Abstract

The extent of brain injury following ischemic stroke is a time and space dependent function of the degree of oxygen deprivation. Although oxygen thresholds for ischemic damage have been investigated for many years, the detailed relationship between local oxygen levels and alterations in neuronal structure and function has been extremely challenging to study in vivo. Dendritic spines are of particular interest since they likely play a key role in cortical plasticity following brain injury and are a potential target for rehabilitative training strategies. However, the role of oxygen levels at the level of single dendrites is poorly understood, in large part due to a lack of methods capable of quantifying oxygenation with micron scale resolution in three dimensions. Although oxygen sensitive electrodes enable precise oxygen measurement at a single location, their invasive nature precludes them from chronic studies and for mapping oxygen distributions. Recent advances in oxygen sensitive phosphorescent dyes have opened up new possibilities for noninvasive oxygen mapping in rodent models when combined with multiphoton excitation. Despite the potential for this approach to yield new insight into microvascular oxygenation, low signals levels limit the speed and penetration depth of the oxygenation measurements. Therefore, the goal of this project is to develop an improved imaging method for three-dimensional determination of intra- and extra-vascular oxygenation levels simultaneously with imaging of dendritic morphology and to use this system to quantify the relationship between local oxygen levels and dendritic remodeling following cerebral ischemia. The technological advances in oxygen mapping will involve two components. First, we will improve the phosphorescence signal levels of the oxygen sensitive probe by developing a spatially multiplexed regenerative amplifier excitation source that will produce several spatially offset excitation spots. The minimal tradeoff in spatial resolution will be offset by the considerable gain in temporal resolution and imaging depth. Second, we will refine a method to transiently disrupt the blood brain barrier using microbubble-assisted focused ultrasound, which will permit delivery of the dye to the extravascular space. Together these advances will enable chronic measurement of oxygen levels with micron scale resolution. We will then use these tools to quantify the longitudinal oxygen gradients from surface and penetrating arterioles through capillaries and draining venules under baseline conditions and after occlusion of a single arteriole. Finally, we will quantify the relationship between oxygen levels surrounding individual dendrites and morphological changes in these dendrites during both acute and chronic ischemia.

Public Health Relevance

Stroke is one of the leading causes chronic disability in the U.S. The disruptions in oxygen supply during ischemic stroke are responsible for a complex sequence of events that leads to cell death. However, the details of the role of oxygen deprivation on cell death and remodeling are not well understood. This project will develop new methods for high resolution imaging of oxygen levels in the brain that will be used to quantify the relationship between oxygen levels and cell death following stroke.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS082518-05
Application #
9273630
Study Section
Medical Imaging Study Section (MEDI)
Program Officer
Koenig, James I
Project Start
2013-09-01
Project End
2018-05-31
Budget Start
2017-06-01
Budget End
2018-05-31
Support Year
5
Fiscal Year
2017
Total Cost
$327,617
Indirect Cost
$108,797

  Institution

Name
University of Texas Austin
Department
Biomedical Engineering
Type
Schools of Engineering
DUNS #
170230239
City
Austin
State
TX
Country
United States
Zip Code
78712

  Publications

Luan, Lan; Sullender, Colin T; Li, Xue et al. (2018) Nanoelectronics enabled chronic multimodal neural platform in a mouse ischemic model. J Neurosci Methods 295:68-76
Miller, David R; Hassan, Ahmed M; Jarrett, Jeremy W et al. (2017) In vivo multiphoton imaging of a diverse array of fluorophores to investigate deep neurovascular structure. Biomed Opt Express 8:3470-3481
Perillo, Evan P; Jarrett, Jeremy W; Liu, Yen-Liang et al. (2017) Two-color multiphoton in vivo imaging with a femtosecond diamond Raman laser. Light Sci Appl 6:
Miller, David R; Jarrett, Jeremy W; Hassan, Ahmed M et al. (2017) Deep Tissue Imaging with Multiphoton Fluorescence Microscopy. Curr Opin Biomed Eng 4:32-39
Luan, Lan; Wei, Xiaoling; Zhao, Zhengtuo et al. (2017) Ultraflexible nanoelectronic probes form reliable, glial scar-free neural integration. Sci Adv 3:e1601966
Das, Subhamoy; Singh, Gunjan; Majid, Marjan et al. (2016) Syndesome Therapeutics for Enhancing Diabetic Wound Healing. Adv Healthc Mater 5:2248-60
Liu, Yen-Liang; Perillo, Evan P; Liu, Cong et al. (2016) Segmentation of 3D Trajectories Acquired by TSUNAMI Microscope: An Application to EGFR Trafficking. Biophys J 111:2214-2227
Davis, Mitchell A; Gagnon, Louis; Boas, David A et al. (2016) Sensitivity of laser speckle contrast imaging to flow perturbations in the cortex. Biomed Opt Express 7:759-75
Lin, Linhan; Peng, Xiaolei; Mao, Zhangming et al. (2016) Bubble-Pen Lithography. Nano Lett 16:701-8
Das, Subhamoy; Monteforte, Anthony J; Singh, Gunjan et al. (2016) Syndecan-4 Enhances Therapeutic Angiogenesis after Hind Limb Ischemia in Mice with Type 2 Diabetes. Adv Healthc Mater 5:1008-13

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