Effects of High-Pressure Treatment on Spores of Clostridium Species

Doona, Christopher J.; Feeherry, Florence E.; Setlow, Barbara; Wang, Shiwei; Nichols, Frank C.; Talukdar, Prabhat K.; Sarker, Mahfuzur R.; Li, Yongqing; Shen, Aimee; Setlow, Peter

doi:10.1128/aem.01363-16

Cited by 36 publications

(36 citation statements)

References 51 publications

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“…However, with spores of at least Clostridioides difficile , CaDPA release does not trigger completion of spore germination, although the CaDPA‐less spores have a higher core water content and are less wet heat resistant than dormant spores (Doona et al . 2016; Setlow et al . 2017).…”

Section: Introductionmentioning

confidence: 99%

Killing of bacterial spores by dodecylamine and its effects on spore inner membrane properties

et al. 2020

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Aims The objective of this study was to determine the effects of Ca‐dipicolinic acid (CaDPA), cortex‐lytic enzymes (CLEs), the inner membrane (IM) CaDPA channel and coat on spore killing by dodecylamine. Methods and Results Bacillus subtilis spores, wild‐type, CaDPA‐less due to the absence of DPA synthase or the IM CaDPA channel, or lacking CLEs, were dodecylamine‐treated and spore viability and vital staining were all determined. Dodecylamine killed intact wild‐type and CaDPA‐less B. subtilis spores similarly, and also killed intact Clostridiodes difficile spores ± CaDPA, with up to 99% killing with 1 mol l−1 dodecylamine in 4 h at 45°C with spores at ~108 ml−1. Dodecylamine killing of decoated wild type and CLE‐less B. subtilis spores was similar, but ~twofold faster than for intact spores, and much faster for decoated CaDPA‐less spores, with ≥99% killing in 5 min. Propidium iodide stained intact spores ± CaDPA minimally, decoated CaDPA‐replete spores or dodecylamine‐killed CLE‐less spores peripherally, and cores of decoated CaDPA‐less spores and dodecylamine‐killed intact spores with CLEs. The IM of some decoated CaDPA‐less spores was greatly reorganized. Conclusions Dodecylamine spore killing does not require CaDPA channels, CaDPA or CLEs. The lack of CaDPA in decoated spores allowed strong PI staining of the spore core, indicating loss of these spores IM permeability barrier. Significance and Impact of the Study This work gives new information on killing bacterial spores by dodecylamine, and how spore IM’s relative impermeability is maintained.

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Section: Introductionmentioning

confidence: 99%

Killing of bacterial spores by dodecylamine and its effects on spore inner membrane properties

et al. 2020

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“…Under these conditions the main inactivation force is the temperature (Reineke et al., ; Sevenich et al., ). Recently, the differences in germination under pressure between Clostridium spores and Bacillus spores have been revealed, showing interesting insights (Figure ; Doona et al., ; Lenz & Vogel, ; Paredes‐Sabja, Setlow, & Sarker, ). In Bacillus spp ., DPA release triggers cortex lytic enzyme (CLE) activation; CLE action is not essential for DPA release, but it can accelerate it.…”

Section: State Of the Artmentioning

confidence: 99%

“…In Clostridium difficile or Clostridium perfringens Doona et al. () observed that the inactivation mechanism differs in comparison to Bacillus species. For the tested strains the initiation of cortex hydrolysis by SleC precedes and triggers DPA release.…”

Section: State Of the Artmentioning

confidence: 99%

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Continuous Versus Discontinuous Ultra‐High‐Pressure Systems for Food Sterilization with Focus on Ultra‐High‐Pressure Homogenization and High‐Pressure Thermal Sterilization: A Review

Sevenich

Mathys

2018

Comp Rev Food Sci Food Safe

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High-pressure thermal sterilization (HPTS) and ultra-high-pressure homogenization (UHPH) are two emerging sterilization techniques that have not been implemented in the food industry yet. The two technologies apply different acting principles as HPTS uses isostatic pressure in combination with heat whereas UHPH uses dynamic pressure in combination with shear stress, cavitation, impingement, and heat. Both technologies offer significant benefits in terms of spore inactivation in food production with reduced thermal intensity and minimized effects on sensory and nutritional profiles. These benefits have resulted in relevant research efforts on both technologies over the past few decades. This state of the art of the discontinuous HPTS-based and the continuous UHPH-based sterilization concepts are assessed within this review. Further, various basic principles and promising future preservation applications of HPTS and UHPH for food processing, that are also applicable in the pharmaceutical, biochemical, and biotechnological sectors, are summarized. In addition, the applications and limitations of these technologies in terms of optimizations needed to overcome the identified challenges are emphasized.

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“…Therefore, they reported that heating of food to temperatures above 85 C would be necessary to inactivate viable spores of C. difficile. More recently, Redondo-Solano, Burson, and Thippareddi (2016) reported much higher thermal resistance for three hypervirulent and one nonvirulent strains of C. difficile spores ranging from 22.14 h at 70 C to 4.93 min at 70 to 90 C. Microwave heating (Malyshev, Williams, Lees, Baillie, & Porch, 2019;Ojha et al, 2016), high pressure treatment (Doona et al, 2016), and use of electrolyzed water (Tkhawkho, Jackson, Nitzan, & Peretz, 2017) have also been proposed for destruction of C. difficile spores.…”

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confidence: 99%

Evaluation of thermal destruction kinetics of Clostridium difficile spores (ATCC 17857) in lean ground beef with first‐order/Weibull modeling considerations

Arora

Oudit

Austin

et al. 2019

J Food Process Engineering

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Thermal destruction kinetics of spores of Clostridium difficile ATCC 17857 was evaluated between 74 and 82°C and characterized using the first‐order log‐linear and Weibull models. Computed decimal reduction times using the first‐order model ranged from 4.39 min at 82°C to 146 min at 74°C, with a z value of 5.17°C. Thermal destruction data were also analyzed using the Weibull model. Based on regression, the predicted one‐D value (first‐order model) and the reliable life (tR) (Weibull model) were 3.86 and 4.05 min at 82°C and 136 and 165 min at 74°C, respectively, indicating the Weibull model to be more conservative yielding higher decimal reduction time values. However, when extended to achieve 2.5, 4, and 6 decimal reductions in C. difficile spores, the calculated process times were more conservative with the first‐order model than with the Weibull model. Moreover, within the experimental range, when data for both models could be compared, predictions from the first‐order model were much closer to the experimental values. Therefore, when used for process calculation for 2.5 or higher log reductions, the first‐order model would give more conservative and safer process times. The study provides destruction kinetics data for C. difficile under a range of temperature conditions. Practical Applications Clostridium difficile is a major cause of antibiotic‐associated diarrhea and pseudomembranous colitis in humans. C. difficile infection is the leading cause of gastroenteritis‐associated death. C. difficile infections have been increasing in recent years, and therefore warrant appropriate remedial measures. Thermal inactivation is the most common method for pathogen control, and often the cooking practices are adjusted to a level pre‐established to make the foods pathogen free. Available information on thermal destruction kinetics is scarce, and therefore the data generated here should be of significant importance for safety considerations.

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Effects of High-Pressure Treatment on Spores of Clostridium Species

Cited by 36 publications

References 51 publications

Killing of bacterial spores by dodecylamine and its effects on spore inner membrane properties

Killing of bacterial spores by dodecylamine and its effects on spore inner membrane properties

Continuous Versus Discontinuous Ultra‐High‐Pressure Systems for Food Sterilization with Focus on Ultra‐High‐Pressure Homogenization and High‐Pressure Thermal Sterilization: A Review

Evaluation of thermal destruction kinetics of Clostridium difficile spores (ATCC 17857) in lean ground beef with first‐order/Weibull modeling considerations

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