泌尿道致病性大腸桿菌於臺灣市售雞肉之盛行率及其於舒肥雞胸肉之熱失活預測模型

李昀蓉; YUN-JUNG LEE

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/83276

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	盧冠宏	zh_TW
dc.contributor.advisor	Kuan-Hung Lu	en
dc.contributor.author	李昀蓉	zh_TW
dc.contributor.author	YUN-JUNG LEE	en
dc.date.accessioned	2023-03-01T17:02:29Z	-
dc.date.available	2023-11-10	-
dc.date.copyright	2023-03-01	-
dc.date.issued	2022	-
dc.date.submitted	2002-01-01	-
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Extra-intestinal pathogenic Escherichia coli – threat connected with food-borne infections. Annals of Agricultural and Environmental Medicine, 26(4), 532-537. https://doi.org/10.26444/aaem/111724 Welch, R. A. (2016). Uropathogenic Escherichia coli-associated exotoxins. Microbiology Spectrum, 4(3). https://doi.org/10.1128/microbiolspec.UTI-0011-2012 Whiting, R. C., & Buchanan, R. L. (1993). A classification of models for predictive microbiology. Food Microbiol, 10(2), 175-177. https://www.scopus.com/inward/record.uri?eid=2-s2.0-0000641649&partnerID=40&md5=9b772f99a1678bac1dfaddaf4aa3e50e WHO. (2021). Antimicrobial resistance. World Health Organization Retrieved 04/22 from https://www.who.int/news-room/fact-sheets/detail/antimicrobial-resistance Wijnker, J. J., Koop, G., & Lipman, L. J. A. (2006). Antimicrobial properties of salt (NaCl) used for the preservation of natural casings. Food microbiology, 23(7), 657-662. https://doi.org/https://doi.org/10.1016/j.fm.2005.11.004 Xia, X., Meng, J., Zhao, S., Bodeis-Jones, S., Gaines, S. A., Ayers, S. L., & McDermott, P. F. (2011). Identification and antimicrobial resistance of extraintestinal pathogenic Escherichia coli from retail meats. Food Protection, 74(1), 38-44. https://doi.org/10.4315/0362-028x.Jfp-10-251 Xing, T., Zhao, X., Han, M., Cai, L., Deng, S., Zhou, G., & Xu, X. (2017). A comparative study of functional properties of normal and wooden breast broiler chicken meat with NaCl addition1 1This research was funded by China Agricultural Research System (Beijing, China, CARS-42) and National Natural Science Foundation of China (31571854). Poultry Science, 96(9), 3473-3481. https://doi.org/https://doi.org/10.3382/ps/pex116 Yamaji, R., Friedman, C. R., Rubin, J., Suh, J., Thys, E., McDermott, P., Hung-Fan, M., & Riley, L. W. (2018). A population-based surveillance study of shared genotypes of Escherichia coli isolates from retail meat and suspected cases of urinary tract infections. mSphere, 3(4). https://doi.org/10.1128/mSphere.00179-18 Yun, K. W., Kim, H. Y., Park, H. K., Kim, W., & Lim, I. S. (2014). Virulence factors of uropathogenic Escherichia coli of urinary tract infections and asymptomatic bacteriuria in children. Microbiology, Immunology and Infection, 47(6), 455-461. https://doi.org/https://doi.org/10.1016/j.jmii.2013.07.010 Zhang, X., Wan, H., Zwiers, F. W., Hegerl, G. C., & Min, S. K. (2013). Attributing intensification of precipitation extremes to human influence. Geophysical Research Letters, 40(19), 5252-5257. Zhao, L., Gao, S., Huan, H., Xu, X., Zhu, X., Yang, W., Gao, Q., & Liu, X. (2009). Comparison of virulence factors and expression of specific genes between uropathogenic Escherichia coli and avian pathogenic E. coli in a murine urinary tract infection model and a chicken challenge model. Microbiology, 155(5), 1634-1644. Zhao, S., Blickenstaff, K., Bodeis-Jones, S., Gaines, S. A., Tong, E., & McDermott, P. F. (2012). Comparison of the prevalences and antimicrobial resistances of Escherichia coli isolates from different retail meats in the United States, 2002 to 2008. Applied and Environmental Microbiology, 78(6), 1701-1707. https://doi.org/10.1128/aem.07522-11 Zhu, C., Wang, D.-Q., Zi, H., Huang, Q., Gu, J.-M., Li, L.-Y., Guo, X.-P., Li, F., Fang, C., Li, X.-D., & Zeng, X.-T. (2021, 2021/12/09). Epidemiological trends of urinary tract infections, urolithiasis and benign prostatic hyperplasia in 203 countries and territories from 1990 to 2019. Military Medical Research, 8(1), 64. https://doi.org/10.1186/s40779-021-00359-8 Zwietering, M., Jongenburger, I., Rombouts, F., & Van't Riet, K. (1990). Modeling of the bacterial growth curve. Applied and Environmental Microbiology, 56(6), 1875-1881.	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/83276	-
dc.description.abstract	泌尿道感染 (urinary tract infections, UTIs) 為多種微生物感染性疾病，其中泌尿致病性大腸桿菌 (uropathogenic Escherichia coli UPEC) 約佔 65-75%。近年來許多研究表明，家禽，尤其是雞肉，可能為人類腸道外致病性大腸桿菌 (extraintestinal pathogenic E. coli, ExPEC) 的主要宿主，而研究證據皆指向食物來源的泌尿致病性大腸桿菌會引發食源性泌尿道感染。因此，新興食源性泌尿道感染為不容忽視的食安議題。然而，據我們所知，目前關於臺灣市售肉品是否為泌尿致病性大腸桿菌宿主的文獻資料相對較少。舒肥法 (sous-vide) 是將真空包裝的食材，在穩定的低溫下長時間烹煮 (low-temperature long-time, LTLT)，使食物口感質地較佳並保留更多的營養成分。然而有研究發現沙門氏菌 (Salmonella spp.) 仍可以從舒肥烹煮過的雞肉中被分離。這表明低溫長時間烹煮過程可能無法滅活所有病原菌。鹽 (sodium chloride, NaCl) 是肉類在舒肥烹調過程中最廣泛使用的醃料之一。更重要的是研究指出由於鹽水溶液的低 pH 值和低水活性而具有抑菌作用，可延長肉類的保質期、減少細菌滋生與改善食物質地。如：研究表明2.5% NaCl溶液可抑制牛肉中O157:H7大腸桿菌的生長。這顯示舒肥食品仍存在微生物危害的食安問題，故舒肥烹調法應設置額外的措施，即鹽水醃漬，以確保即食舒肥產品的安全。因此，本研究將著重於：(1) 調查臺灣市售肉類中泌尿致病性大腸桿菌的盛行率 (2) 從消費者的角度，選擇最具食源性泌尿道感染危害風險的肉類 (雞肉)，並以我國市售雞胸肉上仍存在泌尿致病性大腸桿菌的假設為前提，透過預測微生物學去建立熱失活模型，用以預測在不同溫度 (50、55、60及63°C) 舒肥烹調過程時有無使用鹽水醃漬對雞胸肉中泌尿致病性大腸桿菌的生長和存活情況的影響。本研究從臺灣的傳統市場和超市共收集了 65 個生肉樣品 (包含雞肉、豬肉和牛肉)。從樣品中分離出的大腸桿菌使用聚合酶鏈反應 (PCR) 被進一步鑑定 UPEC的特異性基因、系統分群基因與毒力因子。接著，將泌尿致病性大腸桿菌接種至雞胸肉以獲得存活曲線。同時額外建立58°C的存活曲線作為驗證，並以均方根誤差 (RMSE)、殘差平方和 (SSE)、調整後R平方 (Adjusted R2)、赤池資訊量準則 (AIC)、準確因子 (Af)、偏差因子 (Bf) 和可接受預測區域法 (APZ) 作為統計指標。本研究結果顯示，臺灣市售肉類中存在泌尿致病性大腸桿菌，其中雞肉 (22.6%) 是受泌尿致病性大腸桿菌污染最多的肉類，其次是豬肉 (14.6%) 與牛肉 (13.5%)。從臺灣市售生肉中共分離了861 株大腸桿菌，其中156 株 (18.1%) 被鑑定為 UPEC。UPEC分離株中以系統分群 F 最佔優勢 (36.5%)，其次為 D (24.4%)和 B1 (11.5%)。在10個毒力基因中以fimH (69.2%)、traT (57.7%)、iutA (51.9%) 和ompT (46.8%) 為最常見。黏附素基因fimH主要分布在系統分群A、B1、E及F，而保護蛋白基因traT、ompT與鐵載體基因iutA則主要分布在系統分群B1、D、B2及A。在熱失活模型中，有無鹽水醃漬樣本的存活菌量皆會隨著加熱時間越久而下降。而鹽水醃漬是個有效的措施可在舒肥烹調過程時降低雞胸肉中 UPEC 菌量與其D 值。本實驗所建立的存活模式與驗證的存活曲線皆符合統計指標的標準，顯示此熱失活模型可準確進行預測。因此，本研究指出臺灣市售肉類存在泌尿致病性大腸桿菌污染的風險，並表明黏附素、鐵載體、保護蛋白等毒力因子對於UPEC能入侵泌尿系統並引起泌尿道感染扮演重要角色。而系統分群與毒力因子的分佈結果有助於了解我國泌尿致病性大腸桿菌生態並建立我國食源性泌尿道感染的流行病學資料庫，進而提出泌尿致病性大腸桿菌在即食舒肥雞胸肉之存活模式的預測公式 (the Linear model)，此模型可作為控制該類型產品的微生物危害並進行暴露評估的工具，來預防未來食源性泌尿道感染的發生。	zh_TW
dc.description.abstract	Urinary tract infection (UTI) is known as a multi-microbial infectious disease, in which uropathogenic Escherichia coli (UPEC) accounts for about 65-75% of UTIs. Recent studies indicated that poultry products, especially chicken, could be a reservoir for human extraintestinal pathogenic E. coli (ExPEC) and UPEC was suspected the pathogen resulting in emerging foodborne UTIs. As a result, it is a food safety issue problem that should not be ignored. However, to our knowledge, there is no data on whether retail meats in Taiwan can be the reservoirs of UPEC. Sous-vide defines raw ingredients packaged in a vacuum under low-temperature long-time (LTLT) cooking, making food be better sensory quality and preserving more nutrients. Nevertheless, previous research found that Salmonella could still be isolated from sous-vide cooked chicken, suggesting that the LTLT process might not inactivate all kinds of pathogens. Salt (sodium chloride, NaCl) marinade is one of the most widely used poultry marinades during sous-vide cooking. More importantly, the studies have shown the efficacy of salt marinade in reduction pathogens among meat that can prolong the shelf life of meat, reducing bacterial growth as well as improving its texture. For example, Mukherjee et al. reported that a 2.5% NaCl solution can inhibit the growth of E. coli O157:H7 in ground beef. This means that safety concerns about the presence of microbial hazards in sous-vide food products still exist; hence, sous-vide treatment should apply extra hurdles as salt marinade for the assurance of these products’ safety. Therefore, the objectives of this study were proposed as follows: (1) investigate the prevalence of UPEC isolated from retail meats in Taiwan; (2) form the consumer’s perspective, choosing the meat (chicken) with the highest risk of foodborne UTI, assuming that UPEC remains on the retail chicken breast in Taiwan, and applying predictive microbiology to establish inactivation modeling of UPEC in chicken breast samples with or without salt marinade via sous-vide processing at different temperatures to evaluate the behavior of UPEC. A total of 65 raw meat samples (chicken, pork, and beef) were collected from traditional markets and supermarkets in Taiwan. The E. coli strains isolated from meat samples were further identified the expression of UPEC-specific, phylogenetic, and virulence genes by polymerase chain reaction (PCR). Then, the chicken breast meat was inoculated with a four-strain UPEC cocktail to obtain the survival curves via sous-vide processing at 50, 55, 60 and 63°C. Meanwhile, survival curves at 58°C were constructed for external validation and RMSE, SSE, adjusted R2, AIC, Af, Bf, and the APZ method (pRE) were used as the statistical indices. The results in the study showed that the presence of UPEC among various retail meat in Taiwan, which chicken (22.6%) was with the highest number of the meat contaminated with UPEC, followed by pork (14.6%) and beef (13.5%). All the 861 E. coli isolates from retail raw meat in Taiwan, 156 (18.1%) strains were identified as UPEC. In UPEC isolates, phylogenetic group F was predominant (36.5%), followed by D (24.4%), and B1 (11.5%). Among 10 virulence genes, fimH (69.2%), traT (57.7%), iutA (51.9%), and ompT (46.8%) genes were the most frequently observed. Adhesin gene of fimH was mainly detected in strains of phylogroups A, B1, E, and F, whereas protection protein genes of traT and ompT and siderophore gene of iutA were commonly found in groups B1, D, B2, and A. For inactivation models, the numbers of survival bacterial cells exhibit a decline with time in all treatments. Salt marination is an effective hurdle resulting in lower survival UPEC populations and D-values in the chicken breast during sous-vide cooking. All the models for all treatments fitted well with UPEC survival curves; while the Linear model fitted much better. In conclusion, retail meat in Taiwan has the risk of UPEC contamination. Our findings demonstrate the distribution of phylogenetic groups and virulence factors in UPEC isolates from retail raw meat in Taiwan. It also indicates an important role of adhesins, protection protein, and iron acquisition systems that allowed UPEC to enhance their capacity to colonize the genitourinary system and cause UTIs. The developed survival functions based on the Linear model of UPEC in sous-vide ready-to-eat (RTE) chicken breast can be a tool for controlling the microbial hazards and for exposure assessment to prevent future foodborne UTIs.	en
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dc.description.tableofcontents	論文口試委員審定書.........................................I 誌謝......................................................II 中文摘要..................................................III ABSTRACT..................................................V CONTENT...................................................IX LIST OF FIGURES...........................................XIII LIST OF TABLES............................................XV CHAPTER 1 INTRODUCTION....................................1 CHAPTER 2 BACKGROUND AND LITERATURE REVIEW................7 2.1 Urinary tract infection (UTI).........................7 2.1.1 Clinical features...................................7 2.1.2 Uropathogenic bacteria..............................8 2.1.3 Pathogenesis and pathway............................9 2.1.4 Foodborne urinary tract infection (Foodborne UTI)...11 2.2 Uropathogenic Escherichia coli (UPEC).................15 2.2.1 Classifying Escherichia coli (E. coli)..............15 2.2.2 UPEC................................................17 2.2.3 Phylogenetic group..................................18 2.2.4 Virulence factors...................................19 2.3 Factors affecting bacterial growth....................23 2.3.1 Intrinsic factors...................................23 2.3.2 Extrinsic factors...................................24 2.3.3 Other factors.......................................25 2.4 Sous-vide.............................................25 2.4.1 History of sous-vide................................26 2.4.2 Principle and benefits of sous-vide.................27 2.4.3 Microbiological hazards in sous-vide food products..28 2.4.4 High risk for microbial contamination of sous-vide RTE poultry products...30 2.4.5 Extra hurdle technology of sous-vide................31 2.5 Salt marinade for sous-vide cooking...................32 2.5.1 Principle and benefits of salt marinade.............32 2.5.2 Control strategies based on antimicrobial effect of brine solution........33 2.6 Predictive microbiology...............................34 2.6.1 Primary model.......................................35 2.6.2 Secondary model.....................................36 2.6.3 Tertiary model......................................36 2.6.4 Validation..........................................37 2.7 Study aims............................................40 CHAPTER 3 MATERIALS AND METHODS...........................42 3.1 The study design......................................42 3.2 UPEC identification...................................43 3.2.1 Sampling............................................43 3.2.2 Microbiological analyses............................43 3.2.3 Physical analyses...................................44 3.2.4 Isolation and DNA extraction........................44 3.2.5 Clinical reference strains and culturing............45 3.2.6 UPEC identification.................................46 3.2.7 Phylogenetic genes and virulence genes..............46 3.2.8 Polymerase chain reaction condition.................47 3.3 Inactivation models of sous-vide cooking..............48 3.3.1 A cocktail of UPEC..................................48 3.3.2 Salt marinade.......................................49 3.3.3 Preparation and inoculation of chicken breast meat..49 3.3.4 Sous-vide cooking...................................50 3.3.5 Bacterial enumeration...............................51 3.3.6 Parameters and survival modeling....................51 3.3.7 Model evaluation and validation.....................53 3.3.8 Statistical methods.................................55 CHAPTER 4 RESULTS AND DISCUSSION..........................57 4.1 Physical analyses.....................................57 4.2 Microbiological analyses..............................57 4.2.1 Prevalence of E. coli from retail meat..............57 4.2.2 Contamination scenario of E. coli and total bacterial in meat.....58 4.3 E. coli isolates from samples.........................60 4.3.1 Final E. coli recovery..............................60 4.3.2 Identification as UPEC from E. coli isolates........61 4.3.3 Phylogenetic distribution among UPEC isolates.......62 4.3.4 Virulence genotyping of UPEC isolates...............64 4.3.5 Relation among phylogenetic group and virulence genes.....66 4.3.6 Phylogenetic group and virulence genes of UPEC reference strains....67 4.4 Construct the predictive inactivation models..........67 4.4.1 Survival curves of UPEC under sous-vide cooking.....67 4.4.2 Primary models of UPEC under sous-vide cooking......70 4.4.3 Impact of salt marinade on UPEC inactivation........73 4.4.4 Secondary models of UPEC under sous-vide cooking....75 4.4.5 Model validation....................................76 CHAPTER 5 RESEARCH LIMITATIONS AND RECOMMENDATIONS........78 CHAPTER 6 CONCLUSION......................................80 REFERENCES................................................83 FIGURES...................................................106 TABLES....................................................125 APPENDIXES................................................162 Figure 1. Meat consumption worldwide from 1990 to 2021....106 Figure 2. Poultry meat consumption........................106 Figure 3. Meat consumption per capita.....................107 Figure 4. Epidemiology of UTIs............................107 Figure 5. The urinary tract and sits of infection.........108 Figure 6. UTI pathogenesis................................108 Figure 7. The association between food and UTIs...........109 Figure 8. Virulence factors of surface structural in UPEC.109 Figure 9. Classification of E. coli into three main groups.110 Figure 10. The phylogenetic tree identification method by (Clermont et al., 2000) ....111 Figure 11. The phylogenetic tree identification method by (Clermont et al., 2003) ....112 Figure 12. The pH growth ranges for foodborne pathogens...113 Figure 13. Sous-vide cooking temperature safety zones.....113 Figure 14. The association between food and UTIs..........114 Figure 15. The framework of this study....................115 Figure 16. Sampling location..............................116 Figure 17. Prevalence of E. coli recovered from retail meat in Taiwan....117 Figure 18. The schematic diagram of UPEC determination described in the study. 118 Figure 19. Prevalence of UPEC from E. coli isolates among retail meat in traditional markets and supermarkets...................................119 Figure 20. Survivor curves of UPEC in (A) untreated, (B) NaCl-treated chicken breast under sous-vide cooking....................................120 Figure 21. The experimental populations of UPEC with a comparison between untreated and treated chicken breast under sous-vide cooking.........121 Figure 22. Effect of temperature on the D-values in untreated chicken breast....122 Figure 23. Effect of temperature on the D-values in NaCl-treated chicken breast.122 Figure 24. The observed data and predicted survivor curve of UPEC in chicken breast under sous-vide cooking at 58°C............................123 Figure 25. The observed data and predicted survivor curve of UPEC in NaCl-treated chicken breast under sous-vide cooking at 58°C.............123 Figure 26. Relative error plots with APZ method in chicken breast under sous-vide cooking at 58°C............................................124 Figure 27. Relative error plots with APZ method in NaCl-treated chicken breast under sous-vide cooking at 58°C..................................124 Table 1. The number of raw meat samples....................125 Table 2. pH value of samples...............................126 Table 3. Aw value of samples...............................127 Table 4. Prevalence of E. coli recovered from retail meat in traditional markets and supermarkets...............................................128 Table 5. E. coli count and total plate count averages of various meat.....129 Table 6. E. coli count and total plate count averages of various meat from traditional markets and supermarkets.......................130 Table 7. The primer sequences and sizes of UPEC determination.....131 Table 8. The primer sequences and sizes of the phylogenetic group.....132 Table 9. The primer sequences and sizes of the virulence factors.....133 Table 10. PCR conditions for each gene.....134 Table 11. Strains used as the cocktail in the study.........135 Table 12. Phylogenetic type of reference strains and the strains used in the cocktail....................................................136 Table 13. Virulence factors of reference strains and the strains used in the cocktail....................................................137 Table 14. Prevalence of UPEC from E. coli isolates among retail meat in traditional markets and supermarkets....................................138 Table 15. Prevalence of UPEC-specific genes combinations used for the identification of UPEC from E. coli isolates...............................139 Table 16. Phylogenetic group distribution among UPEC strains from retail meat in traditional markets and supermarkets by (Clermont et al., 2000)....140 Table 17. Phylogenetic group distribution among UPEC strains from retail meat in traditional markets and supermarkets by (Clermont et al., 2013)....141 Table 18. Virulence factors of UPEC strains from retail meat in Taiwan.....142 Table 19. Virulence factors of UPEC strains from retail meat in traditional markets and supermarkets............................................143 Table 20. Relation among phylogenetic group and virulence factors of UPEC strains from traditional markets....................................144 Table 21. Relation among phylogenetic group and virulence factors of UPEC strains from supermarkets...........................................145 Table 22. Evaluation microbiological analyses of raw chicken breast samples after exposing under UV light.....................................146 Table 23. The equation of the TDT curve in untreated and NaCl-treated chicken breast under sous-vide cooking.....................................147 Table 24. The observed counts and predicted counts from Weibull and Linear models of UPEC in chicken breast under sous-vide cooking at 50°C......148 Table 25. The observed counts and predicted counts from Weibull and Linear models of UPEC in NaCl-treated chicken breast under sous-vide cooking at 50°C.....149 Table 26. The observed counts and predicted counts from Weibull and Linear models of UPEC in chicken breast under sous-vide cooking at 55°C.......150 Table 27. The observed counts and predicted counts from Weibull and Linear models of UPEC in NaCl-treated chicken breast under sous-vide cooking at 55°C.....151 Table 28. The observed counts and predicted counts from Weibull and Linear models of UPEC in chicken breast under sous-vide cooking at 60°C.......152 Table 29. The observed counts and predicted counts from Weibull and Linear models of UPEC in NaCl-treated chicken breast under sous-vide cooking at 60°C.....153 Table 30. The observed counts and predicted counts from Weibull and Linear models of UPEC in chicken breast under sous-vide cooking at 63°C.......154 Table 31. The observed counts and predicted counts from Weibull and Linear models of UPEC NaCl-treated chicken breast under sous-vide cooking at 63°C........155 Table 32. The thermal inactivation parameters and statistical indices of UPEC growth in untreated and NaCl-treated chicken breast under sous-vide cooking evaluated with different primary models at 50, 55, 60 and 63°C..............156 Table 33. Thermal inactivation kinetics of the 4-strains of UPEC analyzed by Linear model at 50, 55, 60 and 63°C.................................158 Table 34. Aw and pH value of chicken breast samples..........159 Table 35. NaCl content of chicken breast samples.............160 Table 36. The validation for the performance of developed models of UPEC in untreated and NaCl-treated chicken breast under sous-vide cooking at 58°C.......161	-
dc.language.iso	en	-
dc.title	泌尿道致病性大腸桿菌於臺灣市售雞肉之盛行率及其於舒肥雞胸肉之熱失活預測模型	zh_TW
dc.title	Prevalence of uropathogenic Escherichia coli in retail chicken meat and predictive models for the thermal inactivation in sous-vide processed chicken breast	en
dc.title.alternative	Prevalence of uropathogenic Escherichia coli in retail chicken meat and predictive models for the thermal inactivation in sous-vide processed chicken breast	-
dc.type	Thesis	-
dc.date.schoolyear	111-1	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	張靜文;楊登傑;陳鑫昌	zh_TW
dc.contributor.oralexamcommittee	Ching-Wen Chang;Deng-Jye Yang;Hsin-Chang Chen	en
dc.subject.keyword	泌尿道致病性大腸桿菌,舒肥法,即食食品,低溫長時間烹煮法,熱失活,預測微生物學,雞胸肉,	zh_TW
dc.subject.keyword	uropathogenic Escherichia coli,sous-vide,ready-to-eat,low-temperature long-time,thermal inactivation,predictive microbiology,chicken breast,	en
dc.relation.page	181	-
dc.identifier.doi	10.6342/NTU202201820	-
dc.rights.note	未授權	-
dc.date.accepted	2022-07-29	-
dc.contributor.author-college	公共衛生學院	-
dc.contributor.author-dept	食品安全與健康研究所	-
顯示於系所單位：	食品安全與健康研究所

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ntu-111-1.pdf 目前未授權公開取用	5.08 MB	Adobe PDF

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