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Effect of arterial blood perfusion pressure on vascular conductance and muscle blood flow at rest and exerciseVillar, Rodrigo January 2012 (has links)
The adaptations of vessel diameter represented by vascular conductance (VC), muscle
blood flow (MBF) and oxygen delivery (DO2est) were investigated during rest and exercise
using the effects of gravity to manipulate muscle perfusion pressure (MPP) by placing
the heart above (head-up tilt) and below (head-down tilt) the level of the muscle. This
experimental paradigm was used to explore VC and MBF regulation and related control
mechanisms during rest and exercise. Study 1 tested the repeatability of Doppler ultra-
sound measurements of muscle blood flow velocity (MBV), arterial diameter, MBF and
VC. The adaptations in VC and MBF (Study 2) and changes in anterograde and retro-
grade MBV patterns (Study 3) were investigated during postural challenges at rest. Study
4, determined the peak VC and its fractional recruitment during transitions from rest to
lower (LPO) and higher power output (HPO) calf muscle exercise in HDT and HUT. Study
5 investigated the combined effects of altered MPP and hypoxia during exercise. During
rest-HDT, increases in VC compensated for the MPP reduction to maintain MBF, while
in rest-HUT, MBF was reduced. Following the start of LPO and HPO exercises, MBF and
VC responses were delayed in HDT and accelerated in HUT. During LPO, MBF steady-
state was reduced in HUT compared to horizontal (HOR), while the greater increase in
VC during HDT maintained MBF at a similar level as HUT. Post-exercise MBF recovered
rapidly in all positions after LPO exercise but did not after HPOHDT. During HPOHDT,
MBF was reduced despite the increase in VC, while in HPOHUT MBF was similar to that
in HPOHOR. The hypoxic challenge added in exercise was met during LPOHDT by in-
creased VC to compensate reduced MPP and O2 availability such that MBF maintained
DO2est. However, during HPOHDT in hypoxia, VC reached maximal vasodilatory capacity,
compromising MBF and DO2est. Together, these findings indicate that LPOHDT in nor-
moxia or hypoxia VC increased to maintain MBF and DO2est, but during HPO functional
limitation for recruitment of VC constrained MBF and DO2 in normoxia and hypoxia.
Elevated muscle electromyograpic signals in HPOHDT were consistent with challenged aer-
obic metabolism. MPP reduction in HDT caused slower adaptation of MBF limiting O2
availability would result in a greater O2 deficit that could contribute to an increase in the
relative stress of the exercise challenge and advance the onset of muscle fatigue.
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Effect of arterial blood perfusion pressure on vascular conductance and muscle blood flow at rest and exerciseVillar, Rodrigo January 2012 (has links)
The adaptations of vessel diameter represented by vascular conductance (VC), muscle
blood flow (MBF) and oxygen delivery (DO2est) were investigated during rest and exercise
using the effects of gravity to manipulate muscle perfusion pressure (MPP) by placing
the heart above (head-up tilt) and below (head-down tilt) the level of the muscle. This
experimental paradigm was used to explore VC and MBF regulation and related control
mechanisms during rest and exercise. Study 1 tested the repeatability of Doppler ultra-
sound measurements of muscle blood flow velocity (MBV), arterial diameter, MBF and
VC. The adaptations in VC and MBF (Study 2) and changes in anterograde and retro-
grade MBV patterns (Study 3) were investigated during postural challenges at rest. Study
4, determined the peak VC and its fractional recruitment during transitions from rest to
lower (LPO) and higher power output (HPO) calf muscle exercise in HDT and HUT. Study
5 investigated the combined effects of altered MPP and hypoxia during exercise. During
rest-HDT, increases in VC compensated for the MPP reduction to maintain MBF, while
in rest-HUT, MBF was reduced. Following the start of LPO and HPO exercises, MBF and
VC responses were delayed in HDT and accelerated in HUT. During LPO, MBF steady-
state was reduced in HUT compared to horizontal (HOR), while the greater increase in
VC during HDT maintained MBF at a similar level as HUT. Post-exercise MBF recovered
rapidly in all positions after LPO exercise but did not after HPOHDT. During HPOHDT,
MBF was reduced despite the increase in VC, while in HPOHUT MBF was similar to that
in HPOHOR. The hypoxic challenge added in exercise was met during LPOHDT by in-
creased VC to compensate reduced MPP and O2 availability such that MBF maintained
DO2est. However, during HPOHDT in hypoxia, VC reached maximal vasodilatory capacity,
compromising MBF and DO2est. Together, these findings indicate that LPOHDT in nor-
moxia or hypoxia VC increased to maintain MBF and DO2est, but during HPO functional
limitation for recruitment of VC constrained MBF and DO2 in normoxia and hypoxia.
Elevated muscle electromyograpic signals in HPOHDT were consistent with challenged aer-
obic metabolism. MPP reduction in HDT caused slower adaptation of MBF limiting O2
availability would result in a greater O2 deficit that could contribute to an increase in the
relative stress of the exercise challenge and advance the onset of muscle fatigue.
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Změna prokrvení svalu při kompresivní terapii / A Change in Blood Flow to the Muscle during Compression TherapyKuncová, Eliška January 2020 (has links)
Title: A Change in Blood Flow to the Muscle during Compression Therapy Objectives: The main objective of this work is to determine the change in muscle blood flow during compression therapy, specifically during flossing. Another objective is to get acquainted with compression techniques. Methods: In our work, we used an anamnesty questionnaire to get basic information about probabilities. Flossing was applied to the right shoulder for two minutes. The flow measurement was carried out on Précisé 8008 and the data were evaluated using descriptive statistics, testing using a linear model, an ANOVA and T-test. Results: We found that the development of blood flow to the biceps brachii muscle during and after application is variable. After application of flossing, there are statistically significant changes in blood flow to the upper limb (where flossing was applied) and subsequently, after application, there is an improvement in muscle blood flow (TcpO2). There is also a change in blood flow to the opposite limb (where flossing has not been applied), but this change is statistically significant at the time of the lowest blood flow to the limb where flossing was applied and 15 minutes after the lowest perfusion was measured. Furthermore, flossing was found not to return rapidly to baseline in the upper...
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Mechanisms that Jeopardize Skeletal Muscle Perfusion during SurgeryMak, Timothy 05 December 2013 (has links)
We assessed potential mechanisms that may jeopardize skeletal muscle perfusion during surgery leading to adverse outcomes including muscle injury and flap hypoxia. In craniotomy patients, we observed an increase in serum lactate and creatine kinase and urine myoglobin; indicative of muscle damage. The early rise in lactate correlated with elevated BMI, suggesting that obesity caused tissue compression and muscle ischemia. In our rodent model, we investigated the effects of flap preparation and phenylephrine on muscle perfusion by assessing microvascular blood flow and tissue PO2. Phenylephrine reduced muscle blood flow by ~20%, yet increased PO2 by ~10% suggestive of decreased O2 metabolism. At baseline, muscle flap blood flow was reduced by ~50% while PO2 was severely reduced ~80% (~5 torr) suggesting that flap perfusion was attenuated and O2 metabolism was increased. Phenylephrine infusion further reduced muscle flap perfusion. These data demonstrate multiple mechanisms by which muscle perfusion is jeopardized during surgery.
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Mechanisms that Jeopardize Skeletal Muscle Perfusion during SurgeryMak, Timothy 05 December 2013 (has links)
We assessed potential mechanisms that may jeopardize skeletal muscle perfusion during surgery leading to adverse outcomes including muscle injury and flap hypoxia. In craniotomy patients, we observed an increase in serum lactate and creatine kinase and urine myoglobin; indicative of muscle damage. The early rise in lactate correlated with elevated BMI, suggesting that obesity caused tissue compression and muscle ischemia. In our rodent model, we investigated the effects of flap preparation and phenylephrine on muscle perfusion by assessing microvascular blood flow and tissue PO2. Phenylephrine reduced muscle blood flow by ~20%, yet increased PO2 by ~10% suggestive of decreased O2 metabolism. At baseline, muscle flap blood flow was reduced by ~50% while PO2 was severely reduced ~80% (~5 torr) suggesting that flap perfusion was attenuated and O2 metabolism was increased. Phenylephrine infusion further reduced muscle flap perfusion. These data demonstrate multiple mechanisms by which muscle perfusion is jeopardized during surgery.
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