柵欄技術應用於桃園大溪地區豆腐乾衛生品質之改善

Hsiao-Ju Pu; 蒲孝如

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/33879

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	游若?博士
dc.contributor.author	Hsiao-Ju Pu	en
dc.contributor.author	蒲孝如	zh_TW
dc.date.accessioned	2021-06-13T05:48:03Z	-
dc.date.available	2006-07-28
dc.date.copyright	2006-07-28
dc.date.issued	2006
dc.date.submitted	2006-07-09
dc.identifier.citation	台北市政府衛生局。2003。台北市政府衛生局九十二年年節食品抽驗結果第二批不合格名冊。http://www.healthcity.net.tw/upload/122.htm。台北市政府衛生局。2004。九十三年豆製品抽驗結果名冊。http://210.69.108.165/Hhotlist.asp?DiscussID=101。台北市政府衛生局。2005a。台北市政府衛生局九十四年年節食品抽驗結果第一波不合格名冊。http://food.doh.gov.tw/show.asp?2005117112340385。台北市政府衛生局。2005b。台北市政府衛生局九十四年年節食品抽驗結果第二波不合格名冊。http://food.doh.gov.tw/show.asp?2005117112340385。台灣食品良好作業規範發展協會。2005。黃豆加工食品工廠良好作業規範專則。http://www.gmp.org.tw/lawsexecution/13.doc。行政院衛生署。2005a。一般食品類衛生標準。http://food.doh.gov.tw/chinese/ruler/hygiene_standed_3.htm#2。行政院衛生署。2005b。食品良好衛生規範。http://food.doh.gov.tw/chinese/ruler/ruler_1_1.asp?chieng=1&lawsidx=395。行政院衛生署。2005c。食品添加物使用範圍及其限量。http://food.doh.gov.tw/chinese/ruler/ingrdient_standard.htm。行政院衛生署。2005d。食品衛生管理法。http://food.doh.gov.tw/chinese/ruler/ruler_1_1.asp?chieng=1&lawsidx=393。李貽琳。1987。豆乾食品中微生物生長和安全之研究。博士學位論文。國立台灣大學食品科技研究所。台北。李晉嘉。2003。以反應曲面法研究生化柴油之最優酵素合成。碩士學位論文。私立大葉大學食品工程學研究所。彰化。周正俊。1985。豆腐、豆乾中微生物品質之探討。行政院衛生署七十五年度科技研究發展計畫。行政院衛生署。台北。沈明來。2000。試驗設計學。九州圖書文物有限公司，台北。洪連發。1997。以回應曲面法探討微胞強化超過濾技術純化酪蛋白磷胜肽之最佳條件。碩士學位論文。國立台灣大學化學工程學研究所。台北。黃韋誠。2003。以反應曲面法探討鱈魚漿製品最適化之研究。碩士學位論文。國立屏東科技大學食品科學研究所。屏東。傅遠鵬。1988。食品分析方法手冊。食品工業發展研究所，新竹。翁瑋蓮。1999。以反應曲面法探討扣碗酪之最佳生產模式。碩士學位論文。國立臺灣大學畜產學研究所。台北。經濟部中央標準局。2001。中國國家標準CNS食品中防腐劑之檢驗法總號 10949 類號N6190。經濟部中央標準局。台北。劉益忠。2002。酒釀萃微膠囊化。博士學位論文。國立台灣大學畜產學研究所。台北。賴茲漢、柯文慶、沈賜川。1994。乳酸發酵豆乾之製造與品質改進。食品科學。21 (4)：256-166。 AOAC. 1984. 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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/33879	-
dc.description.abstract	本研究進行桃園大溪地區豆腐乾製程與產品之衛生概況結果為生豆、豆乳至豆腐乾，半成品至成品的過程中，水分含量70 %至90 %不等，pH值介於6至7左右，為一般微生物適合生長的環境。該地區豆腐乾防腐劑添加過量的情況已豆腐乾類產品最為嚴重，11件豆腐乾樣品中有6件苯甲酸使用過量的情形。桃園縣大溪地區市售四種豆腐乾產品於25℃儲存12小時後，除了過氧化氫殘留量超過0.1 %之產品菌數沒有明顯增加外，菌數均達107 CFU/g~108 CFU/g，且表面有粘性物質產生及不良氣味，於5℃之儲存下市售產品儲存期間菌數之下降不明顯。實驗自四種豆腐乾產品中所分離出之腐敗微生物為Acinetobacter lwoffii，此菌為不具發酵特性之格蘭氏陰性桿菌。本實驗目的為應用符合GRAS之物質於豆腐乾製程以改目前善大溪地區豆腐乾之儲存情況與衛生品質。依據反應曲面法之結果找出培養溫度25℃下，苯甲酸濃度400~500 ppm、磷酸濃度300~400 ppm時，Serratia liquefaciens有較低之平均生長速度0.002至0.004 (OD600/hr)。中藥水溶液對豆腐乾腐敗菌之抑制實驗結果丁香與肉桂對A. lwoffii最小抑制濃度為3 % (w/v)，丁香對P. fluorescens最小抑制濃度為16 %，大茴香對S. liquefaciens最小抑制濃度為6 %。豆腐乾經由以下列滷汁配方：苯甲酸420 ppm、檸檬酸鈉300 ppm或磷酸300 ppm、10 %中藥(肉桂:大茴香:丁香=3 :4 :3)以100℃滷煮15分鐘處理後，豆腐乾pH値從6.4降至5.5或5.2，並且於25℃儲存二天，表面未有粘性物質產生且無不良氣味，相較於大溪地區市售豆腐乾之儲存情況儲存期限從12小時延長至48小時，4℃下豆腐乾之總生菌數隨著儲存時間之延長而下降，顯示本實驗配方可延緩豆腐乾在儲存期間之腐敗速度。	zh_TW
dc.description.abstract	The dried soybean curds from Taoyuan County contains about, 70-90 % water, and water activity is about 0.8.The pH is around 6.0 - 7.0 which provides a good growth condition for spoilage organisms. Generally, after 12 hours of storage under room temperature, dried soybean curd will spoil and form slime on the surface. The spoilage organism isolated from dried soybean curd of Taoyuan County in this study was found to be Acinetobacter sp. Objective of this study is to improve the microbial quality of dried soybean curd in Taoyuan- Daxi area by combine several GRAS materials. According to the results of RSM, we decide the use of benzoic acid (420 ppm) and phosphoric acid (300 ppm) in treating dried soybean curd when the temperature of environment is 25℃ and the pH of soybean curd is 5 to minimize the growth of Serratia liquefaciens. The growth of indicator organisms, Serratia liquefaciens, can be inhibited by anise, cinnamon and clove and the minimum inhibitory concentration for anise, cinnamon, and clove are 6 %, 12% and 20 %, respectively. Pseudomonas fluorescens can be inhibited by clove, with a minimum inhibitory concentration of 16 %. While Acinetobacter lwoffii can be inhibited by cinnamon and clove, both with a minimum inhibitory concentration of 3 %. The combinations of benzoic acid 420 ppm, phosphoric acid or citric acid 300 ppm, cinnamon 3 %, anise 4 %, and clove 3 % in the bittern could extend the shelf life of dried soybean curd from 12 hours to 48 hours under 25℃. The total count of dried soybean curd decrease with the storage time under 5℃.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T05:48:03Z (GMT). No. of bitstreams: 1 ntu-95-R93641028-1.pdf: 2015693 bytes, checksum: a8abad755b302594923779760dbb64f5 (MD5) Previous issue date: 2006	en
dc.description.tableofcontents	壹、前言................................................1 貳、文獻整理............................................2 一、豆製品之簡介........................................2 (一) 豆乾、豆腐.......................................2 (二) 市售豆乾食品之主要衛生安全問題.....................2 (三) 易腐敗食品之定義...................................2 (四) 衛生署食品衛生之相關規定...........................3 (五) 造成豆製品污染常見之細菌...........................3 1. Lactic acid bacteria.................................3 2. Pseudomonas..........................................3 3. Enteric bacteria.....................................4 4. Streptococci.........................................4 5. 其他.................................................4 二、常使用於食品中之防腐物質............................4 (一) 弱酸...............................................4 (二) 過氧化氫...........................................5 (三) 天然防腐物質.......................................6 (四) 豆乾常用之防腐劑...................................8 三、柵欄技術............................................9 (一) 柵欄技術之簡介 ....................................9 (二) 從微生物生理學來看柵欄技術之優點..................13 1. 柵欄技術與微生物的內平衡............................13 2. 柵欄技術與微生物的能量耗盡..........................13 3. 柵欄技術與微生物的緊迫反應..........................14 (三) 食品中的防腐柵欄因子..............................14 1. 物理性柵欄..........................................15 2. 物理化學柵欄........................................15 3. 微生物柵欄..........................................15 4. 其他柵欄............................................15 (四) 柵欄技術與食品的品質..............................15 四、反應曲面法.........................................18 (一) 反應曲面法簡介....................................18 (二) 反應曲面法之原理基本概念..........................19 (三) 反應曲面法之數學模式介紹..........................20 (四) 最佳化配方搜尋過程................................23 (五) 反應曲面法實驗設計步驟............................24 1.確定因數.............................................24 2.選擇適當層階.........................................24 3.確定決定品質之測量方法後進行實驗之設計...............24 (六) 常用之反應曲面法實驗設計..........................24 1.二階層因數設計.......................................24 2.中心混層設計.........................................25 (七) 反應曲面模式適切性之統計檢驗......................27 (八) 反應曲面法的優點..................................27 參、實驗架構與研究目的.................................30 肆、材料與方法.........................................33 一、試驗材料...........................................33 (一) 原料..............................................33 (二) 試驗菌株..........................................33 (三) 培養基............................................33 (四)藥品...............................................34 (五) 儀器設備與消耗器材................................34 二、試驗方法...........................................36 (一)豆乾廠房空中落菌檢測............................36 (二)豆乾製程中各項半成品性狀調查.......................36 (三)市售豆乾防腐劑添加量檢測...........................36 (四)市售豆乾過氧化氫殘留量檢測.........................38 (五)豆乾微生物菌相測定.................................38 (六)市售豆乾酸鹼度、水活性及水分含量分析...............39 (七)市售豆乾腐敗指標微生物分離與鑑定...................39 (八)儲存試驗...........................................39 (九)統計分析...........................................40 (十)菌株之保存與活化...................................40 (十一)微生物生長測定...................................40 (十二)微生物平均生長速度測定...........................40 (十三)反應曲面法之試驗設計.............................41 (十四)反應曲面法最適配方搜尋...........................42 (十五)中藥水溶液製備...................................42 (十六)中藥水溶液抑制實驗...............................42 (十七)滷汁製備.........................................43 (十八)儲存試驗.........................................43 (十九)反應曲面法之統計分析.............................43 伍、結果與討論.........................................45 一、大溪地區豆乾生產現況調查...........................45 (一)豆乾製程與廠房環境衛生狀況.........................45 (二)市售豆乾防腐劑添加量與過氧化氫殘留量檢測...........47 (三)市售豆乾儲存試驗...................................47 (四) 市售豆乾腐敗指標微生物分離與鑑定..................48 二、以反應曲面法配合中藥水溶液抑制實驗探討豆乾滷汁中柵欄因子抑制指標微生物之最佳配方.............................49 (一)選擇指標微生物.....................................49 (二)反應曲面數學模式之建立.............................49 (三)培養液酸鹼度對Serratia liquefaciens平均生長速度之影響.....................................................52 (四)培養液中苯甲酸及磷酸濃度對Serratia liquefaciens平均生長速度之影響.............................................52 (五)抑制豆乾腐敗微生物Serratia liquefaciens生長之最適條件探討....................................................53 (六)中藥水溶液對豆乾腐敗菌之抑制作用...................53 (七)中藥水溶液對豆乾腐敗菌之最小抑制濃度...............54 (八)儲存試驗...........................................55 1.滷汁與豆乾酸鹼度於滷煮前後之變化............55 2.豆乾於室溫下儲存期間之生菌數變化............55 3.豆乾於冷藏儲存期間之生菌數變化..............56 陸、結論...............................................80 柒、參考文獻...........................................82
dc.language.iso	zh-TW
dc.subject	豆乾	zh_TW
dc.subject	柵欄技術	zh_TW
dc.subject	衛生	zh_TW
dc.subject	microbial quality	en
dc.subject	dried soybean curd	en
dc.subject	hurdle technology	en
dc.title	柵欄技術應用於桃園大溪地區豆腐乾衛生品質之改善	zh_TW
dc.title	Improvement of Microbial Quality of Dried Soybean Curd of Taoyuan - Daxi Area by Hurdle Technology	en
dc.type	Thesis
dc.date.schoolyear	94-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	蔡國珍博士,潘崇良博士,丘志威博士,周正俊博士
dc.subject.keyword	豆乾,衛生,柵欄技術,	zh_TW
dc.subject.keyword	dried soybean curd,microbial quality,hurdle technology,	en
dc.relation.page	88
dc.rights.note	有償授權
dc.date.accepted	2006-07-11
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	食品科技研究所	zh_TW
顯示於系所單位：	食品科技研究所

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