Enhancement of light in tissue using hyper-osmotic agents

Raiyan T. Zaman; Bo Chen; Ashwin B. Parthasarathy; Arnold D. Estrada; Ardien Ponticorvo; Henry G. Rylander; Andrew K. Dunn; Ashley J. Welch

doi:10.1117/12.763241

Enhancement of light in tissue using hyper-osmotic agents

Raiyan T. Zaman, Bo Chen, Ashwin B. Parthasarathy, Arnold D. Estrada, Ardien Ponticorvo, Henry G. Rylander, Andrew K. Dunn, Ashley J. Welch

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

Optical changes in skin blood flow due to the presence of glycerol were measured from a two-dimensional map of blood flow in skin blood vessels with a dynamic imaging technique using laser speckle. In this study a dorsal skin-flap window was implanted on the hamster skin with and without a hyper-osmotic agent i.e. glycerol. The hyper-osmotic drug was delivered to the skin through the open dermal end of the window model. A two-dimensional map of blood flow in skin blood vessels were obtained with very high spatial and temporal resolution by imaging the speckle pattern with a CCD camera. Preliminary studies demonstrated that hyper-osmotic agents such as glycerol not only make tissue temporarily translucent, but also reduce blood flow. The blood perfusion was measured every 3 minutes up to 36-60 minutes after diffusion of anhydrous glycerol. Small capillaries blood flow reduced significantly within 3-9 minutes. Perfusion rate in lager blood vessels i.e. all arteries and some veins decreased (speckle contrasts increased from 0.0115 to 0.384) over time. However, the blood flow in some veins reduced significantly in 36 minutes. After 24 hours the blood perfusion further reduced in capillaries. However, the blood flow increased in larger blood vessels in 24 hours compared to an hour after application of glycerol. For further investigation the speckle contrast measurement were verified with color Doppler optical coherence tomography.

Original language	English (US)
Title of host publication	Optical Interactions with Tissue and Cells XIX
DOIs	https://doi.org/10.1117/12.763241
State	Published - 2008
Externally published	Yes
Event	Optical Interactions with Tissue and Cells XIX - San Jose, CA, United States Duration: Jan 21 2008 → Jan 23 2008

Publication series

Name	Progress in Biomedical Optics and Imaging - Proceedings of SPIE
Volume	6854
ISSN (Print)	1605-7422

Conference

Conference	Optical Interactions with Tissue and Cells XIX
Country/Territory	United States
City	San Jose, CA
Period	1/21/08 → 1/23/08

Keywords

Blood perfusion
Color Doppler optical coherence tomography
Hyper-osmotic agents
Optical change
Speckle measurement
Window model

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Biomaterials
Atomic and Molecular Physics, and Optics
Radiology Nuclear Medicine and imaging

Access to Document

10.1117/12.763241

Cite this

Zaman, RT, Chen, B, Parthasarathy, AB, Estrada, AD, Ponticorvo, A, Rylander, HG, Dunn, AK & Welch, AJ 2008, Enhancement of light in tissue using hyper-osmotic agents. in Optical Interactions with Tissue and Cells XIX., 68541F, Progress in Biomedical Optics and Imaging - Proceedings of SPIE, vol. 6854, Optical Interactions with Tissue and Cells XIX, San Jose, CA, United States, 1/21/08. https://doi.org/10.1117/12.763241

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title = "Enhancement of light in tissue using hyper-osmotic agents",

abstract = "Optical changes in skin blood flow due to the presence of glycerol were measured from a two-dimensional map of blood flow in skin blood vessels with a dynamic imaging technique using laser speckle. In this study a dorsal skin-flap window was implanted on the hamster skin with and without a hyper-osmotic agent i.e. glycerol. The hyper-osmotic drug was delivered to the skin through the open dermal end of the window model. A two-dimensional map of blood flow in skin blood vessels were obtained with very high spatial and temporal resolution by imaging the speckle pattern with a CCD camera. Preliminary studies demonstrated that hyper-osmotic agents such as glycerol not only make tissue temporarily translucent, but also reduce blood flow. The blood perfusion was measured every 3 minutes up to 36-60 minutes after diffusion of anhydrous glycerol. Small capillaries blood flow reduced significantly within 3-9 minutes. Perfusion rate in lager blood vessels i.e. all arteries and some veins decreased (speckle contrasts increased from 0.0115 to 0.384) over time. However, the blood flow in some veins reduced significantly in 36 minutes. After 24 hours the blood perfusion further reduced in capillaries. However, the blood flow increased in larger blood vessels in 24 hours compared to an hour after application of glycerol. For further investigation the speckle contrast measurement were verified with color Doppler optical coherence tomography.",

keywords = "Blood perfusion, Color Doppler optical coherence tomography, Hyper-osmotic agents, Optical change, Speckle measurement, Window model",

author = "Zaman, {Raiyan T.} and Bo Chen and Parthasarathy, {Ashwin B.} and Estrada, {Arnold D.} and Ardien Ponticorvo and Rylander, {Henry G.} and Dunn, {Andrew K.} and Welch, {Ashley J.}",

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AU - Zaman, Raiyan T.

AU - Chen, Bo

AU - Parthasarathy, Ashwin B.

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AU - Ponticorvo, Ardien

AU - Rylander, Henry G.

AU - Dunn, Andrew K.

AU - Welch, Ashley J.

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N2 - Optical changes in skin blood flow due to the presence of glycerol were measured from a two-dimensional map of blood flow in skin blood vessels with a dynamic imaging technique using laser speckle. In this study a dorsal skin-flap window was implanted on the hamster skin with and without a hyper-osmotic agent i.e. glycerol. The hyper-osmotic drug was delivered to the skin through the open dermal end of the window model. A two-dimensional map of blood flow in skin blood vessels were obtained with very high spatial and temporal resolution by imaging the speckle pattern with a CCD camera. Preliminary studies demonstrated that hyper-osmotic agents such as glycerol not only make tissue temporarily translucent, but also reduce blood flow. The blood perfusion was measured every 3 minutes up to 36-60 minutes after diffusion of anhydrous glycerol. Small capillaries blood flow reduced significantly within 3-9 minutes. Perfusion rate in lager blood vessels i.e. all arteries and some veins decreased (speckle contrasts increased from 0.0115 to 0.384) over time. However, the blood flow in some veins reduced significantly in 36 minutes. After 24 hours the blood perfusion further reduced in capillaries. However, the blood flow increased in larger blood vessels in 24 hours compared to an hour after application of glycerol. For further investigation the speckle contrast measurement were verified with color Doppler optical coherence tomography.

AB - Optical changes in skin blood flow due to the presence of glycerol were measured from a two-dimensional map of blood flow in skin blood vessels with a dynamic imaging technique using laser speckle. In this study a dorsal skin-flap window was implanted on the hamster skin with and without a hyper-osmotic agent i.e. glycerol. The hyper-osmotic drug was delivered to the skin through the open dermal end of the window model. A two-dimensional map of blood flow in skin blood vessels were obtained with very high spatial and temporal resolution by imaging the speckle pattern with a CCD camera. Preliminary studies demonstrated that hyper-osmotic agents such as glycerol not only make tissue temporarily translucent, but also reduce blood flow. The blood perfusion was measured every 3 minutes up to 36-60 minutes after diffusion of anhydrous glycerol. Small capillaries blood flow reduced significantly within 3-9 minutes. Perfusion rate in lager blood vessels i.e. all arteries and some veins decreased (speckle contrasts increased from 0.0115 to 0.384) over time. However, the blood flow in some veins reduced significantly in 36 minutes. After 24 hours the blood perfusion further reduced in capillaries. However, the blood flow increased in larger blood vessels in 24 hours compared to an hour after application of glycerol. For further investigation the speckle contrast measurement were verified with color Doppler optical coherence tomography.

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KW - Color Doppler optical coherence tomography

KW - Hyper-osmotic agents

KW - Optical change

KW - Speckle measurement

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Enhancement of light in tissue using hyper-osmotic agents

Abstract

Publication series

Conference

Keywords

ASJC Scopus subject areas

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