A disposable blood analysis cartridge may include a sample collection reservoir, an absorbance measurement channel, and an optical light scattering measurement channel. One or more valves may be disposed between the sample collection reservoir and the absorbance measurement channel and/or the optica
A disposable blood analysis cartridge may include a sample collection reservoir, an absorbance measurement channel, and an optical light scattering measurement channel. One or more valves may be disposed between the sample collection reservoir and the absorbance measurement channel and/or the optical light scattering measurement channel. A negative pressure may be applied to the cartridge to pull sample from the sample collection reservoir through the one or more valves and into the absorbance measurement channel and/or the optical light scattering measurement channel. Once the sample is pulled into the absorbance measurement channel and/or the optical light scattering measurement channel, the one or more valves may be closed. With the one or more valves closed, and in some cases, a pusher fluid may be provided to push the fluid sample to other regions of the disposable fluid blood analysis cartridge.
대표청구항▼
1. A method of analyzing a blood sample in a cartridge, the method comprising: receiving a blood sample via a blood sample introduction port of the cartridge, the blood sample being drawn into a sample collection reservoir by capillary action;applying a negative pressure to one or more vacuum ports
1. A method of analyzing a blood sample in a cartridge, the method comprising: receiving a blood sample via a blood sample introduction port of the cartridge, the blood sample being drawn into a sample collection reservoir by capillary action;applying a negative pressure to one or more vacuum ports of the cartridge, the negative pressure causing the blood sample to be drawn from the sample collection reservoir, through one or more open valves, and into a cuvette of an absorbance measurement channel and into at least part of an optical scattering measurement channel having a hydrodynamic focusing region;closing the one or more valves;receiving a reagent via a reagent introduction port, the reagent mixing with the blood sample in the optical scattering measurement channel upstream of the hydrodynamic focusing region;receiving a sheath fluid via a sheath fluid introduction port, the sheath fluid being injected at or near the hydrodynamic focusing region of the optical scattering measurement channel;performing an optical scatter measurement using a window that is adjacent the hydrodynamic focusing region of the optical scattering measurement channel; andperforming an absorbance measurement using the cuvette of the absorbance measurement channel. 2. A method of analyzing a blood sample in a cartridge, the method comprising: receiving a blood sample via a blood sample introduction port of the cartridge, the blood sample being drawn into a sample collection reservoir by capillary action;applying a negative pressure to a vacuum port of the cartridge to draw at least a portion the blood sample from sample collection reservoir and into a sample loading channel;closing a valve to prevent backflow of the blood sample from the sample loading channel back into the blood sample introduction port;using a positive pressure to pushing the blood sample from the sample loading channel to at least one other region of the cartridge for analysis; andanalyzing the blood sample. 3. The method of claim 2, wherein pushing at least a portion of the blood sample from the sample loading channel comprises introducing a pusher fluid into the cartridge to push at least a portion of the blood sample from the sample loading channel to at least one other region of the cartridge for analysis. 4. The method of claim 1, wherein the negative pressure is applied through one or more gas permeable membranes on the cartridge, such that the negative pressure causes the blood sample to be drawn from the sample collection reservoir, through the one or more open valves, and into the cuvette of the absorbance measurement channel and into at least part of an optical scattering measurement channel, before arriving at the one or more gas permeable membranes. 5. The method of claim 4 further comprises: closing the one or more valves after the blood sample has been drawn to the one or more gas permeable membranes; andafter the one or more valves are closed, applying a positive pressure to the blood sample to push the blood sample toward the hydrodynamic focusing region. 6. The method of claim 5, further comprising applying a positive pressure to the reagent to push the reagent to mix with the blood sample upstream of the hydrodynamic focusing region. 7. The method of claim 6, further comprising applying a positive pressure to the sheath fluid to push the sheath fluid and to inject the sheath fluid at or near the hydrodynamic focusing region of the optical scattering measurement channel. 8. The method of claim 7, wherein the blood sample is further applied to a plasma separation membrane before reaching the cuvette of the absorbance measurement channel. 9. The method of claim 7, wherein the optical scatter measurement includes a cytometer measurement. 10. The method of claim 2, wherein the negative pressure is applied through one or more gas permeable membranes on the cartridge, such that the negative pressure causes the blood sample to be drawn from the sample collection reservoir, into the sample loading channel, and up to the one or more gas permeable membranes. 11. The method of claim 10, wherein the valve is positioned fluidly between the sample collection reservoir and the one or more gas permeable membranes. 12. The method of claim 11, wherein at least one other region of the cartridge is accessed downstream of the valve and upstream of the one or more gas permeable membranes. 13. The method of claim 2, wherein analyzing the blood sample includes performing an optical scatter measurement. 14. The method of claim 13, wherein the optical scatter measurement includes a cytometer measurement. 15. The method of claim 2, wherein analyzing the blood sample includes performing an optical absorbance measurement. 16. A method of analyzing a blood sample in a cartridge, the method comprising: receiving a blood sample via a blood sample introduction port of the cartridge;receiving a reagent via a reagent introduction port;receiving a sheath fluid via a sheath fluid introduction port;applying a negative pressure to one or more vacuum ports of the cartridge, the negative pressure causing the blood sample to be drawn from the sample collection reservoir, through one or more open valves, and to one or more gas permeable membranes;closing the one or more valves;after the one or more valves are closed, pushing the blood sample and the reagent through an optical scattering measurement channel that includes a hydrodynamic focusing region, wherein the reagent and the blood sample are allowed to mix in the optical scattering measurement channel upstream of the hydrodynamic focusing region;injecting the sheath fluid into the optical scattering measurement channel at or near the hydrodynamic focusing region; andperforming an optical scatter measurement using a window that is at or adjacent the hydrodynamic focusing region of the optical scattering measurement channel. 17. The method of claim 16, further comprises opening the one or more valves before applying the negative pressure to one or more vacuum ports of the cartridge. 18. The method of claim 16, wherein the sheath fluid is injected around the blood sample at or near the hydrodynamic focusing region. 19. The method of claim 16, further comprising performing an optical absorbance measurement of the blood sample. 20. The method of claim 19, further comprising applying the blood sample to a plasma separation membrane before performing the optical absorbance measurement.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (98)
Yager Paul ; Brody James P., Absorption-enhanced differential extraction device.
Bonne Ulrich (4936 Shady Oak Rd. Hopkins MN 55343) Ohnstein Thomas R. (1944 Hythe St. Roseville MN 55113), Electronic microvalve apparatus and fabrication.
Sun Decai ; Bringans Ross D. ; Chua Christopher L. ; Floyd Philip D. ; Peeters Eric ; Kubby Joel A. ; Tran Alex T., Fabrication of scanning III-V compound light emitters integrated with Si-based actuators.
Haake John M. ; Dhuler Vijayakumar R. ; Wood Robert L., Fiber optic connector having a microelectromechanical positioning apparatus and an associated fabrication method.
Cleopatra Cabuz ; J. David Zook ; Thomas Raymond Ohnstein ; Ulrich Bonne ; Eugen Loan Cabuz ; Ernest Allen Satren, Fluid driving system for flow cytometry.
Hansen W. Peter (Middleboro MA) Hoffman Robert A. (Mansfield MA), Method and apparatus for automated identification and enumeration of specified blood cell subclasses.
Harris Thomas R. (Nashville TN) Galloway ; Jr. Robert L. (Nashville TN), Method of measuring lung vascular function and transcapillary transport by the use of nonradioactive markers.
Weigl Bernhard H. ; Yager Paul ; Brody James P. ; Holl Mark R. ; Kenny Margaret ; Schutte David ; Hixson Gregory ; Zebert M. Diane ; Kamholz Andrew ; Wu Caicai ; Altendorf Eric, Microfabricated diffusion-based chemical sensor.
Peeters Eric ; Sun Decai ; Connell G. A. Neville ; Bringans Ross D. ; Apte Raj B. ; Paoli Thomas L. ; Maeda Patrick Y. ; Fork David K. ; Kubby Joel A. ; Floyd Philip D., Monolithic scanning light emitting devices.
Yokoyama Yoshinori,JPX ; Takeda Munehisa,JPX ; Ota Hitoshi,JPX ; Uemura Aritomo,JPX ; Kitayama Tadayoshi,JPX, Optical switching apparatus for use in an optical communication system.
Cabuz, Cleopatra; Zook, J. David; Cox, James Allen; Ohnstein, Thomas Raymond; Bonne, Ulrich; Cabuz, Eugen Loan; Satren, Ernest Allen; Padmanabhan, Aravind; Marta, Teresa M., Portable flow cytometry.
Weigl Bernhard H. ; Holl Mark R. ; Zebert Diane ; Kenny Margaret ; Wu Caicai, Simultaneous analyte determination and reference balancing in reference T-sensor devices.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.