Technology Bundle ID
TAB-2759

Physiologic Sampling Pump Capable of Rapidly Adapting to User Breathing Rate

Linked ID
E-169-2013-0
Lead Inventors
Larry Lee (CDC)
Co-Inventors
Michael Flemmer (CDC)
Development Stages
Prototype
Development Status
  • In situ data available (on-site)
  • Prototype
ICs
CDC
This CDC developed physiologic sampling pump (PSP) overcomes shortcomings of previous devices by the use of calibrated valves in conjunction with a constant speed pump. This novel approach obviates typical PSP inertia that inherently limits system response, functionality and accuracy. All prior PSP designs have attempted to follow a user's breathing pattern by changing pump speed, thereby altering sampling rate. In that approach, pump inertia will limit system response and function due to the time required to adjust speed. Additionally, variable pump speeds often produce size selective sampling errors at low flow rates.

Performance of this PSP is not degraded by pump inertia or low flow size selective sampling errors. This design maintains a consistent pump speed, controlling PSP sampling rate with calibrated valves that redirect air flow almost instantaneously. In situ device testing demonstrated that when this air-flow valve is properly integrated into a sampling head, response time of the PSP is essentially mutually exclusive of the magnitude of changes in the effective flow, facilitating consistently small error in sampling performance regardless of user-exertion scenario.
Commercial Applications
  • Air sampling device manufacturers
  • Assessing airborne hazard exposures for workplace safety
  • Industrial hygiene programs
  • Respiration monitoring device for patients
  • Aerobic training system for athletes
Competitive Advantages
  • Allows for air sampling to be modulated to follow breathing rate
  • Design obviates the sluggishness inherent in prior art physiologic sampling pumps (PSPs) caused by variable pump speed effect on sampling rate
  • Improved accuracy compared to earlier PSPs, irrelevant of user-exertion scenarios
  • Follows inhalation on a breath-by-breath basis

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