2022-2023年农牧学院表学术论文212篇，其中SCI论文105篇，CSCD论文107篇，出版专著15部。2022年农牧学院发表SCI论文48篇，出版专著8部,2023年农牧学院发表学术论文164篇（SCI论文57篇，CSCD论文107篇），出版专著7部。

专著（15部）

[1]宋洋波（副主编）吐鲁番杏标准体系，2022,中国财富出版社ISBN：978-7-5047-7380-7

[2]高小龙（参编）动物性食品卫生学实验指导(第三版),2022,中国农业出版社 ISBN：978-7-109-29147-8

[3]陈付菊（参编）动物组织学与胚胎学实验指导，2022,西北农林科技大学出版社，ISBN ：978-7-5683-1086-4

[4]王树林主编 食品科学与工程虚拟仿真实验，2021.12青海民族出版社ISBN：978-75420-3786-2

[5]李希来（主编）高寒矿区生态修复技术创新与实践，2022科学出版社，

[6]孙海群(主编）青海种子植物形态及生态地理分布，2022中国农业科学技术出版社ISBN：978-7-5116-5493-9

[7]芦光新（副主编）草地保护学，2022中国农业大学出版社，ISBN：978-7-5655-2667-1

[8]白露超（主编）北川河源区国家级自然保护区昆虫2022中华工商联合出版社，ISBN：978-7-5158-3357-6

[9]莫重辉(副主编) 中国天然草原常见毒害草图谱2023, 中国农业科学技术出版社

[10]张寿（主编）柴达木肉牛养殖技术2023, 青海民族出版社ISBN：978-7-5420-4033-6

[11]芦光新（副主编）三江源区放牧高山嵩草草甸水源涵养功能研究2023,

[12]温小成（副主编）种子植物形态及生态地理分布2023, 中国农业科学技术出版社

[13]温小成（参编）三江源国家公园主要植物图谱2023, 青海民族出版社

[14]杨元武（主编）草业科学专业实践教学指导书2023, 中国农业科学技术出版社

[15]张英（主编）草业科学专业实践教学指导书2023, 中国农业科学技术出版社

2022年发表的SCI论文（48 篇）

[1]仝丽娜, The 16S rRNA Gene Sequencing of Gut Microbiota in Chickens Infected with Different Virulent Newcastle Disease Virus Strains, 2022, Animals（basel）

[2]文英, Intestinal Microbial Diversity of Free-Range and Captive Yak in Qinghai Province. , 2022, Microorganisms

[3]孙亚丽, Serological Analysis of IgG and IgM Antibodies against Anaplasma spp. in Various Animal Species of the Qinghai-Tibetan Plateau., 2022, Animals

[4]李积旭, Seroepidemiology of Neosporosis in Various Animals in the Qinghai-Tibetan Plateau. , 2022, Frontiers in Veterinary Science

[5]李积旭, Toxoplasma gondii and Neospora caninum Infections in Stray Cats and Dogs in the Qinghai-Tibetan Plateau Area, China. , 2022, Animals

[6]祁有朝, The Bile Acid Membrane Receptor TGR5 in Cancer: Friend or Foe? , 2022, Molecules

[7]祁有朝, Effect of Lycium barbarum polysaccharides on cell signal transduction pathways. , 2022, Biomedicine & Pharmacotherapy

[8]荆海霞, Effect of leptin on the growth and expression of STAT3 in yak mammary epithelial cells. , 2022, Veterinary World

[9]李英, Molecular detection of Anaplasma spp., Babesia spp. and Theileria spp. in yaks (Bos grunniens) and Tibetan sheep (Ovis aries) on the Qinghai-Tibetan Plateau, China. , 2022, Parasit Vectors

[10]李英, Spotted Fever Group Rickettsia Infecting Ticks (Acari: Ixodidae), Yak (Bos grunniens), and Tibetan Sheep (Ovis aries) in the Qinghai-Tibetan Plateau Area, China., 2022, Front Vet Sci

[11]陈付菊, Hypoxia-induced oxidative stress and apoptosis in scaleless carp gills, 2022, Fish Physiol Biochem

[12]丁保安, Emergence of mcr-1- and blaNDM-harboring IncHI2 Plasmid in Escherichia coli strains isolated from meat in Zhejiang, China, 2022, J Glob Antimicrob Resist

[13]丁保安, Antimicrobial resistance surveillance of Escherichia coli from chickens in the Qinghai Plateau of China, 2022, Frontiers in Microbiology

[14]丁保安, Effect of β-1,3/1,6-glucan on gut microbiota of yellow-feathered broilers, 2022, AMB Express

[15]丁保安, The effect of bile salt diet supplementation on genes related to fat metabolism in yellow-feathered broilers, 2022, Veterinary World

"[16]王树林, Dynamics of Physicochemical Properties, Functional Compounds and Antioxidant Capacity during Spontaneous Fermentation of Lycium Ruthenicum Murr. (Qinghai–Tibet Plateau) Natural Vinegar

, 2022, Foods"

[17]韩丽娟, Effects of different feeding regimes on muscle metabolism and its association with meat quality of Tibetan sheep, 2022, Food Chemistry

[18]韩丽娟, Metabolomics approach reveals high energy diet improves the quality and enhances the flavor of black Tibetan sheep meat by altering the composition of rumen microbiota, 2022, Frontiers in Nutrition

[19]拜彬强, Average daily gain and energy and nitrogen balances of 4-month-old growing female yak calves sucking once daily, 2022, Frontiers in Veterinary Science

[20]拜彬强, Selenite uptake by Medicago sativa L. roots, 2022, Grassland Science

[21]宋洋波, Dynamics of Physicochemical Properties, Functional Compounds and Antioxidant Capacity during Spontaneous Fermentation of Lycium Ruthenicum Murr. (Qinghai–Tibet Plateau) Natural Vinegar, 2022, Foods

[22]王进英, Adulteration detection of Qinghai-Tibet Plateau flaxseed oil using HPLC-ELSD profiling of triacylglycerols and chemometrics, 2022, LTW-Food Science and Technology

[23]王进英, Effect of different extraction methods on the quality characteristics of rapeseed oil and flaxseed oil, 2022, Journal of Food Quality

[24]桂林生, Effects of dietary concentrate: forage ratio on development of gastrointestinal tract in black Tibetan sheep, 2022, JOURNAL OF APPLIED ANIMAL RESEARCH

[25]桂林生, Effects of Dietary Non-Fibrous Carbohydrate (NFC) to Neutral Detergent Fiber (NDF) Ratio Change on Rumen Bacterial Community and Ruminal Fermentation Parameters in Chinese Black Tibetan Sheep (Ovis aries). , 2022, SMALL RUMINANT RESEARCH

[26]李希来, Macroaggregation is promoted more effectively by organic than inorganic fertilizers in farmland ecosystems of China—A meta-analysis, 2022, Soil and Tillage Research

[27]李希来, Change in Alpine Grassland NPP in Response to Climate Variation and Human Activities in the Yellow River Source Zone from 2000 to 2020, 2022, Sustainability

[28]李希来, Effects of Restoration Years on Vegetation and Soil Characteristics under Different Artificial Measures in Alpine Mining Areas, West China, 2022, Sustainability

[29]李希来, Effects of Alpine Wetland Degradation on Soil Microbial Structure and Diversity on the Qinghai Tibet Plateau, 2022, Eurasian Soil Science

[30]李希来, The Infuence of Degradation of Alpine Marshy Wetland on Ecosystem Respiration and Its Components, 2022, Wetlands

[31]李希来, Effects of Nitrogen Addition on Soil Carbon-Fixing Microbial Diversity on Different Slopes in a Degraded Alpine Meadow, 2022, Front

[32]李希来, Degradation reduces the diversity of nitrogen-fixing bacteria in the alpine wetland on the Qinghai-Tibet Plateau, 2022, Front

[33]姚喜喜, Phenological Phases of Forage and Rumen Fluid Affect Conjugated Linoleic Acids Composition of Milk of Yak from Qinghai Tibet Plateau, 2022, Pakistan Journal of Zoology

[34]谢永丽, Bacillus halotolerans KKD1 induces physiological, metabolic and molecular reprogramming in wheat under saline condition, 2022, Frontiers in plant science

[35]李长慧, Physiological adaptability of three gramineae plants under various vegetation restoration models in mining area of Qinghai-Tibet Plateau, 2022, Journal of Plant Physiology

[36]马坤, Application of Organic Fertilizer Changes the Rhizosphere Microbial Communities of a Gramineous Grass on Qinghai-Tibet Plateau, 2022, Microorganisms

[37]颜珲璘, Grass-legume mixtures enhance forage production via the bacterial community, 2022, Agriculture Ecosystems & Environment

[38]赵阳安, Effects of Microbial Fertilizer on Soil Fertility and Alfalfa Rhizosphere Microbiota in Alpine Grassland, 2022, Agronomy

[39]张丹, Prediction of the sea buckthorn AQP gene structure and its spatiotemporal expression pattern under drought stress, 2022, Journal of Plant Biochemistry and Biotechnology

[40]熊辉岩, Transcriptomic analysis of rapeseed seed development reveals how its special eco-environment results in high yield in high-altitude areas, 2022, Frontiers in Plant Science

[41]祁鹤兴, Root Rot of Angelica sinensis Caused by Clonostachys rosea and Fusarium acuminatum in China , 2022, Plant Disease

[42]祁鹤兴, First Report Disease of Clonostachys rosea Causing Root Rot on Astragalus membranaceus in China, 2022, Plant Disease

"[43]斯帅鹏, Development of novel

polymorphic microsatellite markers for Picea brachytyla, 2022, Molecular Biology Reports"

"[44]王芊, A Model-Based Assessment for the Ability of National

Nature Reserves to Conserve the Picea Species in China under Predicted Climate Conditions, 2022, Sustainability"

[45]王春晶, Determinants of species assemblages of insect pests in alpine forest ecosystems of western China, 2021, Forest Ecosystems

[46]周渊涛, The complete mitochondrial genome and phylogenetic analysis of Illiberis pruni Dyar, 1905 (Lepidoptera: Zygaenidae), 2022, Mitochondrial DNA

[47]周渊涛, Analysis of complete mitochondrial genome sequence of Pontania dolichura (Hymenoptera: Tenthredinidae) (Thomson, 1871), 2022, Mitochondrial DNA

[48]卢九斤、许云章, Nitrogen Fertilizer and Nitrapyrin for Greenhouse Gas Reduction in Wolfberry Orchards on the Qinghai–Tibetan Plateau, 2022, Agriculture

2023年发表的SCI论文（57篇）

[1]李玲霞, Inhibition of caspase-1-dependent apoptosis suppresses peste des petits ruminants virus replication, 2023, Journal of Veterinary Science

[2]孙亚丽, The diurnal salivary glands transcriptome of Dermacentor nuttalli from the first four days of blood feeding, 2023, Ticks Tick Borne Dis.2023 Jul;14(4):102178.

[3]孙亚丽, The life cycle of Dermacentor nuttalli from the Qinghai-Tibetan Plateau under laboratory conditions and detection of spotted fever group Rickettsia spp, 2023, Front Vet Sci. 2023 Feb 24:10:1126266."

[4]孙亚丽, De novo assembled transcriptomics assisted label-free quantitative proteomics analysis reveals sex-specific proteins in the intestinal tissue of Haemaphysalis qinghaiensis., 2023, Infect Genet Evol.2023 Apr:109:105409."

[5]李积旭, Hemalin vaccination modulates the host immune response and reproductive cycle of Haemaphysalis longicornis, 2023, Veterinary Parasitology, (2023)

doi:https://doi.org/10.1016/j.vetpar.2023.110051"

[6]康明, First description of Blastocystis sp. and Entamoeba sp. infecting zoo animals in the Qinghai-Tibetan plateau area, China, 2023, Front Cell Infect Microbiol.2023 Jun 8:13:1212617."

[7]冶贵生, Effects of three different probiotics of Tibetan sheep origin and their complex probiotics on intestinal damage, immunity, and immune signaling pathways of mice infected with Clostridium perfringens type C, 2023, Frontiers in Microbiology, 2023,14:1177232

[8]吴华, The Effect of Lycium ruthenicum Murry Anthocyanins on the Apoptosis and Proliferation of H9c2 Cell Induced by Hypoxia, 2023, Journal of Food Biochemistry, vol. 2023

[9]韩丽娟, Metabolomics approach reveals high energy diet improves the quality and enhances the flavor of black Tibetan sheep meat by altering the composition of rumen microbiota, 2023, Frontiers in Nutrition，2023,9: 915558.

[10]韩丽娟, Metabolome and microbiome analysis revealed the effect mechanism of different feeding modes on the meat quality of Black Tibetan sheep, 2023, Frontiers in Microbiology., 2023,6: 915558

[11]韩丽娟, Insight into the differences of meat quality between Qinghai white Tibetan sheep and black Tibetan sheep from the perspective of metabolomics and rumen microbiota, 2023, Food Chemistry: X ., 2023,19:100843

[12]韩丽娟, Exploring the effects of palm kernel meal feeding on the meat quality and rumen microorganisms of Qinghai Tibetan sheep，, 2023, Food Sci Nutr, 2023;01:1–19

[13]韩丽娟, Effect of Different Heat Treatments on the Quality and Flavor Compounds of Black Tibetan Sheep Meat by HS-GC-IMS Coupled with Multivariate Analysis, 2023, Molecules 2023, 28, 165

[14]院珍珍, The antioxidant mechanism of exopolysaccharides’ synthesis from Agaricus bitorquis (Quél.) Sacc. Chaidam under the infuence of Lycium ruthenicum Murr. anthocyanin extract, 2023, Macromolecular Research，网络首发

[15]院珍珍, Glycolysis characteristics of intracellular polysaccharides from Agaricus bitorquis (Qu´el.) sacc. Chaidam and its effects on intestinal flora from different altitudes of mice in vitro fermentation, 2023, Food Research International，网络首发

[16]桂林生, Effects of dietary forage-to-concentrate ratio on fat deposition, fatty acid composition, oxidative stability and mRNA expression of sirtuins genes of subcutaneous fat in sheep, 2023, JOURNAL OF APPLIED ANIMAL RESEARCH, 2023, 51, 382-387

[17]桂林生, Fat deposition, fatty acid profiles, antioxidant capacity and differentially expressed genes in subcutaneous fat of Tibetan sheep fed wheat-based diets with and without xylanase supplementation, 2023, JOURNAL OF ANIMAL PHYSIOLOGY AND ANIMAL NUTRITION

[18]丁保安, Campylobacter jejuni infection induces dynamic expression of avian host defense peptides in vitro and in vivo, 2023, Veterinary Microbiology 2023

[19]张军霞, Differential expression of mRNAs encoding MSTN/SMAD signaling pathway molecules in muscle tissue of Tibetan sheep, 2023, Food Science & Nutrition.2023，"

[20]张军霞, Molecular characterization and expression of TGFβRI and TGFβRII and its

association with litter size in Tibetan sheep, 2023, Vet Med Sci. 2023, 9(2):934-944."

[21]叶英, Rapid detection of I−in food samples by cholesteric chiral artificial receptor L5, 2023, Food Chemistry

[22]叶英, Rapid Detection of Ag+ in Food Using Cholesteric Chiral Artificial Receptor L5, 2023, Microchemical Journal

[23]叶英, Widely targeted metabolome profifiling of different plateau raspberries and berry parts provides innovative insight into their antioxidant activitie, 2023, Front. Plant Sci.

[24]叶英, Chiral cholesteric molecular tweezerartificial receptors 7a for the rapid detection of tryptophan and the chiral resolution of D-/L-tryptophan, 2023, Journal of Food Composition and Analysis.

[25]叶英, Modulation of gut flore by dietary fibers fromPyrus bretschneideriRehd.: Evaluation of fermentation characteristics using a colonic in vitro fermentation model, 2023, Journal of Functional Foods

[26]李长斌, Grazing Intensity Affects Soil Organic Carbon Stock and Its Chemical Compositions in Potentilla fruticosa Shrublands on the Tibetan Plateau., 2023, Journal of Soil Science and Plant Nutrition，2023."

[27]张英, Diversity of soil bacteria in alpine coal slag mountain grassland in diferent vegetation restoration years, 2023, Annals of Microbiology

[28]谢永丽, Analysis of the Biological Activity and Whole Genome Sequencing of Bacillus cereus CDHWZ7 Isolated from the Rhizosphere of Lyciumruthenicum on the Tibetan Plateau, 2023, Agriculture

[29]芦光新, Grass-microbial inter-domain ecological networks associated with alpine grassland productivity, 2023, Frontiers in Microbiology, 14

[30]芦光新, Response of Organic Fertilizer Application to Soil Microorganisms and Forage Biomass in Grass–LegumeMixtures, 2023, Agronomy,2023,13(2):481.

[31]芦光新, Non-targeted metabolomics analysis reveals the mechanism of arbuscular mycorrhizal symbiosis regulating the cold-resistance of Elymus nutans, 2023, Frontiers in Microbiology，2023,1134585

[32]芦光新, Grass-legume Mixture with Rhizobium Inoculation Enhanced the Restoration Effects of Organic Fertilizer, 2023, Microorganisms，2023,11,1114

[33]闫京艳, In plateaus, land cover replaced climate as the vital environmental factor on the spatial composition of bumblebees with the altitude rising., 2023, Ecological Entomology.2023;48(4),409–420.

[34]闫京艳, Impacts of future climate on the distribution of 4 bumblebee species in the Qinghai–Tibet Plateau., 2023, Journal of Insect Science. 2023; 23(4): 14; 1–8.

[35]白露超, Erysiphe thuemenii Causing powdery mildew on Potentilla indica in China, 2023, Canadian Journal of Plant Pathology，2023, Vol. 45, Nos. 5-6, 446–450

[36]唐楠, Molecular cloning and prokaryotic expression of the polyprotein gene of tulip breaking virus, 2023, Pakistan Journal of Botany，2023，56（2）

[37]王春晶, Spatial prioritization for the conservation of terrestrial vertebrate genera in the Neotropics, 2023, Biodiversity and Conservation,2023,32:3423–3445

[38]王春晶, Effects of Habitat Heterogeneity and Topographic Variation on Insect Pest Risks in Alpine Regions, 2023, Land,2023,12,1314

[39]王春晶, Comparison and phylogenetic analysis of the chloroplast genomes of Sabina przewalskii f. pendula and Juniperus przewalskii, 2023, Journal of Animal & Plant Sciences, 2023,33(2), 462-473

[40]王春晶, Development and characterization of 165 SNP markers in Mimosa bimucronata (Candolle) O. Kuntze, 2023, Conservation Genetics Resources, 2023,15, 7-14.

[41]桂林生, Effects of dietary forage-to-concentrate ratio on fat deposition, fatty acid composition, oxidative stability and mRNA expression of sirtuins genes of subcutaneous fat in sheep, 2023, JOURNAL OF APPLIED ANIMAL RESEARCH, 2023, 51, 382-387

[42]桂林生, Fat deposition, fatty acid profiles, antioxidant capacity and differentially expressed genes in subcutaneous fat of Tibetan sheep fed wheat-based diets with and without xylanase supplementation, 2023, JOURNAL OF ANIMAL PHYSIOLOGY AND ANIMAL NUTRITION

[43]丁保安, Campylobacter jejuni infection induces dynamic expression of avian host defense peptides in vitro and in vivo, 2023, Veterinary Microbiology 2023

[44]张军霞, Differential expression of mRNAs encoding MSTN/SMAD signaling pathway molecules in muscle

tissue of Tibetan sheep, 2023, Food Science & Nutrition.2023，"

[45]张军霞, Molecular characterization and expression of TGFβRI and TGFβRII and its

association with litter size in Tibetan sheep, 2023, Vet Med Sci. 2023, 9(2):934-944."

[46]祁鹤兴, Cladosporium species causing leaf spot on silage maize based on multi-locus phylogeny in China, 2023, Journal of Phytopathology, 2023, 171:82-91.

[47]李希来, Analyzing the recovery mechanisms of patchy degradation and its response to mowing and plateau pika disturbances in alpine meadow, 2023, Ecological Indicators　

[48]李希来, Positive effects of fungal β diversity on soil multifunctionality mediated by pH in the natural restoration succession stages of alpine meadow patches, 2023, Ecological Indicators

[49]李希来, Responses of soil microbial activities to soil overburden thickness in restoring a coal gangue mound in an alpine mining area, 2023, Ecological Indicators

[50]李希来, N2-fixing bacteria are more sensitive to microtopography than nitrogen addition in degraded grassland, 2023, Frontiers in Microbiology

[51]李希来, Comparative responses of carbon flux components in recovering bare patches of degraded alpine meadow in the Source Zone of the Yellow River, 2023, Science of The Total Environment

[52]李希来, A Study on the C, N, and P Contents and Stoichiometric Characteristics of Forage Leaves Based on Fertilizer-Reconstructed Soil in an Alpine Mining Area, 2023, Plants

[53]李希来, Relationship between Species Diversity and Community Stability in Degraded Alpine Meadows during Bare Patch Succession, 2023, Plants

[54]李希来, Variability in soil nematode communities across recovery patches in degraded Alpine meadows of the Yellow River source region, 2023, Nematology

[55]李希来, Effects of Long-Term Exclosure on Main Plant Functional Groups and Their Biochemical Properties in a Patchily Degraded Alpine Meadow in the Source Zone of the Yellow River, West China, 2023, Agronomy

[56]李希来, A Topographic Perspective on the Propensity for Degradation of Plateau Swampy Meadows in Maduo County, West China, 2023, Land

[57]李希来, Watershed-level spatial pattern of degraded alpine meadow and its key influencing factors in the Yellow River Source Zone of West China, 2023, Ecological Indicators

2023年发表中文论文（107篇）

[1]祁有朝, 组学技术在糖尿病研究中的应用, 2023, 中国医院药学杂志

[2]祁有朝, 双酚类化合物对机体影响的研究进展, 2023, 食品工业科技

[3]祁有朝, 黑果枸杞和黄果枸杞的广泛靶向代谢组学分析, 2023, 食品科学

[4]吴华, 生物发酵饲料在猪养殖中的应用, 2023, 饲料工业（网络首发）

[5]吴华, 黑果枸杞花青素通过调节Ca2+稳态对低氧诱导的H9c2大鼠心肌细胞的保护作用, 2023, 中国兽医科学（网络首发）

[6]吴华, 微生态制剂作用机制及对畜禽免疫功能的影响, 2023, 饲料研究（网络首发）

[7]吴华, ceRNA在动物低氧适应性中的研究进展, 2023, 饲料研究（网络首发）

[8]吴华, 天然提取物在影响动物氧化应激中的研究进展, 2023, 饲料研究,2023(18):145-149

[9]吴华, 紫锥菊提取物菊苣酸对低氧环境下H9c2大鼠心肌细胞增殖的影响, 2023, 中国兽医学报,2023,43(08):1720-1724+1733

[10]吴华, 黑果枸杞花青素介导低氧诱导的H9c2大鼠心肌细胞ceRNA调控网络构建, 2023, 农业生物技术学报,2023,31(08):1671-1683.

[11]吴华, 黑果枸杞花青素对低氧诱导的H9c2大鼠心肌细胞凋亡的影响, 2023, 畜牧兽医学报,2023,54(08):3490-3499

[12]吴华, 黑果枸杞花青素对H9c2大鼠心肌细胞抗氧化能力、炎性因子及能量代谢作用的影响, 2023, 饲料研究,2023,46(09):61-65.

[13]吴华, 菊苣酸对低氧诱导下的H9c2大鼠心肌细胞氧化损伤水平、炎性因子、能量代谢的影响, 2023, 饲料研究,2023,46(07):73-76

[14]吴华, 低氧环境下菊苣酸对SD大鼠心肌组织低氧适应性的影响, 2023, 中国兽医学报,2023,43(02):348-356.

[15]吴华, 低氧环境下菊苣酸对SD大鼠脂肪组织抗氧化能力、炎性因子及能量代谢的影响, 2023, 中国兽医学报,2023,43(02):357-363+373.

[16]吴华, 黑果枸杞花青素对低氧诱导的H9c2大鼠心肌细胞增殖的影响, 2023, 东北农业大学学报,2023,54(7): 42~49.

[17]韩丽娟, 超声辅助酶法提取黄刺浆果总黄酮的工艺优化及其生物活性研究, 2023, 粮食与油脂, 2023, 36(09): 105-110.

[18]韩丽娟, 黄刺多糖工艺优化及其对过氧化氢损伤的胰岛β细胞的保护作用, 2023, 食品与发酵工业,2023,49(03):146-156.

[19]韩丽娟, 复合菌种发酵对蚕豆蛋白理化性质及其功能特性的影响, 2023, 食品与发酵工业,2023,49(04):183-188.

[20]院珍珍, 响应面法优化地皮菜总三萜提取工艺及其抗氧化活性, 2023, 食品研究与开发,2023,44(4):86-91

[21]院珍珍, 普鲁兰酶协同α-葡萄糖苷酶青稞快消化淀粉含量的工艺优化研究, 2023, 中国酿造,2023,42(1):115-120

[22]院珍珍, 鹿角菜多酚提取工艺优化及抗氧化活性研究, 2023, 中国食品添加剂,2023,(9):98-106

[23]院珍珍, 响应面法优化地皮菜总三萜提取工艺及其抗氧化活性, 2023, 食品研究与开发,2023,44(4):86-91

[24]院珍珍, 普鲁兰酶协同α-葡萄糖苷酶青稞快消化淀粉含量的工艺优化研究, 2023, 中国酿造,2023,42(1):115-120

[25]院珍珍, 鹿角菜多酚提取工艺优化及抗氧化活性研究, 2023, 中国食品添加剂,2023,(9):98-106

[26]罗毅皓, 青稞酒糟多酚提取工艺优化及其抗氧化性, 2023, 食品研究与开发,2023,44(19):140-146

[27]孙万成, 牦牛酥油乳脂肪球膜蛋白对双歧杆菌增殖的影响, 2023, 中国乳品工业,2023,51(06):4-9

[28]孙万成, 不同部位及地区藏羊肉的肉品质及其组织学特性, 2023, 食品研究与开发,2023,44(09):59-68

[29]罗毅皓, 基于气相色谱-离子迁移谱分析不同地区羊肉的挥发性风味化合物, 2023, 食品与发酵工业,2023,49(10):265-272

[30]罗毅皓, 功能活性因子对机体白色和棕色脂肪组织的调控机理研究进展, 2023, 食品科学,2023,44(15):278-288

[31]桂林生, 低蛋白日粮中不同比例氨基酸对藏羊背腰最长肌肉品质、氨基酸和脂肪酸组成以及维生素和矿物质含量的影响, 2023, 草业学报

[32]桂林生, 颗粒饲料中小麦添加比例对青海藏羊生长性能与肠道发育的影响, 2023, 西北农林科技大学学报

[33]张军霞, 藏羊BMPRII基因的序列特征和表达分析, 2023, 西南农业学报,2023,36(01):194-202.

[34]张军霞, 2-甲氧基肉桂醛缓解猪IPEC-J2细胞氧化损伤的效果研究, 2023, 中国畜牧杂志,2023,59(03):247-253.

[35]张军霞, 绵羊繁殖性能分子调控机制的研究进展, 2023, 中国草食动物学报,2023,43(03):47-52.

[36]叶英, 黄果梨膳食纤维咀嚼片配方优化及其降糖活性研究, 2023, 食品研究与开发

[37]叶英, 黄果梨饮料加工技术优化及稳定性研究, 2023, 食品工业

[38]叶英, 不同萌发条件及加工方法对藜麦品质的影响, 2023, 中国粮油学报

[39]叶英, 红枸杞甜型酒发酵工艺响应面法优化及成分变化规律研究, 2023, 食品研究与开发

[40]叶英, 肉苁蓉原浆口服液制备工艺优化及成分分析, 2023, 食品研究与开发

[41]叶英, 狭果茶藨子有机酸制备工艺优化及抗氧化活性研究, 2023, 中国食品添加剂

[42]叶英, 以研助教、以赛促教+线上线下虚实结合模式下的《食品化学》实践教学改革, 2023, 国家通用语言文字教育与研究

[43]谢永丽, 解淀粉芽孢杆菌DGL1促燕麦生长分子机制及代谢通路探究, 2023, 草地学报

[44]谢永丽, 4株促紫花苜蓿生长的芽孢杆菌分子鉴定及其生物活性分析, 2023, 西北农业学报

[45]谢永丽, 干旱沙地白刺根际 Bacillus halotolerans DGL6 对“青麦 7 号”的促生及防病效果, 2023, 微生物学通报

[46]赵孟良, 菊芋功能成分及其在畜牧生产中的应用进展, 2023, 饲料研究

[47]赵孟良, 菊芋NAC转录因子家族基因的鉴定及分析, 2023, 生物技术通报

[48]朱惠琴, 田葛缕子叶绿体基因组微卫星特征分析, 2023, 北方园艺

[49]芦光新, 环青海湖地区两种禾本科牧草根际微生物差异分析, 2023, 中国草地学报2023,45（07）

[50]芦光新, 有机肥改变了退化人工草地微生物群落网络结构和潜在功能, 2023, 草地学报，2023，31(9)

[51]芦光新, 短期施有机肥对‘川草2号’老芒麦AMF种类及分布的影响, 2023, 草地学报，2023

[52]芦光新, 有机肥与补播对退化人工草地植被与土壤的影响, 2023, 中国草地学报，2023,45（02）:67-75

[53]芦光新, 4种宿主植物对根内球囊霉和摩西球囊霉的扩繁效果及菌根接种效应, 2023, 草原与草坪，2023,43(03):84-91

[54]闫京艳, 15种熊蜂全基因组SSR分布规律研究, 2023, 南方农业学报，2023

[55]熊辉岩, 大麦光合碳途径关键酶基因的生物信息学分析, 2023, 分子植物育种

[56]王金贵, 地膜覆盖及不同施肥处理对根际土壤微生物数量和酶活性的影响, 2023, 西北农业学报，2023，32（3）：429-439

[57]白露超, 青海省主要林区白粉菌物种多样性研究, 2023, 青海大学学报，2023,41(04): 16-23

[58]巨秀婷, 郁金香不同组织RT-qPCR的内参基因筛选与稳定表达分析, 2023, 南方农业学报，2023

[59]巨秀婷, 基于一流专业建设视角的设施园艺和无土栽培实践教学探究, 2023, 科教导刊,2023(06):23-25.

[60]巨秀婷, 新农科背景下“园艺学概论”混合式课程建设探索与实践, 2023, 现代园艺,2023,46(14)

[61]巨秀婷, 郁金香HKT1基因参与盐胁迫响应的时空表达模式分析, 2023, 北方园艺,2023(16):71-77.

[62]巨秀婷, 柔毛郁金香叶绿体基因组密码子偏好性分析, 2023, 江苏农业科学

[63]巨秀婷, 薰衣草种子萌发对温度和赤霉素的响应, 2023, 种子，2023

[64]唐楠, 万寿菊雄性不育两用系遗传转化体系的建立, 2023, 分子植物育种，2023，21（19）：6398-6405

[65]唐楠, 专业Seminar课程在研究生科研能力培养中的应用——以农艺与种业专业硕士园艺方向为例, 2023, 现代园艺，2023，46（07）

[66]唐楠, 基于SRAP分子标记的孔雀草种质资源遗传多样性分析, 2023, 青海大学学报，2023,41(01)

[67]唐楠, 黄化对兰州百合植株生长发育的影响, 2023, 青海大学学报，2023,41(02)

[68]马玉花, 中国沙棘HrANR基因及类黄酮累积与抗旱的关系, 2023, 广西植物,2023

[69]马玉花, 沙棘rbcL基因的扩增及序列分析, 2023, 北方园艺,2023

[70]马玉花, 中国沙棘HrNHX6基因克隆及其在干旱胁迫下的表达分析, 2023, 福建农林学报,2023,38(07)

[71]马玉花, 盐胁迫下中国沙棘HrNHX6基因的时空表达模式研究, 2023, 山东农业科学,2023

[72]马玉花, 干旱胁迫下沙棘NAC基因的时空表达模式, 2023, 西北农业学报,2023,32(06)

[73]马玉花, 西藏沙棘根瘤内生假单胞菌的分离鉴定及促生性研究, 2023, 福建农林学报,2023,38(05)

[74]马玉花, 干旱胁迫下沙棘CMO基因的时空表达模式与蛋白结构预测, 2023, 西北林学院学报,2023

[75]马玉花, 中国沙棘SSR-PCR反应体系的优化及引物开发, 2023, 基因组学与应用生物学,2023

[76]马玉花, 干旱胁迫下沙棘脯氨酸含量及HrP5CS基因表达分析, 2023, 福建农林大学学报(自然科学版),2023

[77]马玉花, 西藏沙棘根瘤内生菌假单胞菌属的分离与鉴定, 2023, 甘肃农业大学学报,2023,58(03)

[78]马玉花, 西藏沙棘AQP基因的扩增及生物信息学分析, 2023, 青海科技,2023,30(02)

[79]马玉花, 基于ITS的青海不同地区铁棒锤遗传变异分析, 2023, 分子植物育种,2023

[80]马玉花, 中国沙棘Hr3GT基因的扩增及生物信息学分析, 2023, 青海农林科技,2023，(01)

[81]马玉花, 青海野生中国沙棘资源表型性状多样性分析, 2023, 植物遗传资源学报,2023,24(04)

[82]马玉花, 中国沙棘根际四株假单胞菌的分离、鉴定及促生能力的比较, 2023, 北方园艺,2023(01)

[83]桂林生, 低蛋白日粮中不同比例氨基酸对藏羊背腰最长肌肉品质、氨基酸和脂肪酸组成以及维生素和矿物质含量的影响, 2023, 草业学报

[84]桂林生, 颗粒饲料中小麦添加比例对青海藏羊生长性能与肠道发育的影响, 2023, 西北农林科技大学学报

[85]丁保安, 饲粮代谢能水平对 14 ~ 17 周龄不同性别北京油鸡 育肥期生长性能、屠宰性能、肉品质及 血清生化指标的影响, 2023, 动物营养学报，2023

[86]张军霞, 藏羊BMPRII基因的序列特征和表达分析, 2023, 西南农业学报,2023,36(01):194-202.

[87]张军霞, 2-甲氧基肉桂醛缓解猪IPEC-J2细胞氧化损伤的效果研究, 2023, 中国畜牧杂志,2023,59(03):247-253.

[88]张军霞, 绵羊繁殖性能分子调控机制的研究进展, 2023, 中国草食动物学报,2023,43(03):47-52.

[89]王东霞, 保水剂处理下呼伦贝尔地区燕麦草产量和营养成分差异分析, 2023, 草业科学，2023.40（10）：1-10

[90]王东霞, 呼伦贝尔地区燕麦与豌豆混播对燕麦产量和品质的影响, 2023, 湖南农业科学，2022（11）：19-23

[91]谢得娟, 西宁市周边地区野生灌木开发利用价值评价, 2023, 青海大学学报，2023，5（41）

[92]赵艳艳, 野生青海茄参种子萌发的初步探索, 2023, 甘肃农业大学学报,2023

[93]赵艳艳, 野生青海茄参不同组织营养品质分析, 2023, 甘肃农业大学学报,2023

[94]赵艳艳, 基于转录组的青海茄参CML基因家族鉴定及冷胁迫表达分析不同组织营养品质分析, 2023, 甘肃农业大学学报,2023

[95]赵艳艳, 低温胁迫对青海茄参叶片抗氧化酶活性及丙二醛与脯氨酸含量的影响, 2023, 青海大学学报，2023，41(5),57-62

[96]祁鹤兴, 青贮玉米蠕形菌的分离鉴定及其致病性分析, 2023, 草地学报,2023,31(01):40-49.

[97]周渊涛, 青海草原毛虫转录组分析及SSR位点开发, 2023, 草地学报，2023，31（09）2653—2662

[98]周渊涛, 青海草原毛虫气味结合蛋白基因与生物信息学分析, 2023, 草地学报，2023，31（03）688—698

[99]李希来, 青藏高原高原鼠兔活动节律监测方法研究, 2023, 动物学杂志

[100]李希来, 施肥和控鼠对黄河源区斑块化退化高寒草甸植被特征及植物化学计量的影响, 2023, 西北农业学报

[101]李希来, 施肥和控鼠对退化高寒草甸植物-土壤-微生物碳氮磷化学计量特征的影响, 2023, 中国草地学报

[102]李希来, 高原鼠兔和高原鼢鼠种群暴发区干扰斑块空间分布格局与演替规律, 2023, 生态学报

[103]李希来, 基于高分影像的黄河源青海片区退化草地识别, 2023, 西北农业学报

[104]李希来, 围栏封育对黄河源区斑块化退化高寒草甸碳交换及其组分的影响, 2023, 生态学报

[105]李希来, 基于高寒矿区颗粒有机肥和羊板粪配施的无客土重构土壤理化性质分析, 2023, 中国土壤与肥料

[106]李希来, 黄河上游区斑块化退化高寒草甸土壤线虫群落分布特征, 2023, 草地学报

[107]李希来, 黄河源永曲河流域高寒草甸地上生物量模拟与时空分布特征研究, 2023, 草地学报