A Novel Instrument for Studying the Flow Behaviour of Erythrocytes through Microchannels Simulating Human Blood Capillaries

A novel instrument has been developed to study the microrheology of erythrocytes as they flow through channels of dimensions similar to human blood capillaries. The channels are produced in silicon substrates using microengineering technology. Accurately defined, physiological driving pressures and...

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Bibliographic Details
Published in:Microvascular research 1997-05, Vol.53 (3), p.272-281
Main Authors: Sutton, N., Tracey, M.C., Johnston, I.D., Greenaway, R.S., Rampling, M.W.
Format: Article
Language:English
Subjects:
Adult
Biological and medical sciences
Blood Flow Velocity
Capillaries - physiology
Erythrocyte Count - instrumentation
Erythrocyte Count - methods
Erythrocyte Volume - physiology
Erythrocytes - physiology
Fundamental and applied biological sciences. Psychology
Hemodynamics. Rheology
Hemorheology - instrumentation
Hemorheology - methods
Humans
Image Processing, Computer-Assisted
Miniaturization
Models, Biological
Silicon
Vertebrates: cardiovascular system
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Summary:A novel instrument has been developed to study the microrheology of erythrocytes as they flow through channels of dimensions similar to human blood capillaries. The channels are produced in silicon substrates using microengineering technology. Accurately defined, physiological driving pressures and temperatures are employed whilst precise, real-time image processing allows individual cells to be monitored continuously during their transit. The instrument characterises each cell in a sample of ca. 1000 in terms of its volume and flow velocity profile during its transit through a channel. The unique representation of the data in volume/velocity space provides new insights into the microrheological behaviour of blood. The image processing and subsequent data analysis enable the system to reject anomalous events such as multiple cell transits, thereby ensuring integrity of the resulting data. By employing an array of microfluidic flow channels we can integrate a number of different but precise and highly reproducible channel sizes and geometries within one array, thereby allowing multiple, concurrent, isobaric measurements on one sample. As an illustration of the performance of the system, volume/velocity data sets recorded in a microfluidic device incorporating multiple channels of 100 μm length and individual widths ranging between 3.0 and 4.0 μm are presented.
ISSN:0026-2862
1095-9319
DOI:10.1006/mvre.1997.2014