Quantitative Measurement of Cerebral Hemodynamics During Activation of Auditory Cortex With Single- and Multi-Distance Near Infrared Spectroscopy

Mohammad, Penaz Parveen Sultana

29 June 2018

Functional Near Infrared Spectroscopy (fNIRS) is a safe, low-cost, non-invasive opti-cal technique to monitor focal changes in brain activity using neurovascular coupling and measurements of local tissue oxygenation, i.e., changes in concentrations of oxygenated hemoglobin (HbO) and deoxygenated hemoglobin (HbR)[42]. This thesis utilizes two fNIRS approaches to measure hemodynamic changes associated with functional stimulation of the human auditory cortex. The first approach, single-distance continuous wave NIRS (CW-NIRS) utilizes relatively simple instrumentation and the Modified-Beer Lambert (MBL) law to estimate activation induced changes in tissue oxygenation (∆CHbO and ∆CHbR)[17]. The second more complex approach, frequency domain NIRS (FD-NIRS), employs a photon diffusion model of light propagation through tissue to measure both baseline (CHbO and CHbR), and stimulus induced changes in oxygenated and deoxygenated hemoglobin[10]. FD-NIRS is more quantitative, but requires measurements at multiple light source-detector separations and thus its use in measuring focal changes in cerebral hemodynamics have been limited. A commercial FD-NIRS instrument was used to measure the cerebral hemodynamics from the right auditory cortex of 9 adults (21 ± 35 years) with normal hearing, while presented with two types of auditory stimuli: a 1000 Hz Pure tone, and Broad band noise. Measured optical intensities were analyzed using both MBL and photon diffusion approaches. Oxygenated hemoglobin was found to increase by 0.351 ± 0.116 µM and 0.060 ± 0.084 µM for Pure tone and Broad band noise stimuli, when analyzed by the MBL method at the ‘best’ source-detector separation. On average (across all sources), MBL analysis estimated an increase in CHbO of 0.100±0.075 µM and 0.099±0.084 µM respectively for Pure tone and Broad band noise stimulation. In contrast, the frequency domain analysis method estimated CHbO to increase by −0.401 ± 0.384 µM and −0.031 ± 0.358 µM for Pure tone and Broad band noise stimulation respectively. These results suggest that although more quantitative, multi-distance FD-NIRS may underestimate focal changes in cerebral hemodynamics that occur due to functional activation. Potential reasons for this discrepancy, including the partial volume effect, are discussed.

Absolute concentration

fNIRS

Modified Beer-Lambert law

FD-DOS

Functional activation

Electrical and Computer Engineering

Chronic monitoring of cortical hemodynamics after ischemic stroke using funcional optical imaging techniques

Schrandt, Christian John

11 August 2015

The roles of the vascular architecture and blood flow in response to neurovascular diseases are important in predicting physiological outcomes. Observing these parameters chronically with optical imaging techniques provides insight into the neurovascular recovery process. We develop and deploy optical imaging systems for monitoring the progression of vascular structure, perfusion, and functional blood response after ischemic stroke in a chronic rodent model to observe vascular dynamics of the cortex under normal and diseased pathologies. Specifically, we monitor the progression of the vascular structure and cerebral blood flow (CBF) over a chronic period in the rodent cortex after photo-thrombotic occlusion. Multi-Exposure Speckle Imaging (MESI) provides surface measurements of microvascular flow dynamics while Two-Photon Fluorescence Microscopy offers direct visualization of the microvascular structure. We observe the occurrence of vascular reorientation in the sub-surface microvascular structure over a 35 day post-occlusion period. We also correlate MESI flow estimates in the parenchyma with sub-surface microvascular volume fractions from two-photon microscopy to assess how vascular density influences the surface-integrated MESI measurements. Next, we develop and validate a MESI technique for measuring absolute changes of the functional blood flow response to forepaw stimulation in rodents, termed FA MESI. The optimal camera exposures for capturing the CBF response to forepaw stimulation are extracted from a training set of animal data and the feasibility of the technique is demonstrated in a testing animal set by comparing functional response results between new and existing techniques. We then deploy this system in a chronic study monitoring the progression of hemodynamic parameters after ischemic stroke within the functionally responding area of the cortex. The progression of the regional CBF perfusion and absolute changes in the magnitude of the functional blood flow response are monitored chronically after photo-thrombotic occlusion. We compare the differences between absolute and relative measurements of the functional blood flow responses, and validate FA MESI by comparing baseline measurements to 15-exposure MESI over the sampled flow distributions. We demonstrate the differences measured between the functional outcomes and the regional CBF perfusion over a three week post-occlusion time period. / text

Chronic stroke imaging

Ischemic stroke

Multi-exposure speckle imaging

Two-photon microscopy

Vascular remodeling

Cortical hemodynamics

Functional activation

Mechanismen und Mediatoren der neurovaskulären Kopplung im Gehirn

Lindauer, Ute

02 October 2001

Zwischen neuronaler und glialer Aktivierung, dem Energiemetabolismus und dem zerebralen Gefäßbett besteht eine enge Beziehung - als Phänomen der neurometabolischen und neurovaskulären Kopplung bekannt. Diese Korrelation von elektrischer und metabolischer Aktivität sowie dem regionalen zerebralen Blutfluß besteht räumliche und zeitliche fokussiert und ist charakteristisch für das Gehirn. Das Verständnis um die Mechanismen und Mediatoren der neurovaskulären Kopplung ist von grundlegender Bedeutung für die korrekte Interpretation moderner bildgebender Verfahren im klinischen Einsatz. Ein Schwerpunkt der Untersuchungen lag in der Überprüfung der Hypothese eines frühen Sauerstoff-oder Glukose-Mangels im Gewebe unter funktioneller Stimulation als mögliches primäres Signal für eine nachfolgende vaskuläre Antwort. Anhand der Befunde kann jedoch ausgeschlossen werden, daß ein möglicherweise kurzzeitig auftretender Substratmangel im Gewebe registriert wird, und auf diesem Wege die Blutflußantwort auf funktionelle Stimulation initiiert wird. Die Frage nach dem eigentlichen Signal für die Blutflußantwort und dem primären Ort der Regulation (Arteriole, Kapillare, Venole) bleibt weiterhin ungeklärt. Die qualitative wie auch quantitative Charakterisierung des Verlaufs der Blutfluß- und Blutoxygenierungsveränderungen unter somatosensorischer Stimulation bildet die Grundlage für die Untersuchung von Veränderungen dieses Musters unter pathophyiologischen Bedingungen als sogenannter Fingerabdruck spezifischer zerebraler Schädigungen. Im Rahmen des zweiten Schwerpunkts beschäftigt sich vorliegende Arbeit mit der Rolle des Bioradikals Stickstoffmonoxid (NO) bei der neurovaskulären Kopplung. Ein im kortikalen Gewebe physiologisch vorhandener basaler NO Spiegel moduliert über die Bereitstellung einer basalen cyclischen Guanosin-3',5'-Monophosphat (cGMP) Konzentration vornehmlich in glatten Gefäßmuskelzellen die Reaktivtät zerebraler Gefäße sowohl auf globale vasodilatatorische Stimuli wie die Hyperkapnie als auch auf funktionelle Aktivität wie die Whisker-Stimulation der Ratte. Da die Bereitstellung des basalen NO / cGMP Spiegels im zerebralen Gewebe für physiologische vaskuläre Antworten von grundlegender Bedeutung ist, ist zu erwarten, daß eine Störung desselben durch pathophysiologische Vorgänge weitreichende Folgen für die adequate Versorgung aktivierter Hirnareale haben dürfte. / A tight relation exists between neuronal and glial cell activation, cerebral energy metabolism, and cerebral vasculature - a phenomenon known as neurometabolic and neurovascular coupling. The correlation of electrical and metabolic activity, and regional cerebral blood flow occurs at high temporal and spatial resolution, and is characteristic for the brain. We need to understand the physiology of neurometabolic and neurovascular coupling to fully exploit the potential of modern functional brain imaging, which utilizes vascular responses to map brain activity. Therefore, understanding the signalling cascade of regional vasodilation due to functional activation is of great importance. In the present work, we have shown that there is no evidence neither for an early deoxygenation nor for an early decrease in glucose concentration in the tissue at the onset of increased neuronal activity. The first event inducing regional cerebral blood flow increase as well as the vascular compartment, at which vasodilation starts (arteriole, capillary, venule), is still not known so far and has to be further investigated. In disease neurovascular coupling may be disturbed, while this disturbance may itself further contribute to tissue damage. Therefore a thorough elucidation of the physiology and pathophysiology of neurometabolic and neurovascular coupling may contribute to the development of treatment strategies in acute and chronic CNS disorders. Beside the mechanisms, little is known concerning the mediators of neurovascular coupling. The involvement of the highly diffusible vasodilator bioradical nitric oxide (NO) in the regulation of regional cerebral blood flow is widely accepted. In the present work, it has been shown that NO acts as a modulator rather than a mediator of vascular relaxation due to functional activation or systemic hypercapnia in the cerebral cortex, permitting vasodilation mediated by other agents. This modulation mainly occurs via a basal cyclic guanosin-3',5'-monophosphate (cGMP) production within the vascular smooth muscle cell. The basal modulatory concentration of NO / cyclic GMP may be disturbed during cerebrovascular disease, leading to a mismatch of regional cerebral blood flow and metabolic demand.

Stickstoffmonoxid

Neurovaskuläre Kopplung

Funktionelle Aktivierung

Zerebrale Blutoxygenierung

Neurovascular coupling

Functional activation

Cerebral blood oxygenation

Nitric oxide

610 Medizin

33 Medizin

WW 1620

ddc:610