AI Article Synopsis
- The study investigates how self-excited oscillations in a Starling resistor relate to physiological conditions using a collapsible tube under controlled pressure.
- It identifies low- and high-frequency oscillations, with low frequencies being sensitive to the sleeve type and the unsupported length of the tube.
- The findings show different oscillation behaviors based on pressure changes, highlighting collapsible tube instability mechanisms and explaining why low-frequency oscillations generally do not occur in normal physiological scenarios.
Article Abstract
To determine whether self-excited oscillations in a Starling resistor are relevant to physiological situations, a collapsible tube conveying an aqueous flow was externally pressurized along only a central segment of its unsupported length. This was achieved by passing the tube through a shorter and wider collapsible sleeve which was mounted in Starling resistor fashion in a pressure chamber. The tube size and material, and all other experimental parameters, were as used in our previous Starling resistor studies. Both low- and high-frequency self-excited oscillations were observed, but the low-frequency oscillations were sensitive to the sleeve type and length relative to unsupported distance. Pressure-flow characteristics showed multiple oscillatory modes, which differed quantitatively from those observed in comparable Starling resistors. Slow variation of driving pressure gave differing behavior according to whether the pressure was rising or falling, in accord with the hysteresis noted on the characteristics and in the tube law. The results are discussed in terms of the various possible mechanisms of collapsible tube instability, and reasons are presented for the absence of the low-frequency mode under most physiological circumstances.
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| http://dx.doi.org/10.1115/1.3168364 | DOI Listing |
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