论文信息 - Bubble cycling and standing waves in ultrasonic cell lysis.

Bubble cycling and standing waves in ultrasonic cell lysis.

Two quite different but potentially complementary hypothetical mechanisms have been proposed to explain the dependence of ultrasonic cell lysis in vitro on exposure vessel rotation. One mechanism proposes that resonant-size bubbles are trapped in planar arrays by standing waves in the sample and that exposure vessel rotation sweeps cells through the bubble arrays. The other mechanism, for which there is now considerable support, proposes that exposure vessel rotation simply allows bubbles to recycle after having been driven through the medium by the ultrasound. We report here the results of efforts to further discriminate between, and quantify, the relative contributions of these two mechanisms. Murine P388 cells were exposed to 1.07 MHz continuous-wave (CW) ultrasound for 5 min at 5 W/cm2 (ISP) using various exposure vessel compositions and exposure configurations. Experimental treatments were designed either to minimize or maximize standing waves in the sample tube, or to minimize the potential for bubble recycling while maximizing standing wave formation. The results of these experiments indicate that bubble cycling is responsible for the majority of cell lysis occurring in the rotating exposure vessels, but that a significant contribution to total lysis is provided by trapped bubbles under some conditions.

M. Miller | A. Brayman | M W Miller | A A Brayman | M. Miller

[1] M. Miller,et al. The kinetics and mechanics of ultrasonically-induced cell lysis produced by non-trapped bubbles in a rotating culture tube. , 1983, Ultrasound in medicine & biology.

[2] G. E. Kaufman,et al. Growth retardation in Chinese hamster V-79 cells exposed to 1 MHz ultrasound. , 1978, Ultrasound in medicine & biology.

[3] D. Miller,et al. Bubble cycling as the explanation of the promotion of ultrasonic cavitation in a rotating tube exposure system. , 1989, Ultrasound in medicine & biology.

[4] D. Miller,et al. The role of non-acoustic factors in the induction and proliferation of cavitational activity in vitro. , 1989, Physics in medicine and biology.

[5] J A Zivin,et al. How to analyze binding, enzyme and uptake data: the simplest case, a single phase. , 1982, Life sciences.

[6] R. M. Thomas,et al. Mechanisms for hemolysis by ultrasonic cavitation in the rotating exposure system. , 1991, Ultrasound in medicine & biology.

[7] Morton W. Miller,et al. The exposure vessel as a factor in ultrasonically-induced mammalian cell lysis--II. An explanation of the need to rotate exposure tubes. , 1982, Ultrasound in medicine & biology.

[8] C R Hill,et al. Physical and chemical aspects of ultrasonic disruption of cells. , 1970, The Journal of the Acoustical Society of America.

[9] A. J. Averbuch,et al. PRIMARY METHOD FOR THE DETERMINATION OF ULTRASONIC INTENSITY WITH THE ELASTIC SPHERE-RADIOMETER. , 1977 .