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1	Developments in the Mutant Prevention Concentration: A Novel Approach to Antimicrobial Susceptibility/Resistance Issues Hesje, Christine Karen 19 November 2008 The mutant prevention concentration (MPC) is defined as the lowest antimicrobial concentration required to inhibit the growth of the least susceptible bacterial cell based on an inoculum of ≥109 colony forming units (CFUs). The current protocol for MPC testing is technically demanding and time-consuming which limits its implementation into clinical microbiology laboratories. In an attempt to simplify the current MPC protocol we developed a modified MPC method, the microbroth dilution method, which requires two fewer days to complete than the current or traditional method. MPC values were consistent for all organisms and strains tested using both the traditional MPC method and the modified microbroth dilution MPC method.<p> Tigecycline is the first of a new class of compound glycylcyclines- with potent in vitro activity against Gram-positive organisms including penicillin-resistant and multi-drug resistant <i>Streptococcus pneumoniae</i> (SP) and methicillin-resistant <i>Staphylococcus aureus</i> (MRSA). We measured minimum inhibitory concentration (MIC) and MPC values for tigecycline against 47 clinical isolates of SP and found that the MPC90 values were >500 fold higher than the MIC90 values. To determine if MPC testing of tigecycline against SP is impacted by blood in the medium, we developed a new medium able to sustain the growth of SP without the need for blood; solidified Todd-Hewitt broth (sTHB). The MPC90 values of tigecycline against SP on sTHB were only 2 fold higher than the MIC90 values. When blood was added to the sTHB, the MPC90 values again became much greater than the MIC90 values (> 256 fold higher). MPC results for <i>Staphylococcus spp.</i> against tigecycline were not impacted by blood in the medium.<p> Benzalkonium chloride (BAK) is a cationic surface-acting agent that acts on bacterial cells by disrupting the intermolecular interaction of the lipid bilayer. To determine if the <i>fluoroquinolones gatifloxacin</i> (Gfx) and moxifloxacin (Mfx) are more active (lower MIC values) in the presence of BAK, we conducted MIC, MPC, and time-kill assays. MIC testing showed that in the presence of 3.125 to 50 µg/ml of BAK, the MIC of Gfx and Mfx decreased by 8- to 5000-fold against clinical isolates of methicillin-susceptible <i>Staphylococcus aureus</i> (MSSA), MRSA, Coagulase-negative <i>Staphylococci</i>(CNS), SP, <i>Escherichia coli</i> (EC), and <i>Pseudomonas aeruginosa</i> (PA). MPC testing showed that the presence of 7 to 10 µg/ml of BAK, the MPC of Gfx and Mfx decreased by 32- to 1000-fold against clinical isolates of MRSA. Conventional time-kill studies (using a bacterial load of 105 CFUs) showed that the killing activity of Gfx against clinical MRSA isolates was enhanced in the presence of BAK with a log10-reduction (percent kill) of 1.6 (76.08%) for Gfx alone at 180 minutes compared to a log10-redecution (percent kill) of 5.4 (100%) for Gfx plus BAK at 180 minutes.<p> Alexidine (Alx) is a bisbiguanide that has been used as an effective disinfectant in the dental industry and is potentially being developed for use as an antimicrobial agent for ocular infections. We conducted susceptibility testing of Alx using MIC testing, MPC testing, and time-kill assays against Gram-positive and Gram-negative pathogens. MIC testing showed that Alx is more active against Gram-positive pathogens than Gram-negative pathogens and showed better activity than the fluoroquinolones Gfx, Mfx, and levofloxacin (Lfx) against MRSA. The MPC values measured for MRSA and MSSA against Alx were non-reproducible using the traditional MPC method. Using the microbroth dilution MPC method, MPC90 values were found to be 32 fold higher than the MIC90 values. If the experimentally determined MPC values are true MPC values, initial MPC testing indicates that Alx may have a high likelihood for selecting for resistance, however, if the MPC values are not accurate it may be necessary to modify the MPC protocol in order to complete MPC testing of Alx against MRSA and MSSA. Conventional time-kill studies (using a bacterial load of 105 CFUs) measured bactericidal activity (> 3 log10-reduction) against MRSA, MSSA, SP, and PA. Mutant Prevention Concentration Alexidine Benzalkonium chloride Tigecycline Antimicrobial Resistance
2	Developments in the Mutant Prevention Concentration: A Novel Approach to Antimicrobial Susceptibility/Resistance Issues Hesje, Christine Karen 19 November 2008 (has links) The mutant prevention concentration (MPC) is defined as the lowest antimicrobial concentration required to inhibit the growth of the least susceptible bacterial cell based on an inoculum of ≥109 colony forming units (CFUs). The current protocol for MPC testing is technically demanding and time-consuming which limits its implementation into clinical microbiology laboratories. In an attempt to simplify the current MPC protocol we developed a modified MPC method, the microbroth dilution method, which requires two fewer days to complete than the current or traditional method. MPC values were consistent for all organisms and strains tested using both the traditional MPC method and the modified microbroth dilution MPC method.<p> Tigecycline is the first of a new class of compound glycylcyclines- with potent in vitro activity against Gram-positive organisms including penicillin-resistant and multi-drug resistant <i>Streptococcus pneumoniae</i> (SP) and methicillin-resistant <i>Staphylococcus aureus</i> (MRSA). We measured minimum inhibitory concentration (MIC) and MPC values for tigecycline against 47 clinical isolates of SP and found that the MPC90 values were >500 fold higher than the MIC90 values. To determine if MPC testing of tigecycline against SP is impacted by blood in the medium, we developed a new medium able to sustain the growth of SP without the need for blood; solidified Todd-Hewitt broth (sTHB). The MPC90 values of tigecycline against SP on sTHB were only 2 fold higher than the MIC90 values. When blood was added to the sTHB, the MPC90 values again became much greater than the MIC90 values (> 256 fold higher). MPC results for <i>Staphylococcus spp.</i> against tigecycline were not impacted by blood in the medium.<p> Benzalkonium chloride (BAK) is a cationic surface-acting agent that acts on bacterial cells by disrupting the intermolecular interaction of the lipid bilayer. To determine if the <i>fluoroquinolones gatifloxacin</i> (Gfx) and moxifloxacin (Mfx) are more active (lower MIC values) in the presence of BAK, we conducted MIC, MPC, and time-kill assays. MIC testing showed that in the presence of 3.125 to 50 µg/ml of BAK, the MIC of Gfx and Mfx decreased by 8- to 5000-fold against clinical isolates of methicillin-susceptible <i>Staphylococcus aureus</i> (MSSA), MRSA, Coagulase-negative <i>Staphylococci</i>(CNS), SP, <i>Escherichia coli</i> (EC), and <i>Pseudomonas aeruginosa</i> (PA). MPC testing showed that the presence of 7 to 10 µg/ml of BAK, the MPC of Gfx and Mfx decreased by 32- to 1000-fold against clinical isolates of MRSA. Conventional time-kill studies (using a bacterial load of 105 CFUs) showed that the killing activity of Gfx against clinical MRSA isolates was enhanced in the presence of BAK with a log10-reduction (percent kill) of 1.6 (76.08%) for Gfx alone at 180 minutes compared to a log10-redecution (percent kill) of 5.4 (100%) for Gfx plus BAK at 180 minutes.<p> Alexidine (Alx) is a bisbiguanide that has been used as an effective disinfectant in the dental industry and is potentially being developed for use as an antimicrobial agent for ocular infections. We conducted susceptibility testing of Alx using MIC testing, MPC testing, and time-kill assays against Gram-positive and Gram-negative pathogens. MIC testing showed that Alx is more active against Gram-positive pathogens than Gram-negative pathogens and showed better activity than the fluoroquinolones Gfx, Mfx, and levofloxacin (Lfx) against MRSA. The MPC values measured for MRSA and MSSA against Alx were non-reproducible using the traditional MPC method. Using the microbroth dilution MPC method, MPC90 values were found to be 32 fold higher than the MIC90 values. If the experimentally determined MPC values are true MPC values, initial MPC testing indicates that Alx may have a high likelihood for selecting for resistance, however, if the MPC values are not accurate it may be necessary to modify the MPC protocol in order to complete MPC testing of Alx against MRSA and MSSA. Conventional time-kill studies (using a bacterial load of 105 CFUs) measured bactericidal activity (> 3 log10-reduction) against MRSA, MSSA, SP, and PA. Mutant Prevention Concentration Alexidine Benzalkonium chloride Tigecycline Antimicrobial Resistance
3	Investigating pre-harvest and postharvest interventions to control foodborne pathogens and surrogates on lettuce Jenott, Jacob Robert January 1900 (has links) Master of Science / Food Science Institute / Sara E. Gragg / Leafy greens have been recognized as vehicles for transmission of foodborne pathogens and an effective pre-harvest intervention to control them is currently lacking. After harvest, lettuce is often subjected to chlorinated water to reduce the microbial load in the water and on the lettuce tissue. While moderately effective, there is also a need for improved postharvest interventions. The purpose of Objective I was to 1) determine potassium bisulfate efficacy at reducing populations of Escherichia coli (E. coli) and Listeria innocua (L. innocua) when applied pre-harvest to lettuce, and 2) assess the impact on product quality at harvest. Potassium bisulfate reduced E. coli populations on inoculated lettuce by 1.32 log₁₀ CFU/g (P=0.0002) and L. innocua by 1.18 log₁₀ CFU/g (P=0.0017). No detectable differences were observed in color (P>0.05); however, brown spots were observed on various leaves sprayed with potassium bisulfate. The purpose of Objective II was to employ a blend of benzalkonium chloride, acetic acid, and methyl paraben (BAM) as a postharvest wash on romaine and iceberg lettuce and to 1) determine efficacy at reducing populations of Listeria monocytogenes (L. monocytogenes), E. coli O157:H7 and Salmonella, 2) measure changes in aerobic bacteria throughout the shelf life, and 3) quantify benzalkonium chloride and methyl paraben residues post-washing. To quantify efficacy of BAM reducing pathogenic bacterial populations, fresh-cut romaine and iceberg lettuce were inoculated with L. monocytogenes, E. coli O157:H7, or Salmonella and washed in BAM at concentrations of 0%, 1%, 2% or 3% for one or five minutes. When plated on recovery media, contact time and wash concentration was not significant (P>0.05) for Salmonella on either product. Concentration was significant (P=0.0189) for L. monocytogenes on romaine; however, the greatest reduction observed was <1.0 log₁₀ CFU/g. The 3% wash significantly reduced E. coli O157:H7 on romaine by 1.75 log₁₀ CFU/g, which is 0.66 log₁₀ CFU/g better than the 0% wash. Following washing, wash water was analyzed and data demonstrate that all wash concentrations significantly (P≤0.05) reduced each foodborne pathogen by >2.0 log₁₀ CFU/g in the wash water. To quantify benzalkonium chloride and methyl paraben residues, as well as changes in aerobic bacteria and product quality, fresh-cut romaine and iceberg lettuce were subjected to a 1 minute wash in BAM at concentrations of 0%, 1%, 2%, or 3% and immediately sampled to determine aerobic populations and product quality. Concentrations 0% and 2% were also packaged into retail storage bags and sampled on days 0, 3, 5, and 7. Residues were quantified on these days as well. On day 0, aerobic populations did not vary according to wash concentration (P>0.05). With regards to shelf-life data, the 2% wash significantly reduced (P=0.0203) aerobic bacteria on romaine lettuce; however, no significant difference was observed on iceberg lettuce (P=0.0819). With regards to overall visual appearance of romaine or iceberg lettuce, no significant difference was detected between 0% and 2% BAM washes for each day throughout the shelf-life study (P>0.05). Methyl paraben and benzalkonium chloride residues were <5.0 and <10.0 ppm, respectively, on both products on each sampling day. Pre-harvest Postharvest Lettuce Potassium bisulfate Benzalkonium chloride
4	Adaptive responses of salmonella enterica serovar enteritidis ATCC 4931 biofilms to nutrient laminar flow and benzalkonium chloride treatment Illathu, Anilkumar Mangalappalli 12 December 2007 <i>Salmonella enterica serovar Enteritidis</i> is an important biofilm-forming food-borne pathogen. This study examined the adaptive responses of <i>Salmonella serovar Enteritidis</i> biofilms to different environmental conditions such as flow velocity and benzalkonium chloride (BC) treatment. The influence of a 10-fold difference in nutrient laminar flow velocity on the dynamics of biofilm formation and protein expression profiles was compared. The mode of development and architecture of low-flow and high-flow biofilms were distinct. Exopolymer composition of the two biofilms was also different. However, no major shift in protein expression was seen between the biofilms, nor were there any stress response proteins involved. The biofilms altered their architecture in response to flow, presumably assuming a structure that minimized overall biofilm stress. An empirically-determined shear-inducing flow was applied on high-flow biofilms, fractionating the biofilms into shearable and non-shearable regions. Length:width indices of cells from the two biofilm regions, as well as planktonic cells from biofilm effluent and continuous culture were determined to be 3.2, 2.3, 2.2, and 1.7, respectively. Expression of proteins involved in cold-shock response, adaptation, and broad regulatory functions in the shearable region, and expression of protein involved in heat-shock response and chaperonin function in the non-shearable region indicated that the physiological status of cells in two biofilm regions was also distinct. The development of biofilm adaptive resistance to BC was then examined. Adapted biofilms survived a lethal BC challenge and re-grew, whereas unadapted biofilms did not. Proteins up-regulated following adaptation included those involved in energy metabolism, amino acid and protein biosynthesis, nutrient-transportation, adaptation, detoxification, and 1,2-propanediol degradation. A putative universal stress protein was also up-regulated. Cold-shock response, stress response, and detoxification are suggested to play roles in adaptive resistance to BC. Functional differences in adaptive response and survival of plankonic and biofilm cells adapted to BC were also studied. The proportion of BC-adapted biofilm cells that survived a lethal BC exposure and heat-shock was significantly higher than that of BC-adapted planktonic cells. Enhanced biofilm-specific up-regulation of various proteins, coupled with alterations in cell surface roughness and shift in fatty acid composition are proposed to function in the enhanced survival of BC-adapted biofilm cells, relative to BC-adapted planktonic cells.<p>It is concluded that biofilms adapt to the stress conditions by means of community, cellular, and sub-cellular level responses. These adaptive responses help the biofilms to enhance their ability for survival in the nature, especially those formed in critical environments such as healthcare facilities, the food industry, and households. Benzalkonium chloride Proteomics Adaptive responses Biofilms Salmonella serovar Enteritidis Microscopy Nutrient laminar flow
5	Adaptive responses of salmonella enterica serovar enteritidis ATCC 4931 biofilms to nutrient laminar flow and benzalkonium chloride treatment Illathu, Anilkumar Mangalappalli 12 December 2007 (has links) <i>Salmonella enterica serovar Enteritidis</i> is an important biofilm-forming food-borne pathogen. This study examined the adaptive responses of <i>Salmonella serovar Enteritidis</i> biofilms to different environmental conditions such as flow velocity and benzalkonium chloride (BC) treatment. The influence of a 10-fold difference in nutrient laminar flow velocity on the dynamics of biofilm formation and protein expression profiles was compared. The mode of development and architecture of low-flow and high-flow biofilms were distinct. Exopolymer composition of the two biofilms was also different. However, no major shift in protein expression was seen between the biofilms, nor were there any stress response proteins involved. The biofilms altered their architecture in response to flow, presumably assuming a structure that minimized overall biofilm stress. An empirically-determined shear-inducing flow was applied on high-flow biofilms, fractionating the biofilms into shearable and non-shearable regions. Length:width indices of cells from the two biofilm regions, as well as planktonic cells from biofilm effluent and continuous culture were determined to be 3.2, 2.3, 2.2, and 1.7, respectively. Expression of proteins involved in cold-shock response, adaptation, and broad regulatory functions in the shearable region, and expression of protein involved in heat-shock response and chaperonin function in the non-shearable region indicated that the physiological status of cells in two biofilm regions was also distinct. The development of biofilm adaptive resistance to BC was then examined. Adapted biofilms survived a lethal BC challenge and re-grew, whereas unadapted biofilms did not. Proteins up-regulated following adaptation included those involved in energy metabolism, amino acid and protein biosynthesis, nutrient-transportation, adaptation, detoxification, and 1,2-propanediol degradation. A putative universal stress protein was also up-regulated. Cold-shock response, stress response, and detoxification are suggested to play roles in adaptive resistance to BC. Functional differences in adaptive response and survival of plankonic and biofilm cells adapted to BC were also studied. The proportion of BC-adapted biofilm cells that survived a lethal BC exposure and heat-shock was significantly higher than that of BC-adapted planktonic cells. Enhanced biofilm-specific up-regulation of various proteins, coupled with alterations in cell surface roughness and shift in fatty acid composition are proposed to function in the enhanced survival of BC-adapted biofilm cells, relative to BC-adapted planktonic cells.<p>It is concluded that biofilms adapt to the stress conditions by means of community, cellular, and sub-cellular level responses. These adaptive responses help the biofilms to enhance their ability for survival in the nature, especially those formed in critical environments such as healthcare facilities, the food industry, and households. Benzalkonium chloride Proteomics Adaptive responses Biofilms Salmonella serovar Enteritidis Microscopy Nutrient laminar flow
6	Fate and effect of quaternary ammonium antimicrobial compounds on biological nitrogen removal within high-strength wastewater treatment systems Hajaya, Malek Ghaleb 20 May 2011 (has links) High strength wastewater (HSWW) generated in food processing industries is characterized by high organic carbon and nitrogen content, and thus high oxygen demand. Biological nitrogen removal (BNR) is a technology widely used for the treatment of HSWW. Food processing facilities practice sanitation to keep food contact surfaces clean and pathogen-free. Benzalkonium chlorides (BACs) are cationic quaternary ammonium antimicrobial compounds (QACs) common in industrial antimicrobial formulations. BAC-bearing wastewater generated during sanitation applications in food processing facilities is combined with other wastewater streams and typically treated in BNR systems. The poor selectivity and target specificity of the antimicrobial BACs negatively impact the performance of BNR systems due to the susceptibility of BNR microbial populations to BAC. Objectives of the research were: a) assessment and quantification of the inhibitory effect of QACs on the microbial groups, which mediate BNR in HSWW treatment systems while treating QAC-bearing HSWW; b) evaluation of the degree and extent of the contribution of QAC adsorption, inhibition, and biotransformation on the fate and effect of QACs in BNR systems. A laboratory-scale, multi-stage BNR system was continuously fed with real poultry processing wastewater amended with a mixture of three benzalkonium chlorides. The nitrogen removal efficiency initially deteriorated at a BAC feed concentration of 5 mg/L due to complete inhibition of nitrification. However, the system recovered after 27 days of operation achieving high nitrogen removal efficiency, even after the feed BAC concentration was stepwise increased up to120 mg/L. Batch assays performed using the mixed liquors of the BNR system reactors, before, during, and post BAC exposure, showed that the development of BAC biotransformation capacity and the acquisition of resistance to BAC contributed to the recovery of nitrification and nitrogen removal. Kinetic analysis based on sub-models representing BNR processes showed that BAC inhibition of denitrification and nitrification is correlated with BAC liquid-phase and solid-phase concentrations, respectively. Simulations using a comprehensive mathematical BNR model developed for this research showed that BAC degradation and the level of nitrification inhibition by BAC were dynamic brought about by acclimation and enrichment of the heterotrophic and nitrifying microbial populations, respectively. The fate and effect of BACs in the BNR system were accurately described when the interactions between adsorption, inhibition, and resistance/biotransformation were considered within the conditions prevailing in each reactor. This work is the first study on the fate and effect of antimicrobial QACs in a continuous-flow, multi-stage BNR system, and the first study to quantify and report parameter values related to BAC inhibition of nitrification and denitrification. Results of this study enable the rational design and operation of BNR systems for the efficient treatment of QAC-bearing wastewater. The outcome of this research provides information presently lacking, supporting the continuous use of QACs as antimicrobial agents in food processing facilities, when and where needed, while avoiding any negative impacts on biological treatment systems and the environment. Inhibition Modeling Nitrification Benzalkonium chloride Biological nitrogen removal Quaternary ammonium compounds
7	Benzalkonio ir metenamino analogų antimikrobinio aktyvumo nustatymas in vitro ir jo priklausomybė nuo aerozolio dalelių krūvio / Establishment of benzalkonium and methenamine analoques antimicrobic activity in vitro and its dependency upon the electrical charge of the particles in the aerosol Grigonis, Aidas 14 February 2007 (has links) Antibacterial effectiveness in vitro of the original quaternary ammonium compounds that were synthesized in the Laboratory of Biologically active substances was determined and the dependence of this activity upon chemical structure of the compound was established. Also generalisations have been made concerning the regularity of this dependency, the effectiveness of the compounds was compared to benzalkonium chloride, their advantages and disadvantages were discussed. Acute toxicity of the most effective compound was established and compared to that of benzalkonium chloride. It was found that these compounds showed good antibacterial activity against Gr+ and Gr- bacteria and low toxicity, thus this original data was summarized in the patent Nr. 4712. For the first time it was found that upon disintegration of quaternary methenamonium compounds new quaternary ammonium compounds, aldehydes and ammonia are produced. The first two of the three show further antimicrobic activity. Using quaternary ammonium salts and cholrhexydine a biocide for disinfection was created. The created biocide was tested for effectiveness when used for disinfection of air in the premises, horizontal and vertical surfaces. The compound was used in the form of aerosols and electro-aerosols. The research data showed that strong concentrations of Dezinfektas IV are necessary (up to 30%), but small amount of the solution per volume is enough (20-30 ml/m3). Ten times higher concentration is needed for... [to full text] Veterinary Medicine U-77 Benzalkonium chloride Ketvirtiniai amonio junginiai Dezinfektas Quaternary ammonium compounds Benzalkonio chloridas
8	Metagenomic and metatranscriptomic investigation of microorganisms exposed to benzalkonium chloride disinfectants Oh, Seung Dae 12 January 2015 (has links) Benzalkonium chlorides (BACs) are widely used, broad-spectrum disinfectants and frequently detected in the environment, even at toxic levels for life. Since such disinfectants can induce broad resistance capabilities, BACs may fuel the emergence of antibiotic resistance in the environment. A substantial body of literature has reported that exposure to BACs causes antibiotic resistance; yet, other studies suggest that the resistance linkage is rare, unsystematic, and/or clinically insignificant. Accordingly, whether or not disinfectant exposure mediates antibiotic resistance and, if so, what molecular mechanisms underlie the resistance link remains to be clearly elucidated. Further, understanding how microbial communities degrade BACs is important not only for alleviating the possible occurrence of antibiotic resistance but also reducing the potential risks to environmental and public health. An integrated strategy that combines metagenomics, metatranscriptomics, genetics, and traditional culture-dependent approaches was employed to provide novel insights into these issues. The integrative approach showed that a microbial community exposed to BACs can acquire antibiotic resistance through two mechanisms: i) horizontal transfer of previously uncharacterized efflux pump genes conferring resistance to BACs and antibiotics, which were encoded on a conjugative plasmid and co-selected together upon BACs and ii) selective enrichment of intrinsically multi-drug resistant organisms. Further, a microbial community adapts to BAC exposure via a variety of mechanisms, including selective enrichment of BAC-degrading species and amino acid substitutions and horizontal transfer of genes related to BAC resistance and degradation. The metatranscriptomic data suggests that the BAC-adapted microbial community metabolized BACs by cooperative interactions among its members. More specifically, Pseudomonas nitroreducens cleaved (i.e., dealkylated) BACs, metabolized the alkyl chain (the dealkylated product of BACs), and released benzyldimethylamine (the other product of BACs), which was further metabolized by other community members (e.g., Pseudomonas putida). Collectively, this study demonstrates the role of BACs in promoting antibiotic resistance and advances current understanding of a microbial community degrading BACs. The results of this work have important implications for (appropriate) usage of disinfectants and for assessing, predicting, and optimizing biological engineering processes treating BAC-bearing waste streams. Benzalkonium chloride Quaternary ammonium compounds Disinfectants Antibiotic resistance Biodegradation Metagenomics Metatranscriptomics Horizontal gene transfer
9	The Evaluation of the Effect of Anionic and Cationic Surfactants on the Hindered Settling of Light Calcium Carbonate Suspensions Chalamuri, Shanmuka Harish January 2014 (has links) No description available. Pharmaceuticals Pharmacy Sciences Hindered settling light calcium carbonate calcium carbonate sodium lauryl sulfate benzalkonium chloride
10	Survival, regrowth and morphotype formation of Salmonella strains after exposure to high or low concentrations of first generation QAC in water Umutesi, Grace 09 December 2022 (has links) This study determines the differences in survival of eight Salmonella strains concentration of BAC in water, followed by regrowth in high and low nutrition conditions containing sublethal concentration of BAC. Our results show strain difference in survival, persistence of Salmonella in BAC at different concentrations. All eight strains of Salmonella were non-recoverable when exposed to 40 to 48 µg/ml BAC for 1h in water. When exposed to 24 µg/ml of BAC for 1 h in water, S. Typhimurium ATCC 14028 and S. Heidelberg ATCC 8326 cells were non-detectable from the initial 7 log CFU/ml. S. Blockley 7175, S. Virchow 7207, S. Poona 01A4242 and S. Poona 00A3208, were non-detectable after 1 h exposure at 24 µg/ml and continued to be non-detectable in 12 µg/ml BAC in both nutrient conditions after 24 h. 3/8 strains formed rugose morphotypes when exposed to BAC thus leading to understanding the role of strain differences. Salmonella benzalkonium chloride quaternary ammonium compounds sublethal and lethal concentrations tolerance and persistence Agriculture Animal Sciences Food Science Microbiology

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