Modification of Food Systems by Ultrasound

Carrillo-López, Luis M.; Alarcón-Rojo, Alma D.; Luna-Rodríguez, Lorena; Reyes-Villagrana, Raúl Alberto

doi:10.1155/2017/5794931

Cited by 41 publications

(14 citation statements)

References 86 publications

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“…Ultrasound exposure time was 0, 10, 20, or 40 min. Samples were directly placed in the water to assure that the possible effect was caused by the cavitation phenomenon, a physical plastic layer could attenuate or modify the effect of the cavitation inside the pack (Carrillo‐Lopez, Alarcon‐Rojo, Luna‐Rodriguez, & Reyes‐Villagrana, ; Garcia‐Galicia et al, ). To ensure an even exposure to ultrasonic waves, the steak was turned at the middle of the ultrasonication time.…”

Section: Methodsmentioning

confidence: 99%

Time matters when ultrasonicating beef: The best time for tenderness is not the best for reducing microbial counts

Diaz‐Almanza

Reyes-Villagrana

Alarcón-Rojo

et al. 2019

J Food Process Engineering

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Research on the effects of high‐intensity ultrasound (HIU) on meat quality properties shows contradictory results. The latter has been sometimes attributed to limited exposure time, not enough to cause cellular modifications. This study evaluated the effect of different exposure times (0, 10, 20, and 40 min) of HIU (37 kHz, 90 W cm−2) on physicochemical properties including; pH, color, tenderness, and microbial counts of two different portions of beef Longissimus lumborum (cranial–caudal). No significant effect of loin portion was observed (p > .05). Ultrasonication time caused a 20.7% toughness reduction of beef (p < .05). However, ultrasonication time also increased hue from 0.62 to 0.76 from red to orange values (p < .05), but it did not affect important coordinates such as a* or C*. Ultrasound caused an increase in the pH from 5.46 to 5.6 (p < .05), but pH was not affected by the time. The highest tenderness was achieved at 40 min of sonication. Significant reductions of mesophiles, psychrophiles, and coliforms were observed after ultrasonication when compared to control (p < .05). The best ultrasonic condition for microbial reduction was at 10 min, when the lowest microorganism counts were achieved, with a subsequent growth when increasing ultrasonication time. Practical Applications High‐intensity ultrasound application appears to be a promising method to increase tenderness in beef. However, optimum time, intensity, and methodology for its application have to be defined, because the variations may affect other quality characteristics such as color or microbial contamination. To find ideal parameter values may help the industry to take decisions on the design of specialized equipment for ultrasonication of meat.

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Section: Methodsmentioning

confidence: 99%

Time matters when ultrasonicating beef: The best time for tenderness is not the best for reducing microbial counts

Diaz‐Almanza

Reyes-Villagrana

Alarcón-Rojo

et al. 2019

J Food Process Engineering

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“…As shown in Figure 8, the clouds of cavitation bubbles on the surface of the sphere are the main factor generating the heating effect. [97] Kiani et al [98] evaluated that the rate of heat transfer between a submerged object and cooling medium was accelerated by the application of ultrasound irradiation. In addition, the impact of ultrasound irradiation on heat transfer was unconcerned with the ball diameter.…”

Section: Controlling Ice Crystals' Size and Shapementioning

confidence: 99%

Mechanism of ultrasound assisted nucleation during freezing and its application in food freezing process

Mei

Xie

2021

International Journal of Food Properties

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Ultrasound assisted freezing (UAF) is a common and remarkable technology of food preservation to conserve the sensory characteristics and nutritional value. The propagation of ultrasound in a medium generates various physical and chemical effects and these effects have been harnessed to improve the efficiency of food freezing. This review provides an overview of recent developments related to the mechanism, influencing factors, equipment of UAF. The applications of high intensity ultrasound to improve the efficiency of freezing process, to control the size and size distribution of ice crystals and to improve the quality of frozen foods are discussed in considerable detail. Then the future development trends and challenges of UAF have also been highlighted.

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“…To simulate hypersound shock waves with protein-size wavelengths, their frequency was set to 625 GHz (corresponding to a period of 1.6 ps ) ( Fig. 1A), which is more than 100 times higher than that of currently used ultrasound waves 17 . The hypersound-perturbed MD simulation of liquid water at 298 K showed the generation and propagation of a high-density region ( Fig.…”

Section: Main Textmentioning

confidence: 99%

“…The increase in the frequency factor could be attributed to enhanced ligand diffusion (Table 1) 17 , which would increase the collision frequency of the ligand with the protein pocket, while enhancing the thermal motions of the solvent molecules did not result in increased ligand diffusion and an acceleration of the ligand binding process (the Supplementary section 1.8). In addition, the generation of local highenergy/pressure regions in the solvent leads to an increase in the effective temperature 15 ; however, the "macroscopic" temperature of the system remained unchanged at 298 K (Supplementary Table 1).…”

Section: Main Textmentioning

confidence: 99%

“…The present acceleration method code is publicly available (see the Code Availability section), can be implemented on standard high-performance computers, and is suitable for parallel computing because performing multiple independent simulations in parallel enables the sampling of a higher number of binding events and thus produces an improved statistical description of the process under study. Furthermore, the hypersound irradiation modeled in the simulations is not a ctitious computational procedure, but a real physical process, even though hypersound waves of molecular (several nanometers) wavelength have not yet been realized 17 , which currently hampers the experimental assessment of its impact. Further applications of the present technique to model other biomolecular (e.g., protein conformational changes and protein-protein interactions) and non-biomolecular (e.g., phase transitions of materials) processes are required to assess its general effectiveness in modeling slow dynamic events.…”

Section: Main Textmentioning

confidence: 99%

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Exploring ligand binding pathways on proteins using hypersound–accelerated molecular dynamics

Araki

Matsumoto

Bekker

et al. 2021

Preprint

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Capturing the dynamic processes of biomolecular systems in atomistic detail remains difficult despite recent experimental advances. Although molecular dynamics (MD) techniques enable atomic-level observations, simulations of “slow” biomolecular processes (with timescales longer than submilliseconds) are challenging, due to current computer speed limitations. Therefore, we developed a new method to accelerate MD simulations by high-frequency ultrasound perturbation. The binding events between the protein CDK2 and its small-molecule inhibitors were nearly undetectable in 100-ns conventional MD, but the new method successfully accelerated their slow binding rates by up to 10–20 times. The accelerated MD simulations revealed a variety of microscopic kinetic features of the inhibitors on the protein surface, such as the existence of different binding pathways to the active site. Moreover, the simulations allowed estimating the corresponding kinetic parameters and exploring other druggable pockets. This method can thus provide deeper insight into the microscopic interactions controlling biomolecular processes.

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Modification of Food Systems by Ultrasound

Cited by 41 publications

References 86 publications

Time matters when ultrasonicating beef: The best time for tenderness is not the best for reducing microbial counts

Time matters when ultrasonicating beef: The best time for tenderness is not the best for reducing microbial counts

Mechanism of ultrasound assisted nucleation during freezing and its application in food freezing process

Exploring ligand binding pathways on proteins using hypersound–accelerated molecular dynamics

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