Vascular adaptations to transverse aortic banding in mice

Craig J. Hartley; Lyssa N. Ochoa; Anilkumar K. Reddy; Lloyd H. Michael; Jennifer S. Pocius; Thuy T. Pham; Cederick W. Scott; Mark L. Entman; John W. Clark; George Taffet

Vascular adaptations to transverse aortic banding in mice

Craig J. Hartley, Lyssa N. Ochoa, Anilkumar K. Reddy, Lloyd H. Michael, Jennifer S. Pocius, Thuy T. Pham, Cederick W. Scott, Mark L. Entman, John W. Clark, George Taffet

Research output: Contribution to journal › Conference article › peer-review

Abstract

Transverse aortic banding in mice generates pressure overload, but cardiac hypertrophy is variable, and the effects on peripheral hemodynamics are unknown. The purpose was to characterize and model carotid and aortic blood flow patterns in banded mice using noninvasive Doppler methods. In 15 normal mice a 27-gauge needle was sutured against the transverse aorta and then removed. In 6 sham-operated mice the suture was not tied. A Doppler probe was used to measure right (R) and left (L) carotid artery (CA), aortic, and mitral blood velocity 1 day later. At 7 days the heart-weight/body-weight ratio (HW/BW) was measured. Mean aortic, mitral, and carotid velocities were similar in sham and banded mice, but peak RCA/LCA velocities were much higher in banded mice and were highly correlated to HW/BW. An esophageal Doppler probe detected high jet velocity and distal vorticity. We conclude that mice compensate for the band by increasing RCA resistance and compliance and decreasing LCA resistance to maintain normal cerebral perfusion. Velocity signals measured within one day and fitted to a lumped-parameter arterial model to estimate the pressure drop can predict the amount of cardiac hypertrophy at one week.

Original language	English (US)
Pages (from-to)	184-187
Number of pages	4
Journal	Annual Reports of the Research Reactor Institute, Kyoto University
Volume	1
State	Published - Dec 1 2001
Event	23rd Annual International Conference of the IEEE Engineering in Medicine and Biology Society - Istanbul, Turkey Duration: Oct 25 2001 → Oct 28 2001

Keywords

Cardiac hypertrophy
Carotid blood flow
Doppler ultrasound
Mice
Vascular modeling

ASJC Scopus subject areas

Energy Engineering and Power Technology
Mechanical Engineering

Cite this

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title = "Vascular adaptations to transverse aortic banding in mice",

abstract = "Transverse aortic banding in mice generates pressure overload, but cardiac hypertrophy is variable, and the effects on peripheral hemodynamics are unknown. The purpose was to characterize and model carotid and aortic blood flow patterns in banded mice using noninvasive Doppler methods. In 15 normal mice a 27-gauge needle was sutured against the transverse aorta and then removed. In 6 sham-operated mice the suture was not tied. A Doppler probe was used to measure right (R) and left (L) carotid artery (CA), aortic, and mitral blood velocity 1 day later. At 7 days the heart-weight/body-weight ratio (HW/BW) was measured. Mean aortic, mitral, and carotid velocities were similar in sham and banded mice, but peak RCA/LCA velocities were much higher in banded mice and were highly correlated to HW/BW. An esophageal Doppler probe detected high jet velocity and distal vorticity. We conclude that mice compensate for the band by increasing RCA resistance and compliance and decreasing LCA resistance to maintain normal cerebral perfusion. Velocity signals measured within one day and fitted to a lumped-parameter arterial model to estimate the pressure drop can predict the amount of cardiac hypertrophy at one week.",

keywords = "Cardiac hypertrophy, Carotid blood flow, Doppler ultrasound, Mice, Vascular modeling",

author = "Hartley, {Craig J.} and Ochoa, {Lyssa N.} and Reddy, {Anilkumar K.} and Michael, {Lloyd H.} and Pocius, {Jennifer S.} and Pham, {Thuy T.} and Scott, {Cederick W.} and Entman, {Mark L.} and Clark, {John W.} and George Taffet",

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language = "English (US)",

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pages = "184--187",

journal = "Annual Reports of the Research Reactor Institute, Kyoto University",

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note = "23rd Annual International Conference of the IEEE Engineering in Medicine and Biology Society ; Conference date: 25-10-2001 Through 28-10-2001",

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T1 - Vascular adaptations to transverse aortic banding in mice

AU - Hartley, Craig J.

AU - Ochoa, Lyssa N.

AU - Reddy, Anilkumar K.

AU - Michael, Lloyd H.

AU - Pocius, Jennifer S.

AU - Pham, Thuy T.

AU - Scott, Cederick W.

AU - Entman, Mark L.

AU - Clark, John W.

AU - Taffet, George

PY - 2001/12/1

Y1 - 2001/12/1

N2 - Transverse aortic banding in mice generates pressure overload, but cardiac hypertrophy is variable, and the effects on peripheral hemodynamics are unknown. The purpose was to characterize and model carotid and aortic blood flow patterns in banded mice using noninvasive Doppler methods. In 15 normal mice a 27-gauge needle was sutured against the transverse aorta and then removed. In 6 sham-operated mice the suture was not tied. A Doppler probe was used to measure right (R) and left (L) carotid artery (CA), aortic, and mitral blood velocity 1 day later. At 7 days the heart-weight/body-weight ratio (HW/BW) was measured. Mean aortic, mitral, and carotid velocities were similar in sham and banded mice, but peak RCA/LCA velocities were much higher in banded mice and were highly correlated to HW/BW. An esophageal Doppler probe detected high jet velocity and distal vorticity. We conclude that mice compensate for the band by increasing RCA resistance and compliance and decreasing LCA resistance to maintain normal cerebral perfusion. Velocity signals measured within one day and fitted to a lumped-parameter arterial model to estimate the pressure drop can predict the amount of cardiac hypertrophy at one week.

AB - Transverse aortic banding in mice generates pressure overload, but cardiac hypertrophy is variable, and the effects on peripheral hemodynamics are unknown. The purpose was to characterize and model carotid and aortic blood flow patterns in banded mice using noninvasive Doppler methods. In 15 normal mice a 27-gauge needle was sutured against the transverse aorta and then removed. In 6 sham-operated mice the suture was not tied. A Doppler probe was used to measure right (R) and left (L) carotid artery (CA), aortic, and mitral blood velocity 1 day later. At 7 days the heart-weight/body-weight ratio (HW/BW) was measured. Mean aortic, mitral, and carotid velocities were similar in sham and banded mice, but peak RCA/LCA velocities were much higher in banded mice and were highly correlated to HW/BW. An esophageal Doppler probe detected high jet velocity and distal vorticity. We conclude that mice compensate for the band by increasing RCA resistance and compliance and decreasing LCA resistance to maintain normal cerebral perfusion. Velocity signals measured within one day and fitted to a lumped-parameter arterial model to estimate the pressure drop can predict the amount of cardiac hypertrophy at one week.

KW - Cardiac hypertrophy

KW - Carotid blood flow

KW - Doppler ultrasound

KW - Mice

KW - Vascular modeling

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JO - Annual Reports of the Research Reactor Institute, Kyoto University

JF - Annual Reports of the Research Reactor Institute, Kyoto University

T2 - 23rd Annual International Conference of the IEEE Engineering in Medicine and Biology Society

Y2 - 25 October 2001 through 28 October 2001

ER -

Vascular adaptations to transverse aortic banding in mice

Abstract

Keywords

ASJC Scopus subject areas

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