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在铝制热死时间管中对悬浮于番茄汁中的肉毒梭菌孢子进行热破坏。

Thermal destruction of Clostridium botulinum spores suspended in tomato juice in aluminum thermal death time tubes.

作者信息

Odlaug T E, Pflug I J

出版信息

Appl Environ Microbiol. 1977 Jul;34(1):23-9. doi: 10.1128/aem.34.1.23-29.1977.

DOI:10.1128/aem.34.1.23-29.1977
PMID:329760
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC242582/
Abstract

The heat destruction characteristics of Clostridium botulinum spores suspended in tomato juice and phosphate buffer were determined by the survivor curve method with aluminum thermal death time tubes. Two type A strains of C. botulinum and a type B strain were evaluated. Strains A16037 and B15580 were implicated in outbreaks of botulism involving home-canned tomato products. Strain A16037 had a higher heat resistance than either 62A or B15580. The mean thermal resistance (D-values) for A16037 in tomato juice (pH 4.2) were: 115.6 degrees C, 0.4 min; 110.0 degrees C, 1.6 min; and 104.4 degrees C, 6.0 min. The mean D-values for A16037 in Sorensen 0.067 M phosphate buffer (pH 7) were: 115.6 degrees C, 1.3 min; 110.0 degrees C, 4.4 min; and 104.4 degrees C, 17.6 min. At each test temperature, the D-values were approximately three times higher in buffer than in tomato juice. The z-value for C. botulinum A16037 spores in tomato juice was 9.4 degrees C, and in buffer the z-value was 9.9 degrees C. The use of aluminum thermal death time tubes in a miniature retort system makes it possible to determine survivor curves for C. botulinum spores at 121.1 degrees C. This is possible because the lag correction factor for the aluminum tubes is only about 0.2 min, making possible heating times as short as 0.5 min.

摘要

采用铝热致死时间管,通过存活曲线法测定了悬浮于番茄汁和磷酸盐缓冲液中的肉毒梭菌孢子的热破坏特性。评估了两株A型肉毒梭菌菌株和一株B型菌株。A16037菌株和B15580菌株与涉及家庭自制罐装番茄制品的肉毒中毒暴发事件有关。A16037菌株的耐热性高于62A菌株或B15580菌株。A16037菌株在番茄汁(pH 4.2)中的平均耐热性(D值)为:115.6℃,0.4分钟;110.0℃,1.6分钟;104.4℃,6.0分钟。A16037菌株在索伦森0.067M磷酸盐缓冲液(pH 7)中的平均D值为:115.6℃,1.3分钟;110.0℃,4.4分钟;104.4℃,17.6分钟。在每个测试温度下,缓冲液中的D值约为番茄汁中的三倍。肉毒梭菌A16037孢子在番茄汁中的z值为9.4℃,在缓冲液中的z值为9.9℃。在微型杀菌釜系统中使用铝热致死时间管,可以测定肉毒梭菌孢子在121.1℃时的存活曲线。这是可行的,因为铝管的滞后校正因子仅约为0.2分钟,使得加热时间可短至0.5分钟。

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