ImageVerifierCode 换一换
格式:PDF , 页数:5 ,大小:405.31KB ,
资源ID:455891      下载积分:10000 积分
快捷下载
登录下载
邮箱/手机:
温馨提示:
如需开发票,请勿充值!快捷下载时,用户名和密码都是您填写的邮箱或者手机号,方便查询和重复下载(系统自动生成)。
如填写123,账号就是123,密码也是123。
特别说明:
请自助下载,系统不会自动发送文件的哦; 如果您已付费,想二次下载,请登录后访问:我的下载记录
支付方式: 支付宝扫码支付 微信扫码支付   
注意:如需开发票,请勿充值!
验证码:   换一换

加入VIP,免费下载
 

温馨提示:由于个人手机设置不同,如果发现不能下载,请复制以下地址【http://www.mydoc123.com/d-455891.html】到电脑端继续下载(重复下载不扣费)。

已注册用户请登录:
账号:
密码:
验证码:   换一换
  忘记密码?
三方登录: 微信登录  

下载须知

1: 本站所有资源如无特殊说明,都需要本地电脑安装OFFICE2007和PDF阅读器。
2: 试题试卷类文档,如果标题没有明确说明有答案则都视为没有答案,请知晓。
3: 文件的所有权益归上传用户所有。
4. 未经权益所有人同意不得将文件中的内容挪作商业或盈利用途。
5. 本站仅提供交流平台,并不能对任何下载内容负责。
6. 下载文件中如有侵权或不适当内容,请与我们联系,我们立即纠正。
7. 本站不保证下载资源的准确性、安全性和完整性, 同时也不承担用户因使用这些下载资源对自己和他人造成任何形式的伤害或损失。

版权提示 | 免责声明

本文(ASHRAE REFRIGERATION IP CH 22-2010 FOOD MICROBIOLOGY AND REFRIGERATION《食物微生物学和制冷》.pdf)为本站会员(bonesoil321)主动上传,麦多课文库仅提供信息存储空间,仅对用户上传内容的表现方式做保护处理,对上载内容本身不做任何修改或编辑。 若此文所含内容侵犯了您的版权或隐私,请立即通知麦多课文库(发送邮件至master@mydoc123.com或直接QQ联系客服),我们立即给予删除!

ASHRAE REFRIGERATION IP CH 22-2010 FOOD MICROBIOLOGY AND REFRIGERATION《食物微生物学和制冷》.pdf

1、22.1CHAPTER 22FOOD MICROBIOLOGY AND REFRIGERATIONBasic Microbiology . 22.1Critical Microbial Growth Requirements . 22.1Design for Control of Microorganisms. 22.3The Role of HACCP 22.4Sanitation 22.4Regulations and Standards . 22.5EFRIGERATIONS largest overall application is the preven-R tion or reta

2、rdation of microbial, physiological, and chemicalchanges in foods. Even at temperatures near the freezing point,foods may deteriorate through growth of microorganisms, changescaused by enzymes, or chemical reactions. Holding foods at lowtemperatures merely reduces the rate at which these changes tak

3、eplace. A few spoilage organisms can grow at or below temperaturesat which food begins to freeze.Refrigeration also plays a major role in maintaining a safe foodsupply. Overall, the leading factor causing foodborne illness isimproper food-holding temperatures. Another important factor isimproperly s

4、anitized equipment. Engineering directly affects thesafety and stability of the food supply in design of cleanable equip-ment and facilities, as well as maintenance of environmental condi-tions that inhibit microbial growth. This chapter briefly discussesthe microbiology of foods and the effect of d

5、esign decisions on theproduction of safe and wholesome foods. Methods of applyingrefrigeration to specific foods are discussed in Chapters 30 to 42.BASIC MICROBIOLOGYMicroorganisms play several roles in a food production facility.They can contribute to food spoilage, producing off-odors and fla-vors

6、, or altering product texture or appearance through slime pro-duction and pigment formation. Some organisms cause disease;others are beneficial and are required to produce foods such ascheese, wine, and sauerkraut through fermentation.Microorganisms fall into four categories: bacteria, yeasts, molds

7、,and viruses. Bacteria are the most common foodborne pathogens.Bacterial growth rates, under optimum conditions, are generallyfaster than those of yeasts and molds, making bacteria a prime causeof spoilage, especially in refrigerated, moist foods. Bacteria havemany shapes, including spheres (cocci),

8、 rods (bacilli), or spirals (spi-rochetes), and are usually between 0.3 and 5 to 10 m in size. Bacteriacan grow in a wide range of environments. Some, notably Clostrid-ium and Bacillus spp., form endospores (i.e., resting states withextensive temperature, desiccation, and chemical resistance).Yeasts

9、 and molds become important in situations that restrict thegrowth of bacteria, such as in acidic or dry products. Yeasts cancause gas formation in juices and slime formation on fermentedproducts. Mildew (black mold) on humid surfaces and mold forma-tion on spoiled foods are also common. Some molds p

10、roduce verypowerful toxins (mycotoxins) that, if consumed, may be fatal.Viruses are obligate intracellular parasites that are specific to anindividual host. All viruses, including human viruses (e.g., hepatitisA), cannot multiply outside living cells or tissue. Refrigerationdesign features must incl

11、ude facilities for good employee handwash-ing and sanitation practices to minimize potential for product con-tamination. Bacterial viruses (phages), however, may contribute tostarter culture failure in bacterial fermentations if proper isolation,ventilation, and sanitation procedures are not followe

12、d. The use ofcommercial concentrated cultures, selected for phage resistance, hasgreatly reduced this problem.Sources of MicroorganismsBacteria, yeasts, and molds are widely distributed in water, soil,air, plant materials, and the skin and intestinal tracts of humans andanimals. Practically all unpr

13、ocessed foods are contaminated with avariety of spoilage and, sometimes, pathogenic microorganismsbecause foods act as excellent media for bacterial multiplication.Food processing environments that contain residual food materialwill naturally select for the microorganisms that are most likely tospoi

14、l the particular product.Microbial GrowthChanges in microbial populations follow a generalized growthcurve (Figure 1). An initial lag phase occurs as organisms adapt tonew environmental conditions and start to grow. The lag phase isvery important because the maximum extension of shelf life andlength

15、 of production runs are directly related to the length of the lagphase. After adaptation, the culture enters into the maximum (loga-rithmic) growth rate, and control of microbial growth is not possiblewithout major sanitation or other drastic measures. Numbers candouble as fast as every 20 to 30 min

16、 under optimum conditions.Toxin production and spore maturation, if possible, usually occurat the end of the exponential phase as the culture enters a stationaryphase. At this time, essential nutrients are depleted and/or inhibitoryby-products are accumulated. Eventually, culture viability declines;

17、the rate depends on the organism, medium, and other environmentalcharacteristics. Although refrigeration prolongs generation timeand reduces enzyme activity and toxin production, in most cases, itwill not restore lost product quality or safety.CRITICAL MICROBIAL GROWTH REQUIREMENTSFactors that influ

18、ence microbial growth can be divided into twocategories: (1) intrinsic factors that are a function of the food itselfThe preparation of this chapter is assigned to TC 10.9, Refrigeration Appli-cation for Foods and Beverages.Fig. 1 Typical Microbial Growth CurveFig. 1 Typical Microbial Growth Curve22

19、.2 2010 ASHRAE HandbookRefrigerationand (2) extrinsic factors that are a function of the environment inwhich a food is held.Intrinsic FactorsIntrinsic factors affecting microbial growth include nutrients,inhibitors, biological characteristics, water activity, pH, and pres-ence of competing microorga

20、nisms in a food. Although engineeringpractices have little effect on these parameters, an understanding ofhow intrinsic factors influence growth is useful in predicting thetypes of microorganisms that may be present.Nutrients. Like other living organisms, microorganisms requirefood to grow. Carbon a

21、nd energy sources are usually sugars andstarches. Nitrogen requirements are met by the presence of protein.Vitamins and minerals are also necessary. Lactic acid bacteria haverather exacting nutritional requirements, but many aerobic sporeformers have tremendous enzymatic capabilities that allow grow

22、thon a wide variety of substrates. Cleanable systems facilitate removalof residual food material and deprive microorganisms of the nutri-ents required for growth, thus preventing a buildup of organisms inthe environment.Inhibitors. Either naturally occurring or added as preservatives,inhibitors may

23、be present in food. Preservatives are not substitutesfor hygienic practices and, with time, microorganisms may developresistance. A cleanable processing system is still essential in pre-venting development of a resistant population.Competing Microorganisms. The presence of one type ofmicroorganism a

24、ffects other organisms in foods. Some organismsproduce inhibiting compounds or grow faster; others are better ableto use the available nutrients in a food matrix.Water Activity. All life-forms require water for growth. Wateractivity awrefers to the availability of water in a food system and isdefine

25、d at a given temperature asVapor pressure of solution (food)aw= Vapor pressure of solute (water)The minimum water activities for growth of a variety of micro-organisms, along with representative foods, are listed in Table 1.These awminima are also factors in environmental humidity controldiscussed i

26、n the section on Extrinsic Factors.When food is enclosed in airtight packaging or in a chamberwith limited air circulation, an equilibrium awis achieved that isequal to the awof the food. In these situations, the awof the fooddetermines which organisms can grow. If the same foods areexposed to reduc

27、ed environmental relative humidity, such as meatcarcasses hanging in a controlled aging room or vegetables dis-played in an open case, surface dehydration acts as an inhibitor tomicrobial growth. Likewise, if a dry product, such as bread, isexposed to a moist environment, mold may grow on the surfac

28、e asmoisture is absorbed. Environmental relative humidity thus signif-icantly affects product shelf life.pH. For most microorganisms, optimal growth occurs at neutralpH (7.0). Few organisms grow under alkaline conditions, but some,such as yeasts, molds, and lactic acid bacteria, are acid tolerant. F

29、ig-ure 2 depicts pH values of a variety of foods and limiting pH valuesfor microorganisms.Extrinsic FactorsExtrinsic factors that influence the growth of microorganismsinclude temperature, environmental relative humidity, and oxygenlevels. Refrigeration and ventilation systems play a major role inco

30、ntrolling these factors.Temperature. Microorganisms can grow over a wide range oftemperatures. Minimum growth temperatures for a variety of spoilageand pathogenic bacteria of significance in foods are summarized inTable 2. Previously, 45F was thought to be sufficient to controlTable 1 Approximate Mi

31、nimum Water Activity for Growth of MicroorganismsOrganism awFoodsPseudomonads 0.98 Fresh fruits, vegetables, meatsSalmonella spp., E. coli 0.95 Many processed foodsListeria monocytogenes 0.93Bacillus cereus 0.92 Salted butterStaphylococcus aureus 0.86 Fermented sausageMolds 0.84 Soft, moist pet food

32、0.80 Pancake syrup, jam0.70 Corn syrupXerotrophic molds 0.65 CaramelsOsmophilic yeasts 0.62Limit of microbial growth 0.60 Wheat flour0.40 Nonfat dry milkTable 2 Minimum Growth Temperatures for Some Bacteria in FoodsOrganismPossibleSignificanceApproximateMinimum GrowthTemperature, FStaphylococcus aur

33、eus Foodborne disease 50Salmonella spp. Foodborne disease 42Clostridium botulinum, proteolytic nonproteolyticFoodborne disease5038Lactobacillus and LeuconostocSpoilage of fresh and cured meats32Listeria monocytogenes Foodborne disease 34Acinetobacter spp. Spoilage of precooked foods 31Pseudomonads S

34、poilage of raw fish, meats, poultry, and dairy products31Fig. 2 pH Ranges for Microbial Growth and RepresentativeExamplesFig. 2 pH Ranges for Microbial Growth and Representative ExamplesFood Microbiology and Refrigeration 22.3growth of pathogenic organisms. However, the emergence of psy-chrophilic p

35、athogens, such as Listeria monocytogenes, has dem-onstrated the need for lower temperatures. In the United States,41F is now recognized as the upper limit for safe refrigerationtemperature, although in some cases 34F or lower may be moreappropriate. Foods that can support growth of pathogenic micro-

36、organisms should not be held between 41 and 140F for more than2 h.Temperature is used to categorize microorganisms. Those capa-ble of growth above 113F, with optimum growth at 130 to 150F,are thermophiles. Thermophilic growth can be extremely rapid,with generation times of 10 to 20 min. Thermophiles

37、 can become aproblem in blanchers and other equipment that maintain food at ele-vated temperatures for extended periods. These organisms die or donot grow at refrigeration temperatures.Mesophiles grow best between 68 and 113F. Most pathogensare in this group, with optimum growth temperatures around

38、98.6F(i.e., body temperature). Mesophiles also include a number of spoil-age organisms. Growth of mesophiles is quite rapid, with typicalgeneration times of 20 to 30 min. Because mesophiles grow so rap-idly, perishable foods must be cooled as fast as possible to preventspoilage or potential unsafe c

39、onditions. Also, slower cooling ratescause mesophiles to adapt and grow at lower temperatures. Withmild temperature abuse, prolific growth can occur, leading to spoil-age or a potential health hazard.Psychrophiles can grow at 41F; some are able to grow at tem-peratures as low as 23F and are a primar

40、y cause of spoilage of per-ishable foods. Psychrophilic growth is slow compared to mesophilicand thermophilic growth, with maximum growth rates of 1 to 2 h orlonger. However, control of psychrophilic growth is a major require-ment in products with extended shelf life. Because many psychro-philes hav

41、e optimum temperatures in the mesophilic range, whatmay seem to be an insignificant increase in temperature can have amajor effect on the growth rate of spoilage organisms. Growthroughly doubles with each 5F increase in temperature. In practice,shelf life of fresh meat is maximized at 29F and is red

42、uced 50% byholding at 36F. Meat freezes at 28F.For all critical growth factors, the range over which growth canoccur is characteristic for a given organism. The range for growth isnarrower than that for survival. For example, the maximum temper-ature for growth is slightly above the optimum, and dea

43、th usuallyoccurs just slightly above the maximum. This is not the case at thelower end of the temperature range. Survival of psychrophilic andmost mesophilic microorganisms is enhanced by low storage tem-peratures. Freezing is not an effective lethal process; some organisms,notably gram-negative bac

44、teria, are damaged by freezing and may dieslowly, but others are extremely resistant. In fact, freezing is used asan effective means of preserving microbial cultures at extremely lowtemperatures (e.g., 110F).Environmental Relative Humidity. Water, previously dis-cussed as an essential intrinsic grow

45、th factor, is also a major extrin-sic factor. Environmental water acts as a vector for transmission ofmicroorganisms from one location to another through foot traffic oraerosols. Refrigeration drain pans and drip coils have been identi-fied as significant contributors of L. monocytogenes contaminati

46、onin food processing environments. Aerosols have also transmitted theagent that causes Legionnaires disease. High relative humidity incold rooms is a particular problem and leads to black mold build-upon walls and ceilings as well as growth of organisms in drains andother reservoirs of water. Conden

47、sation on ceilings supports micro-bial growth and can drip onto product contact surfaces. Inade-quately drained equipment collects stagnant water and supportsmicrobial growth that is easily transported throughout a productionfacility when people walk through puddles. It is extremely impor-tant to co

48、ntrol environmental relative humidity in food productionenvironments. Control measures are discussed further in the sectionon Regulations and Standards.Oxygen. Microorganisms are frequently classified by their oxy-gen requirement. Strictly aerobic microorganisms, such as moldsand pseudomonads, requi

49、re oxygen for growth. Conversely, strictanaerobes, such as Clostridium spp., cannot grow in the presence ofoxygen. Facultatively anaerobic microorganisms (e.g., coliforms)grow with or without oxygen present, and microaerophiles, such aslactobacilli, grow best in conditions with reduced oxygen levels.Controlled-atmosphere (CA) chambers for fruit storage use loweroxygen levels to prolong storage life by retarding growth of spoilageorganisms as well as influencing ripening. Vacuum packing also usesthis extrinsic growth factor by inhibiting the growth of strict ae

copyright@ 2008-2019 麦多课文库(www.mydoc123.com)网站版权所有
备案/许可证编号:苏ICP备17064731号-1