The Effect Ultrasound and Surfactants on Nanobubbles Efficacy against Listeria innocua and Escherichia coli O157:H7, in Cell Suspension and on Fresh Produce Surfaces

Rafeeq, Shamil; Ovissipour, Reza

doi:10.3390/foods10092154

Cited by 7 publications

(4 citation statements)

References 25 publications

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“…This characteristic is particularly valuable for applications that require stringent environmental compliance [129]. This makes them especially suited for applications such as water treatment and sensitive bioprocesses, where chemical changes can adversely affect microbial communities [136]. Their prolonged presence and ability to improve gas availability mean that fewer external inputs are required, contributing to resource conservation and minimizing environmental impacts.…”

Section: Discussionmentioning

confidence: 99%

Use of Nanobubbles to Improve Mass Transfer in Bioprocesses

Silva,

Arias-Torres,

Carlesi

et al. 2024

Processes

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Nanobubble technology has emerged as a transformative approach in bioprocessing, significantly enhancing mass-transfer efficiency for effective microbial activity. Characterized by their nanometric size and high internal pressure, nanobubbles possess distinct properties such as prolonged stability and minimal rise velocities, allowing them to remain suspended in liquid media for extended periods. These features are particularly beneficial in bioprocesses involving aerobic strains, where they help overcome common obstacles, such as increased culture viscosity and diffusion limitations, that traditionally impede efficient mass transfer. For instance, in an experimental setup, nanobubble aeration achieved 10% higher soluble chemical oxygen demand (sCOD) removal compared to traditional aeration methods. Additionally, nanobubble-aerated systems demonstrated a 55.03% increase in caproic acid concentration when supplemented with air nanobubble water, reaching up to 15.10 g/L. These results underscore the potential of nanobubble technology for optimizing bioprocess efficiency and sustainability. This review delineates the important role of the mass-transfer coefficient (kL) in evaluating these interactions and underscores the significance of nanobubbles in improving bioprocess efficiency. The integration of nanobubble technology in bioprocessing not only improves gas exchange and substrate utilization but also bolsters microbial growth and metabolic performance. The potential of nanobubble technology to improve the mass-transfer efficiency in biotechnological applications is supported by emerging research. However, to fully leverage these benefits, it is essential to conduct further empirical studies to specifically assess their impacts on bioprocess efficacy and scalability. Such research will provide the necessary data to validate the practical applications of nanobubbles and identify any limitations that need to be addressed in industrial settings.

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Section: Discussionmentioning

confidence: 99%

Use of Nanobubbles to Improve Mass Transfer in Bioprocesses

Silva,

Arias-Torres,

Carlesi

et al. 2024

Processes

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“…A synergistic study combining pure O 2 ‐nanobubble solution followed by ultrasonication for 5–20 min against an initial count of 6–7 log CFU mL −1 E. coli O157:H7 and L. innocua on spinach leaves was performed; the treatment resulted in >6 log CFU mL −1 reduction of L. innocua after 15 min and 7 log CFU mL −1 reduction for E. coli after 10 min. Nanobubbles in combination with ultrasonication also improved bacterial removal from the surface of spinach leaves, eliminating >2 and 4 log CFU cm −2 of L. innocua and E. coli , respectively (Rafeeq & Ovissipour, 2021). Le Nguyen et al.…”

Section: Impact Of Activated Water Systems On Spoilage and Microbial ...mentioning

confidence: 99%

“…However, extreme internal pressure, temperature, and a rapid collapse are required to support adiabatic compression during MNB collapse to produce ROS. One of the most important ROS generated by oxygen and air MNB is hydroxyl radicals (Rafeeq & Ovissipour, 2021). However, it is still unknown whether MNB‐derived hydroxyl radicals can be produced without applying mechanical and ultrasonic agitation or by lowering pH of the solution (Takahashi et al., 2021; Yasui et al., 2018).…”

Section: Chemical Pathways Of Activated Water Systemsmentioning

confidence: 99%

Recent advances in activated water systems for the postharvest management of quality and safety of fresh fruits and vegetables

Malahlela,

Belay,

Mphahlele

et al. 2024

Comp Rev Food Sci Food Safe

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Over the last three decades, decontamination management of fresh fruits and vegetables (FFVs) in the packhouses and along the supply chains has been heavily dependent on chemical‐based wash. This has resulted in the emergence of resistant foodborne pathogens and often the deposition of disinfectant byproducts on FFVs, rendering them unacceptable to consumers. The management of foodborne pathogens, microbial contaminants, and quality of FFVs are a major concern for the horticultural industries and public health. Activated water systems (AWS), such as electrolyzed water, plasma‐activated water, and micro–nano bubbles, have gained significant attention from researchers over the last decade due to their nonthermal and nontoxic mode of action for microbial inactivation and preservation of FFVs quality. The aim of this review is to provide a comprehensive summary of recent progress on the application of AWS and their effects on quality attributes and microbial safety of FFVs. An overview of the different types of AWS and their properties is provided. Furthermore, the review highlights the chemistry behind generation of reactive species and the impact of AWS on the quality attributes of FFVs and on the inactivation/reduction of spoilage and pathogenic microbes (in vivo or in vitro). The mechanisms of action of microorganism inactivation are discussed. Finally, this work highlights challenges and limitations for commercialization and safety and regulation issues of AWS. The synergistic prospect on combining AWS for maximum microorganism inactivation effectiveness is also considered. AWS offers a potential alternative as nonchemical interventions to maintain quality attributes, inactivate spoilage and pathogenic microorganisms, and extend the shelf‐life for FFVs.

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“…Several studies have demonstrated the potential of power ultrasound alone or combined with antimicrobial compounds such as chorine, PAA, or organic acids to reduce the bacteria load on the fresh produce surfaces [13,[16][17][18][19][20]. However, many of the studies evaluated washing conditions that were not practical for industry use (e.g., long treatment times).…”

Section: Introductionmentioning

confidence: 99%

Efficacy of Power Ultrasound-Based Hurdle Technology on the Reduction of Bacterial Pathogens on Fresh Produce

Zhou,

Salazar,

Fay

et al. 2023

Foods

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Minimally processed produce is frequently contaminated with foodborne bacterial pathogens. Power ultrasound is a non-thermal and cost-effective technology that can be combined with other chemical sanitization methods. This study investigated the reduction of Listeria monocytogenes and Salmonella Newport on grape tomato, romaine lettuce, and spinach washed with water, chlorine, or peroxyacetic acid alone or in combination with 25 or 40 kHz power ultrasound for 1, 2, or 5 min. Produce items were inoculated with either pathogen at 10 log CFU/g, dried for 2 h, and treated. Combined treatment of ultrasound and sanitizers resulted in 1.44–3.99 log CFU/g reduction of L. monocytogenes and 1.35–3.62 log CFU/g reduction of S. Newport, with significantly higher reductions observed on grape tomato. Synergistic effects were achieved with the hurdle treatment of power ultrasound coupled with the chemical sanitizers when compared to the single treatments; an additional 0.48–1.40 log CFU/g reduction of S. Newport was obtained with the addition of power ultrasound on grape tomato. In general, no significant differences were observed in pathogen reductions between the ultrasound frequencies, the sanitizers, or the treatment lengths. Results from this study suggest that incorporation of power ultrasound into the current washing procedure may be beneficial for the reduction, but not elimination, of bacterial pathogens on certain produce items, including tomatoes.

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The Effect Ultrasound and Surfactants on Nanobubbles Efficacy against Listeria innocua and Escherichia coli O157:H7, in Cell Suspension and on Fresh Produce Surfaces

Cited by 7 publications

References 25 publications

Use of Nanobubbles to Improve Mass Transfer in Bioprocesses

Use of Nanobubbles to Improve Mass Transfer in Bioprocesses

Recent advances in activated water systems for the postharvest management of quality and safety of fresh fruits and vegetables

Efficacy of Power Ultrasound-Based Hurdle Technology on the Reduction of Bacterial Pathogens on Fresh Produce

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