Biblio
“Plasma paraoxonase, health, inflammatory conditions, and liver function in transition dairy cows.”, J Dairy Sci, vol. 90, no. 4, pp. 1740-50, 2007.
, “Old and new stories: revelations from functional analysis of the bovine mammary transcriptome during the lactation cycle.”, PLoS One, vol. 7, no. 3, p. e33268, 2012.
, “291 THE USE OF THE DYNAMIC IMPACT APPROACH AND DESORPTION ELECTROSPRAY IONIZATION - MASS SPECTROSCOPY TO ANALYZE ADIPOGENESIS IN PORCINE ADIPOSE-DERIVED STEM CELLS”, Reproduction, Fertility and Development, vol. 25, no. 1, p. 293, 2013.
, “TRIENNIAL LACTATION SYMPOSIUM: Nutrigenomics in dairy cows: Nutrients, transcription factors, and techniques.”, J Anim Sci, vol. 93, no. 12, pp. 5531-53, 2015.
, “Transcription Adaptation during In Vitro Adipogenesis and Osteogenesis of Porcine Mesenchymal Stem Cells: Dynamics of Pathways, Biological Processes, Up-Stream Regulators, and Gene Networks”, PLOS ONE, p. e0137644, 2015.
, “Nutrigenomics Approaches to Fine-Tune Metabolism and Milk Production: Is This the Future of Ruminant Nutrition?”, Advances in Dairy Research, vol. 02, no. 01, 2014.
, “Fine metabolic regulation in ruminants via nutrient-gene interactions: saturated long-chain fatty acids increase expression of genes involved in lipid metabolism and immune response partly through PPAR-α activation.”, Br J Nutr, vol. 107, no. 2, pp. 179-91, 2012.
, “Transcriptomics Comparisons of Mac-T cells Versus Mammary Tissue during Late Pregnancy and Peak Lactation”, Advances in Dairy Research, vol. 01, no. 01, 2013.
, “Physiological and Nutritional Roles of PPAR across Species”, PPAR Research, vol. 20131402086, no. 514, pp. 1 - 3, 2013.
, “A novel dynamic impact approach (DIA) for functional analysis of time-course omics studies: validation using the bovine mammary transcriptome.”, PLoS One, vol. 7, no. 3, p. e32455, 2012.
, “What Scientific Journals Can Do to Improve the Peer Review Process: Rewarding the Reviewer!”, Journal of Nutrition & Food Sciences, vol. 03, no. 04, 2013.
, “Fine metabolic regulation in ruminants via nutrient–gene interactions: saturated long-chain fatty acids increase expression of genes involved in lipid metabolism and immune response partly through PPAR-α activation”, British Journal of Nutrition, vol. 107180158177119161441771135, no. 02, pp. 179 - 191, 2012.
, “Gene networks driving bovine milk fat synthesis during the lactation cycle.”, BMC Genomics, vol. 9, p. 366, 2008.
, “Functional Role of PPARs in Ruminants: Potential Targets for Fine-Tuning Metabolism during Growth and Lactation.”, PPAR Res, vol. 2013, p. 684159, 2013.
, “Functional Role of PPARs in Ruminants: Potential Targets for Fine-Tuning Metabolism during Growth and Lactation”, PPAR Research, vol. 20132339714020548138479266338428909095887199279385947129614157683277896210385421762899113416947828743436877, no. 11158263615235266873163231111641110104497, pp. 1 - 28, 2013.
, “ACSL1, AGPAT6, FABP3, LPIN1, and SLC27A6 are the most abundant isoforms in bovine mammary tissue and their expression is affected by stage of lactation.”, J Nutr, vol. 138, no. 6, pp. 1019-24, 2008.
, “A Novel Dynamic Impact Approach (DIA) for Functional Analysis of Time-Course Omics Studies: Validation Using the Bovine Mammary Transcriptome”, PLoS ONE, vol. 7372681757413986403624401594491129854186802816371674480Reprod847621151459289827657022)73, no. 3, p. e32455, 2012.
, “Physiological and Nutritional Roles of PPAR across Species.”, PPAR Res, vol. 2013, p. 807156, 2013.
, “Innate Olfactory Responses of Asobara japonica Toward Fruits Infested by the Invasive Spotted Wing Drosophila”, Journal of Insect Behavior, vol. 30, no. 5180421, pp. 495 - 506, 2017.
, “ Innate olfactory responses Asobara japonica toward fruits infested by the invasive Spotted Wing Drosophila”, Journal of Insect Behavior, vol. 30, pp. 495-506, 2017.
, “13C and 15N stabilization dynamics in soil organic matter fractions during needle and fine root decomposition”, Organic Geochemistry, vol. 39, no. 4, pp. 465 - 477, 2008.
, “Western-style diet, with and without chronic androgen treatment, alters the number, structure, and function of small antral follicles in ovaries of young adult monkeys”, Fertility and Sterility, vol. 105, no. 4, pp. 1023 - 1034, 2016.
, “The effects of luteinizing hormone ablation/replacement versus steroid ablation/replacement on gene expression in the primate corpus luteum”, Molecular Human Reproduction, vol. 15231331381492275864795711841419183118123613088451173699013603789696731191148107081010, no. 3228115101116411512566136224639235341191985, pp. 181 - 193, 2009.
, “Dynamics of Immune Cell Types Within the Macaque Corpus Luteum During the Menstrual Cycle: Role of Progesterone1”, Biology of Reproduction, vol. 93964912961013137367951511593371228971942215015238172188414196446115701761131366159244112744541167238692094180881391213786156565, no. 5, 2015.
, “Non-genomic actions of progesterone and estrogens in regulating reproductive events in domestic animals.”, Vet J, vol. 176, no. 3, pp. 270-80, 2008.
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