The Open Nanomedicine and Nanotechnology Journal

2009, 2 : 1-9
Published online 2009 January 23. DOI: 10.2174/1875933500902010001
Publisher ID: TONMJ-2-1

Modeling Microscopic Chemical Sensors in Capillaries

Tad Hogg
Hewlett-Packard Laboratories, Palo Alto, CA, USA

ABSTRACT

Nanotechnology-based microscopic robots could provide accurate in vivo measurement of chemicals in the bloodstream for detailed biological research and as an aid to medical treatment. Quantitative performance estimates of such devices require models of how chemicals in the blood diffuse to the devices. This paper models microscopic robots and red blood cells (erythrocytes) in capillaries using realistic distorted cell shapes. The models evaluate two sensing scenarios: robots moving with the cells past a chemical source on the vessel wall, and robots attached to the wall for longer-term chemical monitoring of chemicals released into the bloodstream. Using axial symmetric geometry with realistic flow speeds and diffusion coefficients, we compare detection performance with a simpler model that does not include the cells. The average chemical absorption is quantitatively similar in both models, indicating the simpler model is an adequate design guide to sensor performance in capillaries. However, determining the variation in forces and absorption as cells move requires the full model.