白肉雞生產系統環境因子監控暨家禽大腸桿菌毒力因子調查

Lin-Ching Huang; 黃琳晶

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/60277

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	蔡向榮(Hsiang-Jung Tsai)
dc.contributor.author	Lin-Ching Huang	en
dc.contributor.author	黃琳晶	zh_TW
dc.date.accessioned	2021-06-16T10:14:41Z	-
dc.date.available	2020-06-29
dc.date.copyright	2013-08-23
dc.date.issued	2013
dc.date.submitted	2013-08-19
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Effect of normal intestinal flora of 　　　chicks on colonization by virulent colicin V-producing, avirulent, and mutant colicin 　　　V-producing avian Escherichia coli. Avian Diseases, 38:141-145, 1994. Wooley RE, Spears KR, Brown J, Nolan LK, Fletcher OJ. Relationship of Complement 　　　Resistance and Selected Virulence Factors in Pathogenic Avian Escherichia coli. 　　　Avian Diseases, 36(3):679-684, 1992. Yaguchi K, Ogitani T, Osawa R, Kawano M, Kokumai N, Kaneshige T, Noro T, Masubuchi K, Shimizu Y. Virulence Factors of Avian Pathogenic Escherichia Coli Strains Isolated from Chickens with Colisepticemia in Japan. Avian Diseases, 51(3):656-662, 2007.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/60277	-
dc.description.abstract	自2011年3月至2012年年4月，至嘉義縣、宜蘭縣、新竹縣、桃園縣七個白肉雞場進行，包括雞舍中二氧化碳、硫化氫、一氧化碳、氨氣、風速、相對濕度、溫度、墊料水活性、墊料pH值、雞隻體內大腸桿菌、梭菌、墊料內沙門氏菌、梭菌等環境因子的採樣檢測或測量。22批次生產效能數據中，育成率為86%∼99%，各週死亡率又以第一週及第五週較高。結果發現，二氧化碳濃度與雞隻體內大腸桿菌對於白肉雞育成率有影響，若二氧化碳若超過1,500 ppm則育成率會明顯低於97%（P<0.05）。雞隻體內腸道與肺部大腸桿菌的存在，亦與育成率高低呈正相關（P<0.05）。此外，雖然氨氣、墊料水活性度及墊料pH值並未直接與育成率相關，然經由Pearson積差相關分析結果顯示，此三變數因子皆與大腸桿菌呈正相關（P<0.05），因此若氨氣及墊料水活性度、墊料pH值過高，尤其根據費雪精確檢定結果，知道當墊料水活性度在0.9aw以上或墊料pH值高於8時，將導致大腸桿菌較易滋長，也會間接影響育成率的結果。　　欲了解家禽病原性大腸桿菌於雞隻肺臟與腸道之毒力因子分佈是否有差異，結果顯示，來自欲淘汰或死亡雞隻的大腸桿菌，肺臟與腸道分離株其毒力因子盛行率無顯著差異。表示可能可以由雞隻糞便中分離的大腸桿菌來預測發生呼吸道感染的大腸桿菌之性狀。毒力因子以帶有鐵運輸基因、帶有螯鐵蛋白受體基因、螯鐵分子受體基因、增加血清存活基因、帶有蛋白分解酵素基因與帶有溫度敏感的血凝素基因的大腸桿菌盛行率較高，皆有50%以上。而抗藥性表現部分，有60%以上的分離株皆對Erythromycin、Amoxycillin、Ampicillin、Tetracycline、Sulphamethoxazole/Trimethoprim、Nalidixic Acid、Neomycin、Oxolinic Acid、Florfenicol及Streptomycin等10種抗菌劑有抗藥性，因此對抗菌劑的抗藥性廣泛存在實為家禽產業一大隱憂，應做好監測抗菌劑的審慎使用以避免抗藥性的傳播。	zh_TW
dc.description.abstract	In this project we have completed the monitoring of the environmental quality include temperature, humidity, wind speed, carbon dioxide, carbon monoxide, hydrogen sulfide, ammonia, litter water activity, litter pH values, water quality, Clostridium, Escherichia coli of poultry, Clostridium, Salmonella of litter and so on of five targeted chicken farms. The seven farms were located in Hsinchu County (3 farms), Taoyuan County (1 farm) , Ilan County (2 farms) and Chiayi County (1 farm). The livability of chickens in the five farms was from 94% to 99%. The results showed that the carbon dioxide and Escherichia coli of poultry did affect the livability of chickens. If the carbon dioxide was over 1500 ppm, the livability of chickens would be distinctly less than 97% (p<0.05). And the Escherichia coli of poultry were also significantly correlated to the livability of chickens. Although ammonia, litter water activity, and litter pH values were not direct correlated to the livability of chickens, through a Pearson correlation coefficient, the results revealed that ammonia, litter water activity, and litter pH values all were correlated to Escherichia coli of poultry, The above-mentioned three factors could indirectly relate to the livability of chickens. The increase of ammonia, litter water activity, and litter pH values accounted for growth of Escherichia coli. 　　Escherichia coli is strains cause chicken respiratory tract causes, colibacillosis, even cause extensive mortality in poultry flocks, it was called avian pathogenic Escherichia coli. Recent reports showed that the avian pathogenic Escherichia coli is associated with certain virulence genes (sitA, irp2, iroN, fyuA, iutA, ompT, cvaC, iss and tsh). Identification and characterization of these genes are essential to implementing efficient disease control and prevention systems. The aims of the study were to identify the virulence genes and the antibiotic resistance of avian pathogenic Escherichia coli strains in Taiwan. And determine the difference of antimicrobial sensitivities, distribution of virulence factors between avian pathogenic Escherichia coli from lung and Intestinal of chicken.There were 60 Escherichia coli collected from chicken in six farms.The PCR of the tested samples revealed a higher prevalence of the following genes: sitA 90%, iutA 90%, iss 88%, iroN 63%, ompT 62% and tsh 57%. The study of antibiotic susceptibility profiles showed more than 60% resistance levels against Erythromycin, Amoxycillin, Ampicillin, Tetracycline, Sulphamethoxazole/Trimethoprim, Nalidixic Acid, Neomycin, Oxolinic Acid, Florfenicol and Streptomycin. The resistance rates of virulence factors and antimicrobial both had no significant difference between avian pathogenic Escherichia coli from lung and Intestinal of chicken. The indiscriminate use of antibiotics may increase the risk of development of drug-resistant Escherichia coli strains in Taiwan. Therefore, by monitoring flocks of resistance patterns of Escherichia coli, to in order to reduce the generation and dissemination of Escherichia coli.	en
dc.description.provenance	Made available in DSpace on 2021-06-16T10:14:41Z (GMT). No. of bitstreams: 1 ntu-102-R98629036-1.pdf: 1817181 bytes, checksum: f2e3598aa409a53a4b7e7fe6e604904b (MD5) Previous issue date: 2013	en
dc.description.tableofcontents	總目錄口試委員審定書 i 誌謝 ii 摘要 iv Abstract vii 總目錄 viiii 圖目錄 xiiii 表目錄 xivii 第一章　緒言 1 第二章文獻回顧 3 第一節台灣家禽現況 3 第二節環境因子 4 2-2-1 溫度 4 2-2-2 相對溼度 4 2-2-3 風速 5 2-2-4 二氧化碳 5 2-2-5 一氧化碳 5 2-2-6 硫化氫 6 2-2-7 氨氣 6 2-2-8 墊料pH值 7 2-2-9 墊料水活性度 7 第三節大腸桿菌介紹 8 2-3-1 大腸桿菌綜論 8 2-3-2 腸道外致病性大腸桿菌介紹 10 2-3-3 家禽病原性大腸桿菌的毒力因子 12 2-3-4 家禽病原性大腸桿菌盛行概況 15 第三章材料與方法 18 第一節採樣流程及方法 18 3-1-1入雛前之檢測 19 3-1-1-1入雛前雞舍環境樣本採集 19 3-1-1-2 入雛前墊料採集 20 3-1-1-3 入雛前飼料採集 20 3-1-1-4飲水之檢測 20 3-1-2. 飼養期間之監測 20 3-1-1-1血清學檢測 20 3-1-1-2生物檢體採集 21 3-1-1-3墊料樣本採集 21 3-1-1-4飼料樣本採集 21 3-1-1-5 空氣品質偵測 21 3-1-3-6 指標與建議值 22 第二節各微生物之分離與鑑定 24 3-2-1沙門氏菌之分離與鑑定 24 3-2-1-1採樣與前增菌培養 24 3-2-1-1-1 一日齡雛雞 24 3-2-1-1-2飼料 24 3-2-1-1-3墊料 24 3-2-1-1-3飲水 24 3-2-1-2增菌培養 24 3-2-1-3沙門氏菌鑑定 25 3-2-1-4血清型鑑定 25 3-2-2大腸桿菌之分離與鑑定 26 3-2-2-1大腸桿菌之分離與初步鑑定 26 3-2-2-2大腸桿菌之PCR鑑定 27 3-2-3彎曲桿菌之分離與鑑定 28 3-2-3-1彎曲桿菌之前置處理 28 3-2-3-2彎曲桿菌之PCR鑑定 29 3-2-4梭菌之分離與鑑定 30 3-2-4-1採樣與前增菌培養 30 3-2-4-1-1雞隻檢體 30 3-2-4-1-2墊料檢體 30 3-2-4-2梭菌之鑑定 30 3-2-4-2-1 Iron-milk presumptive test 30 3-2-4-2-2 Motility test & Nitrate reduction test 31 3-2-4-2-3 Lactose fermentation test & Gelatin liquefaction test 31 3-2-4-2-4 PCR鑑定 31 3-2-5 黴漿菌之聚合酶鏈鎖反應 32 第三節 pH值與水活性度測定 34 3-3-1墊料樣本測定 34 3-3-2飼料樣本測定 34 第四節大腸桿菌毒力因子偵測 35 第五節大腸桿菌抗菌劑感受性試驗 36 第六節流行病學分析 37 第七節統計分析 38 3-7-1 環境因子與生產效能的統計分析 38 3-7-2 毒力因子的統計分析 38 第四章結果 39 第一節白肉雞場環境與微生物因子偵測結果 39 4-1-1沙門氏菌分離率 39 4-1-2彎曲桿菌分離率 41 4-1-3梭菌分離率 42 4-1-4大腸桿菌分離率 43 4-1-5黴菌分離率 45 4-1-6 黴漿菌陽性率 45 4-1-7 水質檢測結果 45 第二節白肉雞場墊料與飼料水活性度及pH值偵測結果 46 4-2-1 墊料水活性度與pH值 47 4-2-2 飼料水活性度與pH值 47 第三節白肉雞場空氣因子偵測結果 48 4-3-1 各場二氧化碳濃度 48 4-3-2各場次一氧化碳濃度 52 4-3-3 各場硫化氫濃度 55 4-3-4 各場氨氣濃度 57 4-3-5各場相對濕度 61 4-3-6各場溫度 63 4-3-7各場風速 66 第四節大腸桿菌毒力因子偵測結果 68 第五節抗菌劑敏感性的試驗結果 70 第六節訪談資料 71 4-6-1桃園A場與新竹B場訪談內容 71 4-6-2新竹C場訪談內容 73 4-6-3新竹D場訪談內容 75 第五章　討論 77 第一節　全部雞場各項分析結果 77 5-1-1 微生物分離結果與空氣品質監測結果綜合比較 77 5-1-2 白肉雞場生產效能 79 5-1-3 特殊場次比較 79 5-1-3-1 以育成率選取－G-6場與F-2場之比較 79 5-1-3-2 以墊料更換頻率選取－A-1場與E場之比較 80 5-1-4 Pearson積差相關分析 83 5-1-4-1 環境因子彼此間分析 83 5-1-4-2 環境因子與生產效能間分析 83 5-1-5 卡方檢定 84 5-1-5-1 以育成率分析 84 5-1-5-2 以氨氣濃度分析 85 5-1-5-3 以大腸桿菌分析 86 5-1-5-4 以水活性度分析 86 第二節大腸桿菌毒力因子偵測結果 89 第三節　抗菌劑敏感性的試驗結果 93 第六章結論與建議 95 參考文獻 110 附錄 122 附錄一 122 附錄二 123
dc.language.iso	zh-TW
dc.subject	家禽大腸桿菌	zh_TW
dc.subject	毒力因子	zh_TW
dc.subject	生產效能	zh_TW
dc.subject	環境微生物	zh_TW
dc.subject	空氣品質	zh_TW
dc.subject	抗菌劑	zh_TW
dc.subject	antibiotics	en
dc.subject	environmental microbiology	en
dc.subject	production efficiency	en
dc.subject	avian pathogenic Escherichia coli	en
dc.subject	virulence genes	en
dc.subject	air quality	en
dc.title	白肉雞生產系統環境因子監控暨家禽大腸桿菌毒力因子調查	zh_TW
dc.title	Studies on the monitoring of the environmental factors of broiler production systems and the survey for virulence characteristics of avian Escherichia coli isolates	en
dc.type	Thesis
dc.date.schoolyear	101-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	周崇熙(Chung-Hsi Chou),張紹光(Shao-Kuang Chang),沈瑞鴻(Jui-Hung Shien),郭鴻志(Hung-Chih Kuo)
dc.subject.keyword	空氣品質,環境微生物,生產效能,家禽大腸桿菌,毒力因子,抗菌劑,	zh_TW
dc.subject.keyword	air quality,environmental microbiology,production efficiency,avian pathogenic Escherichia coli,virulence genes,antibiotics,	en
dc.relation.page	160
dc.rights.note	有償授權
dc.date.accepted	2013-08-19
dc.contributor.author-college	獸醫專業學院	zh_TW
dc.contributor.author-dept	獸醫學研究所	zh_TW
顯示於系所單位：	獸醫學系

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