RAPID DETECTION OF SALMONELLA TYPHIMURIUM IN FOOD SAMPLES USING A BIENZYME ELECTROCHEMICAL BIOSENSOR WITH FLOW INJECTION

A bienzyme (tyrosinase and horseradish peroxidase) electrochemical biosensor was developed for detection of Salmonella typhimurium, and evaluated for application in a flow injection system coupled with immunomagnetic separation for food samples. Parameters for immunomagnetic separation, enzymatic reaction, flow injection and electrochemical detection were determined using pure culture samples. The selectivity was tested in the presence of Listeria monocytogenes, Campylobacter jejuni and E. coli 0157:H7. The results showed a linear relationship for logarithmic values between peak current ratio and the cell number of S. typhimurium in the range of 10³ 10⁵ cfu/mL, with R²= 0.99. The detection limit of this method was 1.09 × 10³ cfu/mL for S. typhimurium and the detection time was 2.5 h. Samples of chicken carcass wash water and ground beef were used to evaluate the biosensor. The results demonstrated that this biosensor has a potential for rapid detection of different pathogens in various food samples.     

A CHEMILUMINESCENCE BIOSENSOR COUPLED WITH IMMUNOMAGNETIC SEPARATION FOR RAPID DETECTION OF SALMONELLA TYPHIMURIUM

A chemiluminescence biosensor, using a fiber-optic-linked photometer and a data acquisition unit connected to a PC, was developed in conjunction with immunomagnetic separation for rapid detection of Salmonella Typhimurium. Magnetic microbeads coated with Anti-Salmonella antibodies and anti-Salmonella antibodies conjugated with horseradish peroxidase (HRP) were added to artificially-inoculated samples, and the immuno-reaction was completed in 60 min resulting in a sandwich complex. A magnetic field was applied to collect magnetic beads and the addition of luminol to HRP-conjugated antibodies resulted in a chemiluminescence reaction. The signal was collected through a fiber optic light guide, measured with a photometer, and recorded in the data acquisition unit. The minimum detection limit of the chemiluminescence biosensor for S. Typhimurium was 1.97 × 10³ CFU/mL and the range of the detectable signal was from 8.6 to 350 mV for cell numbers from 1.97 × 10³ to 1.97 × 10⁶ CFU/mL. Signal values for 10⁶ CFU/mL of S. Typhimurium were at least 97 and 394% higher than the corresponding values for S. enteritidis and four times the signal values for others including S. montevideo, S. california, S. heidlberg, and S. seftenberg, respectively. The biosensor response showed a significant difference (P < 0.05) between 10³ CFU/mL S. Typhimurium and 10⁶ CFU/mL of commonly-occurring bacteria in foods including Listeria monocytogenes, Pseudomonas aeruginosa, Citrobacter freundii, Campylobacter jejuni, Escherichia coli O157, and generic Escherichia coli. A regression equation, V = 0.0262 N ^5.7713, with R²= 0.9713 was obtained for the calibration curve over the detection range for S. Typhimurium. The whole procedure could be completed within 90 min.     

APPLICABILITY OF RAPID METHODS FOR DETECTION OF SALMONELLA SPP. IN POULTRY FEEDS: A REVIEW

The rapid detection of pathogenic microbial species in feed is of paramount importance considering its implications for animal production and food safety. More sensitive and rapid detection of contaminated feedstuffs may lead to more selective and therefore less expensive treatment of feeds, reduced rates of transmission to a poultry host and reduced carcass contamination. In order to interrupt the cycle of Salmonella spp. transmission from feed to poultry to the consumer, more rapid detection methods to monitor these sources are needed that provide conclusive results within the time frame of feed mixing or broiler processing. Within the last decade, new variations of selective media have been investigated to increase selectivity without reducing Salmonella spp. recovery. Immunological assay methods may also decrease assay time from 96 h to within 24–30 h. But all commercially available methods still require 16 to 57 h for preenrichment, enrichment, and in some cases, postenrichment to recover sublethally injured cells before the assay can be performed. Among the molecular methods that are currently available, the polymerase chain reaction (PCR) represents a tremendous potential for the detection of low levels of pathogenic bacteria. Once optimized, rapid methods may be used to quickly, reliably and inexpensively screen a variety of feedstuffs and feed components for the presence of Salmonella spp., with the goal of minimizing both the cost of feed treatment and the horizontal transmission of Salmonella spp. from feed to poultry.     

ETHYL ALCOHOL REDUCTION OF SALMONELLA TYPHIMURIUM IN POULTRY FEED

This study was designed to evaluate the effect of ethyl alcohol as a potential treatment for reduction of Salmonella populations in poultry feed. Growth rate of S. typhimurium in tryptic soy broth was significantly reduced by addition of greater than 0.3% volume/volume of ethyl alcohol and growth was completely inhibited by addition of 5% ethyl alcohol. Ethyl alcohol concentrations of 20% volume/weight and greater significantly reduced initial S.typhimurium populations in poultry feed (for 20% treated, 2.31 ± 0.31 vs 3.39 ± 0.29 for untreated; P < 0.05). When feed treatment was administered either before or after inoculation of S. typhimurium with 60% ethyl alcohol or 0.04% buffered propionic acid, populations in feeds treated after inoculation were decreased to a nondetection level (< 1.0 log₁₀ CFU/g) by ethyl alcohol treatment but not by other treatments. Ethyl alcohol treatment may have the potential for reducing Salmonella spp. contamination in poultry feed.     

A MINIATURIZED ENRICHMENT SEROLOGY METHOD FOR RAPID DETECTION of SALMONELLA FROM POULTRY MEAT and REARING FARMS ENVIRONMENT

A miniaturization of the enrichment serology method for the detection of Salmonella was improved in order to make the technique more reliable, cheaper, and faster. the miniaturized method ("Micromethod") was compared to the Sperber and Deibel's method ("Macromethod") and with a classical isolation method; 1062 samples including 700 rearing farms environment samples, 247 poultry meat samples, and 115 nonfat dry milk samples were analyzed. Specificity of both enrichment serology methods was about 92–99.4%. Sensitivity of Micromethod was better than that of the Macromethod for the environmental samples (86.8 and 74.1%, respectively) and the poultry meat samples (87.5 and 77.5%, respectively) but was the same for the nonfat dry milk samples (82.5%). the costs of both methods were respectively 0.43 US $ for the Macromethod and 0.20 US $ for the Micromethod. This "Micromethod" could be proposed for the screening of Salmonella positive batches in the food industries.     

IMAGE ANALYSIS AS A RAPID PATHOGEN DETECTION METHOD FOR USE IN POULTRY INDUSTRY

An image analysis system was developed and evaluated as a method for rapid detection of Salmonella typhimurium in pure culture and in chicken washes. A direct immunomagnetic separation and immunofluorescent staining technique was developed to capture and identify target cells. Digital images were acquired and segmented into background and bacteria. Bacteria were enumerated using a custom designed image analysis software. The image analyses results were compared with manual enumeration. A correlation coefficient of 0.78 was established between manual and image analysis counts. In addition, the difference between the manual and the image analysis bacterial counts in individual images was low. Image analysis took an average of 15 s to analyze an image. The results indicate that the proposed system has the potential to be used as a rapid screening procedure for bacterial detection in the food industry.     

USE OF THREE RAPID DETECTION SYSTEMS TO EVALUATE THE PREVALENCE AND DISSEMINATION OF SALMONELLA IN A BRAZILIAN POULTRY SLAUGHTERHOUSE

Prevalence and dissemination of Salmonella in a Brazilian poultry slaughterhouse were evaluated by three rapid detection systems (SS/SV^TM, VICAM, OSRT^TM, Unipath/Oxoid, and REVEAL^TM, Neogen), plus the conventional procedure. The carcasses were sampled after bleeding (P1), defeathering (P2), evisceration (P3), washing (P4), chilling (P5) and the packaged end-product (P6). In the first set of carcasses, the Salmonella incidence determined by the conventional method was 38.3% and 22.5% by SS/SV^TM. In the set for evaluation of OSRT^TM, the number of positive samples was the same detected by the cultural procedure (49.0%). In the third set, the positivity by the conventional procedure was 33.3%, and 5.0% by REVEAL^TM. The comparisons of positives in the first and third sets of carcasses were significantly different (P < 0.05). The positivity for Salmonella, in carcasses at P1 to P6, as determined by at least one of the methods, was 47.5%, 47.5%, 32.5%, 30.0%, 30.0% and 37.7%, respectively.     

SURVIVAL OF AN UNIRRADIATED SALMONELLA TYPHIMURIUM MARKER STRAIN INOCULATED IN POULTRY FEEDS AFTER IRRADIATION

The present study was designed to compare unirradiated Salmonella typhimurium survival during storage after inoculation in either irradiated or unirradiated poultry feed. The effects of irradiation (5 kGy) on the indigenous feed microflora and on the survival of marker strain of S. typhimurium contaminated after irradiation treatment were determined during 56 days of storage of either soybean meal (SBM) or meat and bone meal (MBM) based feeds. The initial aerobic bacterial populations were reduced more than 90% in both SBM (4.96 to 4.08 ± 0.03 log₁₀ CPU/g feed) and MBM (5.12 to 3.90 ± 0.03) by irradiation. Irradiation treatment reduced the average fungal counts during 56 days of storage in both SBM (4.24 to 2.74 ± 0.03) and MBM (4.38 to 2.15 ± 0.03) containing feeds. However, unirradiated S. typhimurium populations inoculated after irradiation of the feed were not different in either irradiated or nonirradiated SBM and MBM based feeds. Therefore, the differences in fungal versus bacterial sensitivity among the feed types and storage times suggests that gamma irradiation can alter the makeup of indigenous microbial populations in feed but this does not appear to have a discernible influence on subsequent survival of unirradiated S. typhimurium added as a dry inoculum after irradiation.     

RAPID DETECTION OF GERMINATING BACILLUS CEREUS CELLS USING FLUORESCENT IN SITU HYBRIDIZATION

Methods for the specific detection of Bacillus spores are needed in many situations such as the recognition of food poisoning. This study presents an experimental design in order to find the best combination of germination conditions leading to a rapid and detectable fluorescent in situ hybridization (FISH) signal from Bacillus cereus spores present in pure cultures and milk samples.
B. cereus ATCC 14579 and HER 1414 were incubated in 20 different growth media by using a combination of various germinants such as sugars, amino acids and dipicolinic acid. Also, three different germination factors were tested: incubation temperature, inoculum concentration and a heat shock treatment. Permeabilization procedure and hybridization time were optimized on the best germination condition found. B. cereus -specific FISH probes were validated under the optimized condition and in detection of spiked B. cereus spores in 1% ultra heat-treated milk samples. FISH-labeled cells were detected by using flow cytometry, and the results were confirmed by fluorescence microscopy. The optimal condition allows the detection of B. cereus spores in less than 2 h. Overall, a ninefold reduction in total time for detection was achieved when comparing with previous works. Therefore, the permeabilization and hybridization optimizations mentioned in this study are major improvements for the detection time of B. cereus spores.

PRACTICAL APPLICATIONS

By using the optimized conditions of germination/outgrowth, permeabilization and hybridization, the detection of 10³ cfu/mL of Bacillus cereus spores using fluorescent in situ hybridization is possible within 2 h in milk sample.     

RAPID PURIFICATION OF SALMONELLA DNA IN MINCED MEAT AND DETECTION BY REAL-TIME PCR

Four rapid and simple DNA purification and sample treatment protocols were evaluated for detection of Salmonella enterica in spiked minced meat, using a fluorogenic 5'nuclease (TaqMan) PCR assay in an ABI-Prism 7700 Sequence Detector. The detection limit with the single separation treatment of DNeasy was found to be 6–8 CFU in just 19 end-point fluorescence (C_t) values, while this was 22 C_t for a combination of DNeasy and BactXtractor. Extraction by DNeasy resulted in C_t <22, indicating a detection limit of <10 Salmonella cells per 25g, when the samples were inoculated with Salmonella before the overnight preenrichment. The method is currently being adapted to a BioRobot 3000 platform. However, the use of paramagnetic beads (DNA Direct) resulted in poor and variable detection limit.     

RAPID SCREENING FOR SALMONELLA IN FISHMEAL BY ENRICHMENT-IMMUNOASSAY

We previously described an enrichment-immunoassay utilizing a T6 monoclonal antibody capture enzyme-linked immunosorbent assay. Here we evaluated it for the rapid screening for Salmonella in fishmeal obtained from the national Animal and Plant Quarantine service in the People's Republic of China. In this method, the number of Salmonella present is first expanded by appropriate enrichment cultures, and the pathogens are then directly detected by the T6 immunoassay. In a total of 94 enrichment cultures of fishmeal, we obtained an overall concordance of 98% between the results obtained in parallel by this method and by conventional test method. The positive prediction by this method was 92% and the negative prediction was 100%. The turn around time for the new test was 27 h which is a significant improvement from the turn around time exceeding 96 h required for the conventional test method. This test proved to be compatible with the routine work flow in the practical setting of a quarantine laboratory.     

鼠伤寒沙门氏菌噬菌体型的相变异

经过反复检查1980～1993年间在新疆维吾尔自治区各地收集的鼠伤寒沙门氏菌(Salmonella typhimurium)菌株,发现了鼠伤寒沙门氏菌噬菌体型的相变异(phase variation)。在4774或4776噬菌体型(完全型)的培养物中,有一小部分可以发生变异,有的变为4000(第1相),有的变为0776或0774(第2相)。这种4000和0776(0774)噬菌体型培养物的多数,容易发生回复变异,变为原来的噬菌体型4774(或4776);有时,4000噬菌体型(第1相)可以变为0776(第2相),而0774噬菌体型(第2相)也可以变为4000(第1相)。在7776噬菌体型(完全型)的培养物中,也有一小部分可以变为7000(第1相)或0776(第2相)。7000(或7002)和0776噬菌体型培养物的多数容易发生回复变异,变为原来的噬菌体型7776(或7774)。从完全型培养物变为第1相或第2相的变异率为156%,从第1相或第2相培养物变为完全型的变异率为532%。这一现象的阐明,将有助于鼠伤寒沙门氏菌的噬菌体分型,和对鼠伤寒沙门氏菌感染的流行病学分析有重要意义。     

APPLICATION OF A TRANSPOSON FOOTPRINTING TECHNIQUE FOR RAPID IDENTIFICATION OF SALMONELLA TYPHIMURIUM TN5 MUTANTS REQUIRED FOR SURVIVAL UNDER DESICCATION STRESS CONDITIONS

Salmonella spp. are one of the foodborne pathogens that can be isolated in the environments of poultry houses and desiccation is a potential stress condition that can influence the survival of Salmonella spp. in this environment. In order to investigate the desiccation survival mechanism of Salmonella spp. the genome of S. typhimurium ATCC 14028 was screened for the genes potentially required for survival during desiccation using a novel method based on Tn5 mutagenesis previously developed in our laboratory. This method, termed transposon footprinting, simultaneously amplifies the Tn5-flanking sequences in a complex pool of the Tn5 mutants. As the length of the amplified DNA fragment should be unique for each distinct Tn5 mutant, the polymerase chain reaction (PCR) products separated on an agarose gel generate transposon footprints with each band in the footprint representing the corresponding Tn5 mutant. By comparing the transposon footprints from the pools of S. typhimurium Tn5 mutants before and after exposure to desiccation, Tn5 mutants that were not recovered after the selection were rapidly identified that would be easily isolated for further genetic analysis.