Kinetics and Mechanism of Bacterial Inactivation by Ultrasound Waves and Sonoprotective Effect of Milk Components

Gera, Nimish; Doores, Stephanie

doi:10.1111/j.1750-3841.2010.02007.x

Cited by 89 publications

(38 citation statements)

References 47 publications

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“…This suggests the protective effect of food components in the LWE samples. The sonoprotective phenomena of foods (such as milk) on bacteria in comparison to buffers have been previously reported (Gera & Doores, 2011;Wrigley & Llorca, 1992;Zenker, Heinz, & Knorr, 2003). Fat content present in milk was earlier shown to reduce bacterial inactivation efficacy of ultrasound compared to fat-free milk (Bermudez-Aguirre & Barbosa-Cánovas, 2008).…”

Section: Discussionmentioning

confidence: 91%

High Intensity Ultrasound for Salmonella Enteritidis Inactivation in Culture and Liquid Whole Eggs

Techathuvanan

D’Souza

2018

Journal of Food Science

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High intensity ultrasound (HIU) continues to be researched as a nonthermal inactivation technology of appeal to food manufacturers. The advantages of HIU include maintenance of product quality, freshness, product homogenization, along with simultaneous inactivation of pathogens. Besides, it is simple, relatively inexpensive, and easily adaptable to most processing environments. This study investigated the effect of HIU for Salmonella Enteritidis inactivation in culture and liquid whole eggs (LWEs) to decrease egg-associated outbreaks. Overnight S. Enteritidis cultures and spiked LWE (both at 8 log CFU/mL) were treated with 20-kHz HIU for 0, 1, 5, 10, and 30 min (n = 6) in a temperature-controlled system, not to exceed 20 °C, and replicated thrice. At each time point, samples were enumerated on XLT4 agar and morphologically analyzed using scanning electron microscopy, with measurements of color and rheological properties. Our results revealed significant reduction of healthy S. Enteritidis cells up to 3.6 log CFU/mL and 2.3 log CFU/25 mL after HIU treatment of merely 10 min of overnight culture and 30 min in LWE, respectively (P < 0.05). After 5 and 10-min HIU treatment, significant reduction of 1.4-log CFU/25 mL healthy S. Enteritidis in LWE was obtained (P < 0.05). Even at 1-min exposure time, HIU showed significant 1.9 log CFU/mL reduction of cultures (P < 0.05); however, no log-reduction was observed in LWE after 1 min. Scanning electron micrographs showed increased cell structural damage using longer HIU exposure. For product color changes, lower redness and yellowness of LWE were observed visually and instrumentally after 5-min HIU treatment (P < 0.05). The rheological properties of LWE measured at 0 to 200 s shear rate, showed that shear stress of HIU-treated LWEs decreased after 5-min HIU exposure, but increased after 30-min treatment. This study demonstrated that HIU shows promise for rapid Salmonella control in LWE and other liquid foods, as an alternative inactivation method for use in hurdle approaches.

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Section: Discussionmentioning

confidence: 91%

High Intensity Ultrasound for Salmonella Enteritidis Inactivation in Culture and Liquid Whole Eggs

Techathuvanan

D’Souza

2018

Journal of Food Science

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“…Thus, the shock waves and free radicals are believed to contribute majorly toward the antimicrobial effect of ultrasound. 62 However, this effect is largely known to be dependent on the frequency of ultrasound applied. Both the low frequency (<100 kHz) and high frequency ultrasound are known to generate microcavitation.…”

Section: Biophysical Stimulation Methodsmentioning

confidence: 99%

“…Another side effect of the collapse of acoustic cavitation is the development of localized high temperatures that leads to the generation of free radicals. Thus, the shock waves and free radicals are believed to contribute majorly toward the antimicrobial effect of ultrasound . However, this effect is largely known to be dependent on the frequency of ultrasound applied.…”

Section: Strategies Against Prosthetic Infectionmentioning

confidence: 99%

Engineered biomaterial and biophysical stimulation as combinatorial strategies to address prosthetic infection by pathogenic bacteria

Boda

Basu

2016

J. Biomed. Mater. Res.

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A plethora of antimicrobial strategies are being developed to address prosthetic infection. The currently available methods for implant infection treatment include the use of antibiotics and revision surgery. Among the bacterial strains, Staphylococcus species pose significant challenges particularly, with regard to hospital acquired infections. In order to combat such life threatening infectious diseases, researchers have developed implantable biomaterials incorporating nanoparticles, antimicrobial reinforcements, surface coatings, slippery/non-adhesive and contact killing surfaces. This review discusses a few of the biomaterial and biophysical antimicrobial strategies, which are in the developmental stage and actively being pursued by several research groups. The clinical efficacy of biophysical stimulation methods such as ultrasound, electric and magnetic field treatments against prosthetic infection depends critically on the stimulation protocol and parameters of the treatment modality. A common thread among the three biophysical stimulation methods is the mechanism of bactericidal action, which is centered on biophysical rupture of bacterial membranes, the generation of reactive oxygen species (ROS) and bacterial membrane depolarization evoked by the interference of essential ion-transport. Although the extent of antimicrobial effect, normally achieved through biophysical stimulation protocol is insufficient to warrant therapeutic application, a combination of antibiotic/ROS inducing agents and biophysical stimulation methods can elicit a clinically relevant reduction in viable bacterial numbers. In this review, we present a detailed account of both the biomaterial and biophysical approaches for achieving maximum bacterial inactivation. Summarizing, the biophysical stimulation methods in a combinatorial manner with material based strategies can be a more potent solution to control bacterial infections. © 2016 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 105B: 2174-2190, 2017.

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“…The samples were collected in sterilised 500 ml Polyethylene bottles in order to avoid any contamination [13]. The samples were stored at ±4°C during the sampling event in the College Mawar Wastewater Treatment Plant UiTM Shah Alam and continuously stored at ±4°C, including the transportation time <0.5 h, until processing in the lab, within 12 h [14,15].…”

Section: Isolation and Identification Of Escherichia Colimentioning

confidence: 99%

Escherichia coli Wild Type Cells Disruption by Low Intensity Ultrasound for Bacterial Disinfection

et al. 2016

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Bacterial contamination issues are commanding the attention of water and wastewater treatments. There are many treatment methods to eliminate pathogenic bacteria. Therefore, finding efficient disinfection methods is essential to achieving safe water and protecting the human health. Therefore, this paper aims to isolate and identify Escherichia coli from municipal wastewater treatment plant and to investigate the performance of flow cell ultrasound as the bacterial disruption. In order to confirm the identification of Escherichia coli isolated, 16S rRNA sequence analysis was involved. In this particular study, the performance of flow cell ultrasound was measured by disruption of Escherichia coli cells concentration (10 4 cfu/ml), two types of flow rate (25 and 70 ml/min) with varies amplitude and power intensity. Escherichia coli isolated was determined and high homology was found that 16 s rRNA sequence of Escherichia coli with a level of identity 95 %. The flow rate at less power intensity and less oscillations amplitude at 35 % is statistically significant and higher of bacterial disruption than the greater power intensity, p = 001. Meanwhile, higher flow rate was affected by increases of cycle treatment and consequences of the higher disruption of Escherichia coli cells. In addition, ultrasound technology, which includes as an advance technology as improvements to the sustainable technology associated with the increases of public health and environmental quality.

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Kinetics and Mechanism of Bacterial Inactivation by Ultrasound Waves and Sonoprotective Effect of Milk Components

Cited by 89 publications

References 47 publications

High Intensity Ultrasound for Salmonella Enteritidis Inactivation in Culture and Liquid Whole Eggs

High Intensity Ultrasound for Salmonella Enteritidis Inactivation in Culture and Liquid Whole Eggs

Engineered biomaterial and biophysical stimulation as combinatorial strategies to address prosthetic infection by pathogenic bacteria

Escherichia coli Wild Type Cells Disruption by Low Intensity Ultrasound for Bacterial Disinfection

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