Studies on Survival of Bacteria: Rhythmic Response of Microorganisms to Freeze-Drying Additives

Various materials were mixed with suspensions of Serratia marcescens and other organisms. Samples were removed and frozen at intervals after mixing; the number of cells that survived both freeze-drying and exposure to air varied rhythmically as a function of time between mixing and freezing. When assayed before or immediately after drying there were essentially no fluctuations. The response was evident only when these dried samples were exposed to air. In a typical experiment, the number of cells surviving in the sample frozen 30 sec after adding propyl gallate was at least 10 times that in samples frozen either 20 sec earlier or 20 sec later. Other "peaks" in survival were observed at approximately 125 and 450 sec, but the times at which the peaks were observed were not consistent from one experiment to the next. Although we have been unable to control or predict the time at which maxima in resistance occur, we have shown that the phenomenon does occur with Escherichia coli and Saccharomyces cerevisiae as well as with S. marcescens. Furthermore, a rhythmic response also was obtained after a change in pH or cell concentration. It appears that microorganisms respond physiologically and synchronously to changes in their environment, and some of these responses have survival value.     

Viability of frozen rat granulocytes and granulocyte precursors

Mature rat polymorphonuclear leukocytes (PMNs) were frozen to ?196 °C, thawed, and tested for functional viability using a variety of criteria. The assays for functional viability included: qualitative and quantitative nitroblue tetrazolium tests for phagocytic activity, fluorometric tests for membrane integrity, chemotaxis, and bactericidal activity. Maximal survival was obtained when mature PMNs were frozen in the presence of 10% dimethyl sulfoxide (Me₂SO) and 5% hydroxyethyl-starch (HES) for cells cooled at ~10 °C per minute, followed by rapid warming. Maximal survival was obtained for granulocyte precursor cells (as measured by CFU-c) after freezing in the presence of 10% Me₂SO and cooling at ~10 °C per minute. The principal new findings for mature PMNs were: (i) there was a synergistic effect between intra- and extracellular protective additives; (ii) the optimal cooling rate increases from approximately 0.3 to 10 °C per minute when an extracellular protective agent, such as HES is included in the freezing media; (iii) the zwitterion buffer Hepes has a small but consistently beneficial effect on survival; (iv) granulocytes obtained from peripheral blood consistently show a higher functional survival after freezing (95%) than do PMNs obtained from a glycogen-induced peritoneal exudate (70%); (v) neither serum, plasma, nor other macromolecules are needed in the postt-haw dilution media to obtain high survival; and (vi) cells frozen using an optimized two-step protocol survived as well as those frozen using a continuous cooling protocol.     

Cryopreservation of sperm from the marine shrimp Sicyonia ingentis

Sperm from a marine shrimp, Sicyonia ingentis, were frozen to -196 degrees C using a variety of cooling rates and cryoprotectants. A cooling rate of 1 degree C/min resulted in minimal cell breakage. Sperm samples were frozen in solutions of known membrane stabilizers--trehalose, sucrose, proline, and glycerol. These compounds were somewhat effective but a dramatic increase in sperm viability was seen when DMSO was present in the freezing medium. Sperm viability was assessed using the in vitro acrosome reaction technique of Griffin et al. (1987). The highest sperm survival (56%) was obtained with samples frozen at 1 degrees C/min in a 5% (v/v) DMSO solution. No decrease in viability was seen in sperm samples stored in liquid nitrogen (-196 degrees C) for 1 month.     

A brief review of lyophilization damage and repair in bacterial preparations

The principal concern of those responsible for the maintenance of culture collections has been to preserve viability, but nonlethal damage should not be ignored. Whether disruption of any element of a cell is nonlethal depends on the ability of the cell to repair the damage. Subsequent repair of DNA damage can lead to mutation.The protective effect of additives, as measured by survival after lyophilized cultures are reconstituted, sometimes depends upon the interval between making the addition and freezing. A rhythmic variation in the extent of viability has been observed, but increases in number of viable cells cannot be attributed to a repair mechanism. Instead, the changes in survival appear to be associated with a physiological condition of the cell at the instant of freezing.Virulence is generally maintained by lyophilized bacteria, but when stored cultures of Y. pestis were assayed immediately after reconstitution, virulence for mice was significantly reduced (as many as 4000 cells per 50% lethal dose). The virulence could be fully restored by holding reconstituted cultures for 24 hr at room temperature, or by subculture in fresh media. Obviously, the injury induced by lyophilization and storage is not to the DNA.     

Cryoprotective effect of polyols on rat embryos during two-step freezing.

The cryoprotective effect of polyols on rat embryos was measured after two-step freezing, and the mechanism of action of polyols on embryo survival was examined. Rat embryos frozen in solution of polyol by two-step method at the morula stage showed higher survival than that obtained using DMSO. As the number of hydroxyl groups increased, the cryoprotective effect of the polyol increased. However, this was true only when the additive could permeate the cell membrane. Of the additives tested, four or five carbon polyols were most effective at concentrations of 0.3 or 1.0 M than two, three, six, or seven carbon polyols. The highest survival rate was obtained with adonitol, which yielded 83% embryo survival at 1.0 M and 67% even at 0.3 M. Embryos frozen in 0.3 M adonitol and transferred directly into foster mothers without any dilution of the additive after thawing developed into live young. During slow cooling below -40 degrees C, embryonic blastomeres exhibited cell fusion only in the presence of adonitol. These findings suggest that one cryoprotective action of polyols is that the hydroxyl groups act both on the cell surface and the cytoplasm to stabilize the bound water on the embryonic membrane, and that the length of the C-chain determines the permeability of the membrane to the additive.     

嗜碱细菌的液氮超低温冻结保藏

本文报道7株嗜碱细菌的液氮超低温快速冻结保藏的试验结果。从细胞存活率看,冻结保藏3个月,自然pH的10%甘油、5%二甲基亚砜保护剂保藏嗜碱细菌的效果相似于该方法用于一般细菌保藏的保存结果,说明液氮超低温冻结保藏法用于嗜碱细菌的保藏是安全有效的。如选择pH值接近嗜碱细菌的最适生长pH值的保护剂,则可以提高细胞存活率。     

Effect of caffeine on the post-thaw motility of buffalo spermatozoa

Buffalo semen was diluted (1:2) with lactose diluent containing caffeine (2, 4 and 6 mM). Diluted semen samples were frozen in a pellet form (0.15 ml), thawed 24 h after freezing in 2.9% sodium citrate for 30 sec and incubated at 37 degrees C for 3 h. Addition of caffeine to diluted buffalo semen before freezing resulted in a significant increase in the post-thaw motility of spermatozoa over the 3-h incubation period. When caffeine was added to the thawing medium, the post-thaw motility was further improved. Thus, the increase in motility due to caffiene treatment was even more pronounced than in samples treated with caffiene before freezing.     

Lipid and protein changes due to freezing in Dunning AT-1 cells

Defining the process of cellular injury during freezing, at the molecular level, is important for cryosurgical applications. This work shows changes to both membrane lipids and protein structures within AT-1 Dunning prostate tumor cells after a freezing stress which induced extreme injury and cell death. Cells were frozen in an uncontrolled fashion to -20 or -80 degrees C. Freezing resulted in an increase in the gel to liquid crystalline phase transition temperature (T(m)) of the cellular membranes and an increase in the temperature range over which the transition occurred, as determined by Fourier transform infrared spectroscopy (FTIR). Thin layer chromatography (TLC) analysis of total lipid extracts showed free fatty acids (FFA) in the frozen samples, indicating a change in the lipid composition. The final freezing temperature had no effect on the thermotropic response of the membranes or on the FFA content of the lipid fraction. The overall protein secondary structure as determined by FTIR showed only slight changes after freezing to -20 degrees C, in contrast to a strong and apparently irreversible denaturation after freezing to -80 degrees C. Taken together, these results suggest that the decrease in viability between control and frozen cells can be correlated with small changes in the membrane lipid composition and membrane fluidity. In addition, loss of cell viability is associated with massive protein denaturation as observed in cells frozen to -80 degrees C, which was not observed in samples frozen to -20 degrees C.     

State transitions and physicochemical aspects of cryoprotection and stabilization in freeze-drying of Lactobacillus rhamnosus GG (LGG)

Aims: The frozen and dehydrated state transitions of lactose and trehalose were determined and studied as factors affecting the stability of probiotic bacteria to understand physicochemical aspects of protection against freezing and dehydration of probiotic cultures. Methods and Results: Lactobacillus rhamnosus GG was frozen (–22 or –43°C), freeze‐dried and stored under controlled water vapour pressure (0%, 11%, 23% and 33% relative vapour pressure) conditions. Lactose, trehalose and their mixture (1 : 1) were used as protective media. These systems were confirmed to exhibit relatively similar state transition and water plasticization behaviour in freeze‐concentrated and dehydrated states as determined by differential scanning calorimetry. Ice formation and dehydrated materials were studied using cold‐stage microscopy and scanning electron microscopy. Trehalose and lactose–trehalose gave the most effective protection of cell viability as observed from colony forming units after freezing, dehydration and storage. Enhanced cell viability was observed when the freezing temperature was ?43°C. Conclusions: State transitions of protective media affect ice formation and cell viability in freeze‐drying and storage. Formation of a maximally freeze‐concentrated matrix with entrapped microbial cells is essential in freezing prior to freeze‐drying. Freeze‐drying must retain a solid amorphous state of protectant matrices. Freeze‐dried matrices contain cells entrapped in the protective matrices in the freezing process. The retention of viability during storage seems to be controlled by water plasticization of the protectant matrix and possibly interactions of water with the dehydrated cells. Highest cell viability was obtained in glassy protective media. Significance and Impact of the Study: This study shows that physicochemical properties of protective media affect the stability of dehydrated cultures. Trehalose and lactose may be used in combination, which is particularly important for the stabilization of probiotic bacteria in dairy systems.     

Effect of cryoprotectant concentration, equilibration time and thawing procedure on survival and development of rapid frozen-thawed mature mouse oocytes

Experiments were conducted to develop a simple rapid-freezing protocol for mature mouse oocytes that would yield a high proportion of oocytes with developmental potential. The effects of concentration (3.5, 4.5 and 6.0 M dimethyl sulfoxide (DMSO) all with 0.5 M sucrose) and the duration of exposure (2.5 min vs 45 sec) of oocytes to the cryoprotectant and its extraction after thawing in 2, 3 or 4 steps of descending sucrose concentration were studied. The most effective of the rapid-freezing and thawing protocols (4.5 M DMSO; 45 sec exposure and 3-step thawing) was compared to slow freezing protocols using 1.5 M DMSO and 1.0 M 1,2 propanediol as cryoprotectants. The DMSO concentrations had an effect on survival, fertilization and embryo development using short (45 sec) but not long (2.5 min) exposure. The rate of morphological oocyte survival was significantly higher using 4.5 M DMSO than 3.5 or 6.0 M (92% vs 82 and 73%, respectively). The development of fertilized embryos to blastocysts was also significantly higher at 4.5 M than at 3.5 or 6.0 M (68% vs 42 and 53%, respectively). The extraction of cryoprotectant in 3 or 4 steps of descending sucrose concentration resulted in higher survival (P < 0.01) and fertilization than in 2 steps. The best survival, fertilization and development was achieved with the 3-step procedure. Optimal combinations of conditions were 4.5 M DMSO at 45 sec prefreeze exposure and 3-step extraction of the cryoprotectant. Oocytes frozen by conventional methods had a survival, fertilization and development to blastocyst rate significantly lower than those frozen under the optimal rapid conditions. Thus rapid freezing of mature mouse oocytes with 4.5 M DMSO + 0.5 M sucrose and short prefreeze exposure is effective and has the additional advantage of being less time-consuming than slow freezing methods.     

Effect of protective agents, freezing temperature, rehydration media on viability of malolactic bacteria subjected to freeze-drying

AIMS: The effects of protective agents, rehydration media and freezing temperature on the viabilities of Lactobacillus brevis and Oenococcus oeni H-2 when subjected to freeze-drying were investigated. METHODS AND RESULTS: Several protectants and rehydration media were tested to improve the survival after freeze-drying. The cells were also frozen at -65 and -20 degrees C to check the effect of freezing temperature on the viability. CONCLUSIONS: The best protectant and rehydration medium to obtain the highest viability after freeze-drying varied with the species of bacteria. Yeast extract (4.0%) and sodium glutamate (2.5% ) gave maximum viability of L. brevis and O. oeni (67.8% and 53.6% respectively). The highest survival of L. brevis and O. oeni were obtained when rehydrated with 10% sucrose and MGY medium respectively. When the bacterial cells were frozen quickly (-65 degrees C) than slowly (-20 degrees C), L. brevis and O. oeni both showed increased viability after freeze-drying. SIGNIFICANCE AND IMPACT OF THE STUDY: The viabilities of L. brevis and O. oeni after freeze-drying were shown to be strain specific and dependent on protective agents, rehydration media and freezing temperature.     

Hemolysis of human red blood cells by freezing and thawing in solutions containing sucrose: relationship with posthypertonic hemolysis and solute movements

Human red blood cells were frozen at temperatures down to ?9 °C in solutions containing sucrose, and the hemolysis on thawing was measured. This was compared with the hemolysis caused by exposing the cells to high concentrations of sucrose and then resuspending them in more dilute solutions at 4 °C. The effects of the hypertonic solutions of sucrose on potassium, sodium, and sucrose movements were also investigated. It was found that sucrose does not prevent damage to the cells by very hypertonic solutions (whether during freezing and thawing or at 4 °C) but it does reduce hemolysis of cells previously exposed to these solutions if present in the resuspension (or thawing) solution. Evidence is presented that the damaging effects of the hypertonic solutions of sucrose occurring during freezing are associated with changes in cell membrane permeability but that posthypertonic hemolysis is not primarily associated with a “loading” of the cells with extracellular solutes in the hypertonic phase. It is concluded that sucrose may reduce hemolysis of red blood cells by slow freezing and thawing by reducing colloid osmotic swelling of cells with abnormally permeable membranes.     

Survival of cold-stressed Campylobacter jejuni on ground chicken and chicken skin during frozen storage

Campylobacter jejuni is prevalent in poultry, but the effect of combined refrigerated and frozen storage on its survival, conditions relevant to poultry processing and storage, has not been evaluated. Therefore, the effects of refrigeration at 4 degrees C, freezing at -20 degrees C, and a combination of refrigeration and freezing on the survival of C. jejuni in ground chicken and on chicken skin were examined. Samples were enumerated using tryptic soy agar containing sheep's blood and modified cefoperazone charcoal deoxycholate agar. Refrigerated storage alone for 3 to 7 days produced a reduction in cell counts of 0.34 to 0.81 log10 CFU/g in ground chicken and a reduction in cell counts of 0.31 to 0.63 log10 CFU/g on chicken skin. Declines were comparable for each sample type using either plating medium. Frozen storage, alone and with prerefrigeration, produced a reduction in cell counts of 0.56 to 1.57 log10 CFU/g in ground chicken and a reduction in cell counts of 1.38 to 3.39 log10 CFU/g on chicken skin over a 2-week period. The recovery of C. jejuni following freezing was similar on both plating media. The survival following frozen storage was greater in ground chicken than on chicken skin with or without prerefrigeration. Cell counts after freezing were lower on chicken skin samples that had been prerefrigerated for 7 days than in those that had been prerefrigerated for 0, 1, or 3 days. This was not observed for ground chicken samples, possibly due to their composition. C. jejuni survived storage at 4 and -20 degrees C with either sample type. This study indicates that, individually or in combination, refrigeration and freezing are not a substitute for safe handling and proper cooking of poultry.     

Operating conditions that affect the resistance of lactic acid bacteria to freezing and frozen storage

Thermophilic lactic acid bacteria exhibit different survival rates during freezing and frozen storage, depending on the processing conditions. We used a Plackett and Burman experimental design to study the effects of 13 experimental factors, at two levels, on the resistance of Streptococcus thermophilus and Lactobacillus delbrueckii subsp. bulgaricus to freezing and frozen storage. The resistance was evaluated by quantifying the decrease of acidification activity during freezing and throughout 8 weeks of storage. Acidification activity after freezing and frozen storage was affected by 12 experimental factors. Only the thawing temperature did not show any significant effect. S. thermophilus was more resistant than L. bulgaricus and the cryoprotective effect of glycerol during freezing and storage was confirmed. The temperature and duration of the cryoprotection step influenced acidification activity following the freezing step: the lower the temperature and the shorter the duration, the higher the activity. Acidification activity after storage was affected by several experimental factors involved in the fermentation stage: use of NaOH instead of NH4OH for pH control, addition of Tween 80 in the culture medium, and faster cooling led to better cryotolerance. Resistance to freezing and frozen storage was improved by using a high freezing rate and a low storage temperature. Finally, this study revealed that the conditions under which lactic acid bacteria are prepared should be well controlled to improve their preservation and to limit the variability between batches and between species.     

Examination of some processing methods for freezing boar semen.

Five experiments were conducted to examine the effect of processing methods and diluents on survival and morphology of boar spermatozoa after freezing. Post-thawing survival of spermatozoa was better for Beltsville-F3 (BF3) than for tris-fructose-EDTA freezing diluent when the seminal plasma and glycerol were removed prior to freezing (method A). Both freezing diluents yielded similar viability results when the spermatozoa were frozen in the presence of siminal plasma and glycerol (method B). Viability of spermatozoa after thawing was better when glycerol concentration in the prefreezing diluent (method A) or in the freezing medium (method B) was 2-5 and 5-0 rather than 7-5%. Cooling of diluted semen to 5 degrees C beyond 4 h decreased the post-thawing survival of spermatozoa. The proportion of spermatozoa with undamaged acrosomes after processing and thawing by different methods was indistinguishable and relatively low. When the semen was frozen at cell concentrations ranging from 0-25 to 2-0 X 10(9)/ml, the viability of spermatozoa declined with increasing concentration following freezing in BF3, and S-1 diluents. Viability results were very similar for all cell concentrations examined when tris-fructose-EDTA diluent was used, indicating the possibility of freezing boar semen in a concentrated state.     

乳酸菌的抗冷冻性及耐受机理

乳酸菌发酵剂在工业生产过程中,会受到冷冻的刺激,如真空冷冻干燥及后期的低温保藏,此外,发酵乳制品的保藏和干酪的成熟过程也都在低温中进行。这些均会对乳酸菌发酵剂及发酵乳制品质量产生一定的影响。因此,掌握乳酸菌在冷冻条件下的反应机理有助于优化发酵剂和发酵乳制品在工业生产中的冷冻、发酵和贮藏条件,从而提高产品质量和生产效益。本文对乳酸菌的抗冷冻性及机理进行了分析,并对发酵剂的保护提出具体措施。     

Preservation of gastrointestinal bacteria and their microenvironmental associations in rats by freezing.

The use of frozen rat gastrointestinal tissue samples for both the recovery of viable bacteria and for observation of microbial communities associated with the tissue was investigated. A decrease of 1 log in lactobacilli, bifidobacteria, and anaerobes was observed when the numbers of bacteria recoverable from frozen tissue (stored 7 to 9 days) were compared to those recoverable from fresh nonfrozen tissue (zero time control). However, freezing did not appear to decrease the numbers of recoverable coliforms. Tissues, cleaved with razor blades after being frozen and stored for 7 to 9 days, showed bacterial communities situated on the mucosa and in the lumen of gastrointestinal specimens. This freezing technique preserved structures not previously observed in the gastrointestinal tract. This indicates that freezing is a good method to use to study such fragile microenvironments.     

Roles of unfrozen fraction, salt concentration, and changes in cell volume in the survival of frozen human erythrocytes

The cause of slow freezing injury and the basis of the protection by solutes like glycerol are subjects of debate. During slow freezing, cells are sequestered in unfrozen channels between ice crystals that grow by removing pure water from the channels. As a consequence, the solute concentration in the channels rises and the volume of liquid in the channels progressively decreases. The rise in solute concentration, in turn, causes the cells to progressively shrink osmotically. Until recently cryobiologists have ascribed slow freezing injury to either the rise in solute (electrolyte) concentrations in the channels or to the consequent cell shrinkage, rather than to the decrease in the of the channels. Although ordinarily reciprocally coupled, it is possible to separate the composition of the channels from their size, or more precisely from the magnitude of the unfrozen fraction, by suspending cells in NaCl/cryoprotectant solutions in which the mole ratio of the two is held constant, but the molality of the NaCl is allowed to vary below and above isotonic. When human red cells are frozen in such solutions to temperatures that produce given NaCl concentrations (ms), but varying unfrozen fractions (U), survival at low U is found to be strongly dependent on U but independent of ms. At higher values of U, survival becomes inversely dependent on both ms and U. Although cell volume during freezing is independent of the NaCl tonicity in the solution, the cells in the several solutions differ in volume both prior to the onset of freezing and after the completion of thawing. We have now examined and compared the effect of returning the thawed cells to isotonic solutions and isotonic volume or nearly so, and find that there is little change in survival after exposure to low U, but that survival after exposure to high U values exhibits substantially increased sensitivity to ms, a sensitivity that is probably a manifestation of posthypertonic hemolysis. Low values of U were in general attained by the use of solutions with low tonicities of NaCl, and as a consequence cells frozen to low U values had larger volumes prior to freezing than cells frozen to higher U values. The significance of this confounding is discussed.     

Addition of oligosaccharide decreases the freezing lesions on human red blood cell membrane in the presence of dextran and glucose

Although incubation with glucose before freezing can increase the recovery of human red blood cells frozen with polymer, this method can also result in membrane lesions. This study will evaluate whether addition of oligosaccharide (trehalose, sucrose, maltose, or raffinose) can improve the quality of red blood cell membrane after freezing in the presence of glucose and dextran. Following incubation with glucose or the combinations of glucose and oligosaccharides for 3 h in a 37 °C water bath, red blood cells were frozen in liquid nitrogen for 24 h using 40% dextran (W/V) as the extracellular protective solution. The postthaw quality was assessed by percent hemolysis, osmotic fragility, mean corpuscle volume (MCV), distribution of phosphatidylserine, the postthaw 4 °C stability, and the integrity of membrane. The results indicated the loading efficiency of glucose or oligosaccharide was dependent on their concentrations. Moreover, addition of trehalose or sucrose could efficiently decrease osmotic fragility of red blood cells caused by incubation with glucose before freezing. The percentage of damaged cell following incubation with glucose was 38.04 ± 21.68% and significantly more than that of the unfrozen cells (0.95 ± 0.28%, P < 0.01). However, with the increase of the concentrations of trehalose, the percentages of damaged cells were decreased steadily. When the concentration of trehalose was 400 mM, the percentage of damaged cells was 1.97 ± 0.73% and similar to that of the unfrozen cells (P > 0.05). Moreover, similar to trehalose, raffinose can also efficiently prevent the osmotic injury caused by incubation with glucose. The microscopy results also indicated addition of trehalose could efficiently decrease the formation of ghosts caused by incubation with glucose. In addition, the gradient hemolysis study showed addition of oligosaccharide could significantly decrease the osmotic fragility of red blood cells caused by incubation with glucose. After freezing and thawing, when both glucose and trehalose, sucrose, or maltose were on the both sides of membrane, with increase of the concentrations of sugar, the percent hemolysis of frozen red blood cells was firstly decreased and then increased. When the total concentration of sugars was 400 mM, the percent hemolysis was significantly less than that of cells frozen in the presence of dextran and in the absence of glucose and various oligosaccharides (P < 0.01). However, when both glucose and trehalose were only on the outer side of membrane, with increase of the concentrations of sugars, the percent hemolysis was increased steadily. Furthermore, addition of oligosaccharides can efficiently decrease the osmotic fragility and exposure of phosphatidylserine of red blood cells frozen with glucose and dextran. In addition, trehalose or raffinose can also efficiently mitigate the malignant effect of glucose on the postthaw 4 °C stability of red blood cells frozen in the presence of dextran. Finally, addition of trehalose can efficiently protect the integrity of red blood cell membrane following freezing with dextran and glucose. In conclusion, addition of oligosaccharide can efficiently reduce lesions of freezing on red blood cell membrane in the presence of glucose and dextran.     

Survival of Campylobacter jejuni in chicken meat at frozen storage temperatures

The aim of this study was to determine the survival of Campylobacter jejuni in chicken meat samples at frozen temperatures and given length of incubation and to determine the impact of aerobic bacteria on the survival of C. jejuni. The chicken meat samples were inoculated with C. jejuni NCTC 11351 suspensions and stored in bags at temperatures of -20°C and -70°C. The mean value of C. jejuni from meat samples decreased from 7.52 log10 CFU/g after 30 minutes of incubation at ambient temperature, to 3.87 log10 CFU/g on the eighth week of incubation at -20°C, and to 3.78 log10 CFU/g at incubation at -70°C after the same incubation period. Both freezing temperatures, -20°C and -70°C, decreased the number of campylobacters. The presence of aerobic mesophilic bacteria did not influence the survival of C. jejuni in chicken meet samples. Keeping poultry meat at freezing temperatures is important for the reduction of C. jejuni, which has a strong influence on the prevention of occurrence of campylobacteriosis in humans.