Portable six-channel laser speckle system for simultaneous measurement of cerebral blood flow and volume with potential applications in characterization of brain injury

• Published in: Neurophotonics (Print) Vol. 12; no. 1; p. 015003
• Main Authors: Mahler, Simon, Huang, Yu Xi, Ismagilov, Max, Álvarez-Chou, David, Abedi, Aidin, Tyszka, J. Michael, Lo, Yu Tung, Russin, Jonathan, Pantera, Richard L., Liu, Charles, Yang, Changhuei
• Format: Journal Article
• Language: English
• Published: United States Society of Photo-Optical Instrumentation Engineers 01.01.2025; SPIE
• Subjects: Brain; Brain damage; Injuries; Physiological aspects; United States; laser speckle contrast imaging; cerebral blood flow; non-invasive brain imaging; brain injury; biomedical optics; speckle contrast optical spectroscopy
• ISSN: 2329-423X; 2329-4248
• DOI: 10.1117/1.NPh.12.1.015003

Cerebral blood flow (CBF) and cerebral blood volume (CBV) are key metrics for regional cerebrovascular monitoring. Simultaneous, non-invasive measurement of CBF and CBV at different brain locations would advance cerebrovascular monitoring and pave the way for brain injury detection as current brain injury diagnostic methods are often constrained by high costs, limited sensitivity, and reliance on subjective symptom reporting. We aim to develop a multi-channel non-invasive optical system for measuring CBF and CBV at different regions of the brain simultaneously with a cost-effective, reliable, and scalable system capable of detecting potential differences in CBF and CBV across different regions of the brain. The system is based on speckle contrast optical spectroscopy and consists of laser diodes and board cameras, which have been both tested and investigated for safe use on the human head. Apart from the universal serial bus connection for the camera, the entire system, including its battery power source, is integrated into a wearable headband and is powered by 9-V batteries. The temporal dynamics of both CBF and CBV in a cohort of five healthy subjects were synchronized and exhibited similar cardiac period waveforms across all six channels. The potential use of our six-channel system for detecting the physiological sequelae of brain injury was explored in two subjects, one with moderate and one with significant structural brain damage, where the six-point CBF and CBV measurements were referenced to structural magnetic resonance imaging (MRI) scans. We pave the way for a viable multi-point optical instrument for measuring CBF and CBV. Its cost-effectiveness allows for baseline metrics to be established prior to injury in populations at risk for brain injury.