogenetic analyses reveal relationships of microbiota to clinical criteria. PLoS One, 7, e37818 (2012)SujathaS. & HoffmanN.G..:Bacterial communities in women with bacterial vaginosis: high resolution phylogenetic analyses reveal relationships of microbiota to clinical criteria.PLoS One,7,e37818(2012)Search in Google Scholar
Tenenbaum J.B., De Silva V., Langford J.C.: A global geometric framework for nonlinear dimensionality reduction. Science, 290, 2319 (2000)TenenbaumJ.B.De SilvaV.LangfordJ.C.:A global geometric framework for nonlinear dimensionality reduction.Science,290,2319(2000)Search in Google Scholar
Turnbaugh P.J., Ley R.E., Hamady M., Fraser-Liggett C.M., Knight R., Gordon J.I.: The human microbiome project. Nature, 449, 804–810 (2007)TurnbaughP.J.LeyR.E.HamadyM.Fraser-LiggettC.M.KnightR.GordonJ.I.:The human microbiome project.Nature,449,804–810(2007)Search in Google Scholar
Van Der Maaten L., Hinton G.: Visualising Data using t-SNE. J. Mach. Learn. Res. 9, 2579–2605 (2008)Van Der MaatenL.HintonG.:Visualising Data using t-SNE.J. Mach. Learn. Res.9,2579–2605(2008)Search in Google Scholar
Wang F., Huang Z.A., Chen X., Zhu Z.X., Wen Z.K., Zhao J.Y., Yan G.Y.: LRLSHMDA: laplacian regularised least squares for human microbe disease association prediction. Sci. Rep. 7, 7601 (2017)WangF.HuangZ.A.ChenX.ZhuZ.X.WenZ.K.ZhaoJ.Y.YanG.Y.:LRLSHMDA: laplacian regularised least squares for human microbe disease association prediction.Sci. Rep.7,7601(2017)Search in Google Scholar
Wei L.Y., Wan S.X., Guo J.S., Wong K.K.L.: A novel hierarchical selective ensemble classifier with bioinformatics application. Artif. Intell. Med. 83, 82–90 (2017)WeiL.Y.WanS.X.GuoJ.S.WongK.K.L.:A novel hierarchical selective ensemble classifier with bioinformatics application.Artif. Intell. Med.83,82–90(2017)Search in Google Scholar
Wei L.Y., Xing P.W., Zeng J.C., Chen J.X., Su R., Guo F.: Improved prediction of protein-protein interactions using novel negative samples, features, and an ensemble classifier. Artif. Intell. Med. 83, 67–74 (2017)WeiL.Y.XingP.W.ZengJ.C.ChenJ.X.SuR.GuoF.:Improved prediction of protein-protein interactions using novel negative samples, features, and an ensemble classifier.Artif. Intell. Med.83,67–74(2017)Search in Google Scholar
Weinbauer M.G.: Ecology of prokaryotic viruses. FEMS Microbiol. Rev. 28, 127–181 (2010)WeinbauerM.G.:Ecology of prokaryotic viruses.FEMS Microbiol. Rev.28,127–181(2010)Search in Google Scholar
White J.R., Nagarajan N., Pop M.: Statistical methods for detecting differentially abundant features in clinical metagenomic samples. PLoS Comput. Biol. 5, e1000352 (2009)WhiteJ.R.NagarajanN.PopM.:Statistical methods for detecting differentially abundant features in clinical metagenomic samples.PLoS Comput. Biol.5,e1000352(2009)Search in Google Scholar
Wisittipanit N.: Machine learning approach for profiling human microbiome. Ph.D. dissertation, George Mason University, Fairfax (2019)WisittipanitN.:Machine learning approach for profiling human microbiome.Ph.D. dissertation, George Mason University,Fairfax(2019)Search in Google Scholar
Yang X., Gao L., Guo X., Shi X., Wu H., Song F., Wang B.: A network based method for analysis of lncRNA-disease associations and prediction of lncRNAs implicated in diseases. PLoS One, 9, e87797 (2014)YangX.GaoL.GuoX.ShiX.WuH.SongF.WangB.:A network based method for analysis of lncRNA-disease associations and prediction of lncRNAs implicated in diseases.PLoS One,9,e87797(2014)Search in Google Scholar
Yang H., Qiu W.R., Liu G.Q., Guo F.B., Chen W., Chou K.C., Lin H.: iRSpot-Pse6NC: identifying recombination spots in Saccharomyces cerevisiae by incorporating hexamer composition into general PseKNC. Int. J. Biol. Sci. 14, 883–891 (2018)YangH.QiuW.R.LiuG.Q.GuoF.B.ChenW.ChouK.C.LinH.:iRSpot-Pse6NC: identifying recombination spots in Saccharomyces cerevisiae by incorporating hexamer composition into general PseKNC.Int. J. Biol. Sci.14,883–891(2018)Search in Google Scholar
Yeh C.H.: Classification and regression trees (Cart). Chemom. Intell. Lab. Syst. 12, 95–96 (1991)YehC.H.:Classification and regression trees (Cart).Chemom. Intell. Lab. Syst.12,95–96(1991)Search in Google Scholar
Yu L., Huang J.B., Ma Z.X., Zhang J., Zou Y.P., Gao L.: Inferring drug-disease associations based on known protein complexes. BMC Med. Genomics, 8, 2 (2015)YuL.HuangJ.B.MaZ.X.ZhangJ.ZouY.P.GaoL.:Inferring drug-disease associations based on known protein complexes.BMC Med. Genomics,8,2(2015)Search in Google Scholar
Yu L., Zhao J., Gao L.: Predicting potential drugs for breast cancer based on miRNA and tissue specificity. Int. J. Biol. Sci. 14, 971–980 (2018)YuL.ZhaoJ.GaoL.:Predicting potential drugs for breast cancer based on miRNA and tissue specificity.Int. J. Biol. Sci.14,971–980(2018)Search in Google Scholar
Yu L., Ma X.K., Zhang L., Zhang J., Gao L.: Prediction of new drug indications based on clinical data and network modularity. Sci. Rep. 6, 32530 (2016)YuL.MaX.K.ZhangL.ZhangJ.GaoL.:Prediction of new drug indications based on clinical data and network modularity.Sci. Rep.6,32530(2016)Search in Google Scholar
Zhang J., Liu Y.X., Guo X., Qin Y., Garrido-Oter R., Schulze-Lefert P., Bai Y.: High-throughput cultivation and identification of bacteria from the plant root microbiota. Nat. Protoc. 16, 988–1012 (2021)ZhangJ.LiuY.X.GuoX.QinY.Garrido-OterR.Schulze-LefertP.BaiY.:High-throughput cultivation and identification of bacteria from the plant root microbiota.Nat. Protoc.16,988–1012(2021)Search in Google Scholar
Zhang M.L., Pena J.M., Robles V.: Feature selection for multi-label naive Bayes classification. Inf. Sci. 179, 3218–3229 (2009)ZhangM.L.PenaJ.M.RoblesV.:Feature selection for multi-label naive Bayes classification.Inf. Sci.179,3218–3229(2009)Search in Google Scholar
Zou Q., Lin G., Jiang X., Liu X., Zeng X.: Sequence clustering in bioinformatics: an empirical study. Brief. Bioinform. 21, 1–10 (2020)ZouQ.LinG.JiangX.LiuX.ZengX.:Sequence clustering in bioinformatics: an empirical study.Brief. Bioinform.21,1–10(2020)Search in Google Scholar
