Storage of poultry meat under modified atmospheres or vacuum packs: possible role of microbial metabolites as indicator of spoilage

The effect of carbon dioxide (100%), nitrogen (100%), carbon dioxide/oxygen (20% : 80%) or vacuum pack at 3 and 10°C was studied on the microbial flora, in skinless poultry breast fillets or thigh meat. Lactic acid bacteria and Brochothrix thermosphacta were the predominant organisms in samples stored in vacuum packs, carbon dioxide and nitrogen. Pseudomonads grew only in oxygen/carbon dioxide packaging systems. The concentration of lactate diminished in both thigh and breast meat during storage at 3 and 10°C. This decrease was more pronounced in thigh meat stored under 20% : 80% carbon dioxide/oxygen. Acetate increased to varying degrees in all samples regardless of the storage conditions.     

Screening of bacterial strains capable of converting biodiesel‐derived raw glycerol into 1,3‐propanediol, 2,3‐butanediol and ethanol

The ability of bacterial strains to assimilate glycerol derived from biodiesel facilities to produce metabolic compounds of importance for the food, textile and chemical industry, such as 1,3‐propanediol (PD), 2,3‐butanediol (BD) and ethanol (EtOH), was assessed. The screening of 84 bacterial strains was performed using glycerol as carbon source. After initial trials, 12 strains were identified capable of consuming raw glycerol under anaerobic conditions, whereas 5 strains consumed glycerol under aerobiosis. A plethora of metabolic compounds was synthesized; in anaerobic batch‐bioreactor cultures PD in quantities up to 11.3 g/L was produced by Clostridium butyricum NRRL B‐23495, while the respective value was 10.1 g/L for a newly isolated Citrobacter freundii. Adaptation of Cl. butyricum at higher initial glycerol concentration resulted in a PD_max concentration of ～32 g/L. BD was produced by a new Enterobacter aerogenes isolate in shake‐flask experiments, under fully aerobic conditions, with a maximum concentration of ～22 g/L which was achieved at an initial glycerol quantity of 55 g/L. A new Klebsiella oxytoca isolate converted waste glycerol into mixtures of PD, BD and EtOH at various ratios. Finally, another new C. freundii isolate converted waste glycerol into EtOH in anaerobic batch‐bioreactor cultures with constant pH, achieving a final EtOH concentration of 14.5 g/L, a conversion yield of 0.45 g/g and a volumetric productivity of ～0.7 g/L/h. As a conclusion, the current study confirmed the utilization of biodiesel‐derived raw glycerol as an appropriate substrate for the production of PD, BD and EtOH by several newly isolated bacterial strains under different experimental conditions.     

Phenolic extract from olives: inhibition of Staphylococcus aureus

The presence of olive extract in different media with or without glucose retarded staphylococcal growth and accentuated the secretion of protein into the media. Moreover the extract influenced the electrophoretic patterns of proteins secretion into the culture supernatant fluid.     

Listeria monocytogenes Attachment to and Detachment from Stainless Steel Surfaces in a Simulated Dairy Processing Environment

The presence of pathogens in dairy products is often associated with contamination via bacteria attached to food-processing equipment, especially from areas where cleaning/sanitation is difficult. In this study, the attachment of Listeria monocytogenes on stainless steel (SS), followed by detachment and growth in foods, was evaluated under conditions simulating a dairy processing environment. Initially, SS coupons were immersed in milk, vanilla custard, and yogurt inoculated with the pathogen (10⁷ CFU/ml or CFU/g) and incubated at two temperatures (5 and 20°C) for 7 days. By the end of incubation, cells were mechanically detached from coupons and used to inoculate freshly pasteurized milk which was subsequently stored at 5°C for 20 days. The suspended cells in all three products in which SS coupons were immersed were also used to inoculate freshly pasteurized milk (5°C for 20 days). When SS coupons were immersed in milk, shorter lag phases were obtained for detached than for planktonically grown cells, regardless of the preincubation temperature (5 or 20°C). The opposite was observed when custard incubated at 20°C was used to prepare the two types of inocula. However, in this case, a significant increase in growth rate was also evident when the inoculum was derived from detached cells. In another parallel study, while L. monocytogenes was not detectable on SS coupons after 7 days of incubation (at 5°C) in inoculated yogurt, marked detachment and growth were observed when these coupons were subsequently transferred and incubated at 5°C in fresh milk or/and custard. Overall, the results obtained extend our knowledge on the risk related to contamination of dairy products with detached L. monocytogenes cells.Listeria monocytogenes is ubiquitous in nature due to its inherent ability to survive and grow under a wide range of adverse environmental conditions, such as refrigeration temperatures, high acidity and salinity, and reduced water activity (16). This microorganism is a major concern for the food industry, since it is the causal agent of listeriosis, a severe disease with high hospitalization and case-fatality rates (approximately 91% and 30%, respectively) (25). According to the European Centre for Disease Control and Prevention, listeriosis was the fifth most common zoonotic infection in Europe in 2006 (14), while it accounts for approximately 28% of the deaths resulting from food-borne illnesses in the United States (34).In the food industry, inadequately cleaned food-processing equipment (e.g., stainless steel [SS] surfaces) constitutes a potential source for L. monocytogenes, resulting in contamination of foods which come in contact with such equipment (36). Even though adherence to strict sanitation practices should minimize the risk of survivors on surfaces, existing evidence suggests that a considerable risk may occur in sites of processing plants which are not easily cleaned or sanitized, such as those that do not allow direct access of sanitation equipment for abrasion (e.g., edges, convex surfaces, etc.) (43, 45). Attachment to surfaces is believed to be important for the survival and persistence of this pathogen in such environments, with some strains able to remain on equipment surfaces for several years (32, 37). Thus, L. monocytogenes has been shown to adhere to and form biofilms on various food contact surfaces under laboratory conditions (3, 42, 44). Furthermore, attached L. monocytogenes cells are more difficult to mechanically remove from surfaces and are more resistant to sanitizers than their free-living counterparts (15, 40).Dairy products have been implicated in outbreaks of listeriosis (10, 31). However, most of the in vitro studies of the growth and survival of L. monocytogenes in such products have used strains previously cultivated planktonically (41). Although the results obtained in these studies are of great value, such studies have not taken into consideration that cells contaminating a product in a food-processing environment are usually attached to surfaces enclosed in biofilms. Limited information is available on the kinetic behavior of L. monocytogenes in dairy products inoculated with detached cells, although preincubation conditions have been shown to influence subsequent growth and survival of L. monocytogenes in foods (7, 13, 17, 18). Given the major physiological differences between attached and planktonic cells (15, 27, 48), an effect on subsequent growth might be possible.Considering the above, the main objective of the present study was to assess the influence of L. monocytogenes preincubation conditions with respect to mode of growth (either attached to SS or grown suspended in dairy products) on the subsequent growth of this pathogen in milk (at 5°C for 20 days). To prepare the two types of inocula, two different growth media (milk and vanilla custard) and temperatures (5 and 20°C) were studied. The unforced detachment of L. monocytogenes cells from SS coupons and growth in two dairy products (milk and custard) at 5°C for 20 days was also evaluated. In the latter case, previous attachment of cells to the coupons was done under especially adverse preincubation conditions (in yogurt at 5°C for 7 days).     

Effect of microbial cell‐free meat extract on the growth of spoilage bacteria

Aims: This study examined the effect of microbial cell‐free meat extract (CFME) derived from spoiled meat, in which quorum sensing (QS) compounds were present, on the growth kinetics (lag phase, and growth rate) of two spoilage bacteria, Pseudomonas fluorescens and Serratia marcescens. Methods and Results: Aliquots of CFME from spoiled meat were transferred to Brain Heart Infusion broth inoculated with 10³ CFU ml^?1 of 18 h cultures of Ps. fluorescens or Ser. marcescens, both fresh meat isolates; CFME derived from unspoiled fresh meat (‘clean’ meat) served as a control. Changes in impedance measurements were monitored for 48 h, and the detection time (Tdet) was recorded. It was found that in the absence of CFME containing QS compounds the Tdet was shorter (P < 0·05) than that in broth samples with added CFME from spoiled meat. The rate of growth of Ps. fluorescens, recorded as the maximum slope rate of conductance changes (MSrCC), after Tdet, was higher (P < 0·05) in samples with CFME containing QS compounds compared to samples without CFME or CFME derived from ‘clean’ meat. Similar results in MSrCC of impedance changes were obtained for Ser. marcescens. Conclusions: The study indicated that the growth rate (expressed in MSrCC units) of meat spoilage bacteria in vitro was enhanced in samples supplemented with CFME containing QS compounds compared to control samples (i.e., without CFME or with CFME from ‘clean’ meat). This behaviour may explain the dominant role of these two bacteria in the spoilage of meat. Significance and Impact of the Study: These results illustrate the potential effect of signalling compounds released during storage of meat on the behaviour of meat spoilage bacteria. Understanding such interactions may assist in the control of fresh meat quality and the extension of its shelf life.     

Yeast heterogeneity during spontaneous fermentation of black Conservolea olives in different brine solutions

Aims: To assess the yeast community structure and dynamics during Greek‐style processing of natural black Conservolea olives in different brine solutions. Methods and Results: Black olives were subjected to spontaneous fermentation in 6% (w/v) NaCl brine solution or brine supplemented with (i) 0·5% (w/v) glucose, (ii) 0·2% (v/v) lactic acid and (iii) both glucose and lactic acid. Yeast species diversity was evaluated at the early (2 days), middle (17 days) and final (35 days) stages of fermentation by restriction fragment length polymorphism and sequence analyses of the 5·8S internal transcribed spacer and the D1/D2 ribosomal DNA (rDNA) regions of isolates. Analysis revealed a relatively broad range of biodiversity composed of 10 genera and 17 species. In all treatments, yeasts were the main micro‐organisms involved in fermentation together with lactic acid bacteria that coexisted throughout the processes. Metschnikowia pulcherrima was the dominant yeast species at the onset of fermentation, followed by Debaryomyces hansenii and Aureobasidium pullulans. Species heterogeneity changed as fermentations proceeded and Pichia membranifaciens along with Pichia anomala evolved as the main yeasts of olive elaboration, prevailing at 17 and 35 days of the process. Molecular techniques allowed for the identification of five yeast species, namely A. pullulans, Candida sp., Candida silvae, Cystofilobasidium capitatum and M. pulcherrima, which have not been reported previously in black olive fermentation. Conclusions: By using molecular techniques, a rich yeast community was identified from Conservolea black olive fermentations. Metschnikowia pulcherrima was reported for the first time to dominate in different brines at the onset of fermentation, whereas Pichia anomala and P. membranifaciens evolved during the course. The addition of glucose and/or lactic acid perturbed yeast succession and dominance during fermentation. Significance and Impact of the Study: Yeasts have an important role in black olive fermentation and contribute to the development of the organoleptic characteristics of the final product. At the same time, certain species can cause significant spoilage. The present study adds to a better knowledge of yeast communities residing in olive fermentations towards a well‐controlled process with minimization of product’s losses.     

Inhibition of the Early Stage of Salmonella enterica Serovar Enteritidis Biofilm Development on Stainless Steel by Cell-Free Supernatant of a Hafnia alvei Culture

Compounds present in Hafnia alvei cell-free culture supernatant cumulatively negatively influence the early stage of biofilm development by Salmonella enterica serovar Enteritidis on stainless steel while they also reduce the overall metabolic activity of S. Enteritidis planktonic cells. Although acylhomoserine lactones (AHLs) were detected among these compounds, the use of several synthetic AHLs was not able to affect the initial stage of biofilm formation by this pathogen.Biofilms are groups of bacteria encased in a self-produced extracellular matrix (5, 6). Biofilms formed on stainless steel (SS) surfaces in food-processing areas are of great importance since they may lead to food spoilage and transmission of diseases (2, 16). This sessile mode of life allows bacteria to enjoy a number of advantages, such as increased resistance to antimicrobial agents (9, 12). Notably, it is widely accepted that bacteria (both planktonic and biofilm cells) communicate by releasing and sensing signaling compounds in a process commonly known as quorum sensing (13, 18, 24).Salmonella enterica serovar Enteritidis is one of the most important bacterial pathogens worldwide (7, 17). Hafnia alvei are frequent psychrotrophic members of the Enterobacteriaceae community in meat products, playing a role in their spoilage, while they have been shown to be capable of producing signaling compounds (3). In this study, in order to determine any possible influence of compounds produced by H. alvei on the biofilm-forming ability of S. Enteritidis, the latter was left to develop biofilm on SS surfaces in the presence of conditioned medium obtained after the growth of the former. Biofilm formation was assessed directly by detaching cells and enumerating them and, also, indirectly by automated conductance measurements.     

Development of a microbial model for the combined effect of temperature and pH on spoilage of ground meat, and validation of the model under dynamic temperature conditions

The changes in microbial flora and sensory characteristics of fresh ground meat (beef and pork) with pH values ranging from 5.34 to 6.13 were monitored at different isothermal storage temperatures (0 to 20 degrees C) under aerobic conditions. At all conditions tested, pseudomonads were the predominant bacteria, followed by Brochothrix thermosphacta, while the other members of the microbial association (e.g., lactic acid bacteria and Enterobacteriaceae) remained at lower levels. The results from microbiological and sensory analysis showed that changes in pseudomonad populations followed closely sensory changes during storage and could be used as a good index for spoilage of aerobically stored ground meat. The kinetic parameters (maximum specific growth rate [mu(max)] and the duration of lag phase [lambda]) of the spoilage bacteria were modeled by using a modified Arrhenius equation for the combined effect of temperature and pH. Meat pH affected growth of all spoilage bacteria except that of lactic acid bacteria. The "adaptation work," characterized by the product of mu(max) and lambda(mu(max) x lambda) was found to be unaffected by temperature for all tested bacteria but was affected by pH for pseudomonads and B. thermosphacta. For the latter bacteria, a negative linear correlation between ln(mu(max) x lambda) and meat pH was observed. The developed models were further validated under dynamic temperature conditions using different fluctuating temperatures. Graphical comparison between predicted and observed growth and the examination of the relative errors of predictions showed that the model predicted satisfactorily growth under dynamic conditions. Predicted shelf life based on pseudomonads growth was slightly shorter than shelf life observed by sensory analysis with a mean difference of 13.1%. The present study provides a "ready-to-use," well-validated model for predicting spoilage of aerobically stored ground meat. The use of the model by the meat industry can lead to effective management systems for the optimization of meat quality.     

Production of 1,3-propanediol by <Emphasis Type="Italic">Clostridium butyricum</Emphasis> growing on biodiesel-derived crude glycerol through a non-sterilized fermentation process

The aim of the present study was to investigate the production of 1,3-propanediol (PDO) under non-sterile fermentation conditions by employing the strain Clostridium butyricum VPI 1718. A series of batch cultures were performed by utilizing biodiesel-derived crude glycerol feedstocks of different origins as the sole carbon source, in various initial concentrations. The strain presented similarities in terms of PDO production when cultivated on crude glycerol of various origins, with final concentrations ranging between 11.1 and 11.5 g/L. Moreover, PDO fermentation was successfully concluded regardless of the initial crude glycerol concentration imposed (from 20 to 80 g/L), accompanied by sufficient PDO production yields (0.52–0.55 g per gram of glycerol consumed). During fed-batch operation under non-sterile culture conditions, 67.9 g/L of PDO were finally produced, with a yield of 0.55 g/g. Additionally, the sustainability of the bioprocess during a continuous operation was tested; indeed, the system was able to run at steady state for 16 days, during which PDO effluent level was 13.9 g/L. Furthermore, possible existence of a microbial community inside the chemostat was evaluated by operating a polymerase chain reaction-denaturing gradient gel electrophoresis (PCR-DGGE) analysis, and DGGE results revealed the presence of only one band corresponding to that of C. butyricum VPI 1718. Finally, non-sterile continuous cultures were carried out at different dilution rates (D), with inlet glycerol concentration at 80 g/L. Maximum PDO production was achieved at low D values (0.02 h⁻¹) corresponding to 30.1 g/L, while the elaboration of kinetic data from continuous cultures revealed the stability of the bioprocess proposed, with global PDO production yield corresponding to 0.52 g/g.     

Quorum sensing in the context of food microbiology

Food spoilage may be defined as a process that renders a product undesirable or unacceptable for consumption and is the outcome of the biochemical activity of a microbial community that eventually dominates according to the prevailing ecological determinants. Although limited information are reported, this activity has been attributed to quorum sensing (QS). Consequently, the potential role of cell-to-cell communication in food spoilage and food safety should be more extensively elucidated. Such information would be helpful in designing approaches for manipulating these communication systems, thereby reducing or preventing, for instance, spoilage reactions or even controlling the expression of virulence factors. Due to the many reports in the literature on the fundamental features of QS, e.g., chemistry and definitions of QS compounds, in this minireview, we only allude to the types and chemistry of QS signaling molecules per se and to the (bioassay-based) methods of their detection and quantification, avoiding extensive documentation. Conversely, we attempt to provide insights into (i) the role of QS in food spoilage, (ii) the factors that may quench the activity of QS in foods and review the potential QS inhibitors that might "mislead" the bacterial coordination of spoilage activities and thus may be used as biopreservatives, and (iii) the future experimental approaches that need to be undertaken in order to explore the "gray" or "black" areas of QS, increase our understanding of how QS affects microbial behavior in foods, and assist in finding answers as to how we can exploit QS for the benefit of food preservation and food safety.