Predicting and managing heat dissipation from a neural probe

Light stimulating neural probes are rapidly increasing our understanding of neural pathways. Relocating the externally coupled light source to the probe tip has the potential to dramatically improve the flexibility of the technique. However, this approach would generate heat within the embedded prob...

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Bibliographic Details
Published in:Biomedical microdevices 2015-08, Vol.17 (4), p.81-9, Article 81
Main Authors: Smith, Andrew N., Christian, Matthew P., Firebaugh, Samara L., Cooper, Garret W., Jamieson, Brian G.
Format: Article
Language:English
Subjects:
Animals
Biological and Medical Physics
Biomedical Engineering and Bioengineering
Biophysics
Blood
Body Temperature
Brain
Brain - metabolism
Calibration
Cattle
Cooling
Electric Stimulation - instrumentation
Engineering
Engineering Fluid Dynamics
Equipment Design
Flexibility
Heat
Heat transfer
Hot Temperature
Insertion
Membranes
Microelectrodes
Microtechnology
Models, Biological
Nanotechnology
Neural networks
Neurons
Neurons - metabolism
Spreading
Thermal Conductivity
Tissues
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Summary:Light stimulating neural probes are rapidly increasing our understanding of neural pathways. Relocating the externally coupled light source to the probe tip has the potential to dramatically improve the flexibility of the technique. However, this approach would generate heat within the embedded probe where even minor temperature excursions could easily damage tissues under study. A COMSOL model was used to study the thermal effects of these heated probes in the brain including blood perfusion and metabolic heating, and to investigate the effect of passive methods for improving heat dissipation. The probe temperature initially decreases with insertion depth, and then becomes steady. Extending the probe beyond the heated region has a similar effect, while increasing the size of the heated region steadily decreases the probe temperature. Increasing the thermal conductivity of the probe promotes spreading, decreasing the probe temperature. The effects of insertion depth and probe power dissipation were experimentally tested with a microfabricated, heated mock neural probe. The heated probe was tested in 0.65 % agarose gel at room temperature and in ex vivo cow brain at body temperature. The thermal resistance between the probe and the neural tissue or agarose gel was determined at a range of insertion depths and compared to the COMSOL model.
ISSN:1387-2176
1572-8781
DOI:10.1007/s10544-015-9976-3