Functional capillary organization in striated muscle

Berg, B. R.; Sarelius, Ingrid H.

doi:10.1152/ajpheart.1995.268.3.h1215

Cited by 42 publications

(65 citation statements)

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“…The number of capillaries in the tissue module agrees with experimental observation for the average number of capillaries supplied by a single arteriole (Berg and Sarelius, 1995). Twelve capillaries in a tissue block with a cross section of 100 × 100 μm 2 provide a capillary density (CD) of 1200 μm −2 , a value close to experimental observations (Ellsworth et al, 1988).…”

Section: Model Parameterssupporting

confidence: 85%

“…A tissue module is defined as the tissue block containing capillaries supplied by a single arteriole. For the particular tissue a module contains an average of approximately 12 capillaries (Berg and Sarelius, 1995). We define a unit tissue block of size 100 × 100 × 800 μm that contains capillaries from two modules feeding arterioles and draining venules.…”

Section: Microvascular Networkmentioning

confidence: 99%

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A computational model of oxygen delivery by hemoglobin-based oxygen carriers in three-dimensional microvascular networks

Tsoukias

Goldman

Vadapalli

et al. 2007

Journal of Theoretical Biology

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A detailed computational model is developed to simulate oxygen transport from a three-dimensional microvascular network to surrounding tissue in the presence of hemoglobin-based oxygen carriers. The model accounts for nonlinear O 2 consumption, myoglobin facilitated diffusion and nonlinear oxyhemoglobin dissociation in the RBCs and plasma. It also includes a detailed description of intravascular resistance to O 2 transport and is capable of incorporating realistic three-dimensional microvascular network geometries. Simulations in this study were performed using a computergenerated microvascular architecture that mimics morphometric parameters for the hamster cheek pouch retractor muscle. Theoretical results are presented next to corresponding experimental data. Phosphoresence quenching microscopy provided PO 2 measurements at the arteriolar and venular ends of capillaries in the hamster retractor muscle before and after isovolemic hemodilution with three different hemodilutents; a non-oxygen-carrying plasma expander and two hemoglobin solutions with different oxygen affinities. Sample results in a microvascular network show an enhancement of diffusive shunting between arterioles, venules and capillaries and a decrease in hemoglobin's effectiveness for tissue oxygenation when its affinity for O 2 is decreased. Model simulations suggest that microvascular network anatomy can affect the optimal hemoglobin affinity for reducing tissue hypoxia. O 2 transport simulations in realistic representations of microvascular networks should provide a theoretical framework for choosing optimal parameter values in the development of hemoglobin-based blood-substitutes.

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Section: Model Parameterssupporting

confidence: 85%

Section: Microvascular Networkmentioning

confidence: 99%

A computational model of oxygen delivery by hemoglobin-based oxygen carriers in three-dimensional microvascular networks

Tsoukias

Goldman

Vadapalli

et al. 2007

Journal of Theoretical Biology

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“…This is based on our prior work showing that the excessred blood cell flux travels only to the stimulated downstream branch in experiments with α v β 3 integrin ligation [16]. Next we estimated the downstream surface area for exchange using a published value for a typical capillary grouping (module) with a total length of approximately 2,800 µm [28] and average capillary diameter of 5 µm (hamster red blood cell is 5 µm); surface area per module is 4.4 × 10 –4 cm 2 /module. The volume flow and surface area provided Jv/S from the Starling equation.…”

Section: Discussionmentioning

confidence: 99%

“…The arteriolar network is a repeating structure across the hamster cheek pouch tissue; they arise from (nonnutritive) arcading arterioles, and consist of a central feed arteriole and 3–7 terminal branch arterioles [16,25,26,27]. The terminal branch arterioles perfuse only capillaries [28]; thus, flow into these networks is solely nutritional. Similar arteriolar structures are seen in the cremaster muscle of the hamster, rat or mouse [10,29].…”

Section: Methodsmentioning

confidence: 99%

Downstream Exposure to Growth Factors Causes Elevated Velocity and Dilation in Arteriolar Networks

2010

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Our goal was to characterize changes in flow and diameter with vascular endothelial cell growth factor A (VEGF-A) and fibroblast growth factor 2 (FGF2). Observations were made in arteriolar networks of the cheek pouch tissue in anesthetized hamsters (pentobarbital 70 mg/kg, i.p., n = 45). Local and remote dilation responses to micropipette-applied VEGF or FGF2 yielded similar EC₅₀ values. The role of gap junctions in the remote response was tested by applying sucrose, halothane or 18αGA to the feed arteriole midway between the remote stimulation and upstream observation sites; all remote dilation to FGF2 was prevented, while only the early dilation to VEGF was blocked. The remote dilation to VEGF displayed a second rheologic mechanism. The second mechanism involved an abrupt increase in upstream velocity and shear rate, followed by nitro-arginine sensitive dilation. To test whether the abrupt increase in shear could be caused by other agents known to cause edema, remote responses to histamine and thrombin were tested. Each caused an abrupt increase in velocity followed by nitro-arginine-sensitive dilation. This study shows that VEGF or agents that increase permeability can initiate an upstream velocity increase with dilation that recruits flow to the network; this is in addition to simultaneous gap junction-mediated dilation.

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“…Observations were made at the inflow of a transverse arteriole (feed vessel), located in each preparation as described previously [7, 8]. This site was chosen for study because it is functionally an inflow to an arteriolar network; its branch arterioles directly feed adjacent capillary networks [9, 10]. …”

Section: Methodsmentioning

confidence: 99%

Network Vascular Communication Initiated by Increases in Tissue Adenosine

Rivers

Frame

1999

J Vasc Res

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Vascular communication of vasomotor signals appears to coordinate the distribution of tissue blood flow. This study was performed to determine whether elevated tissue concentrations of adenosine or nitric oxide could induce vascular communicating signals. To test this, remote arteriolar responses were tested when drugs were applied either directly to an arteriole (∼20 μm diameter), or into the tissue in a region (with no vessels over 10 μm in diameter) that was 500 μm away from the arteriole and that bore no defined relationship to the flow path of the remote arteriole. In anesthetized hamster cheek pouch (n = 25), or cremaster muscle (n = 10), remote arteriolar responses were measured in response to nitric oxide (NO) donors (10^–5 to 10^–3 M), adenosine (10^–5 to 10^–3 M), or papaverine (10^–5 to 10^–2 M) applied for 40–120 s. Papaverine caused no remote response when applied directly while adenosine and NO donors caused similar, late-onset (10–20 s), dose-dependent, remote responses in both preparations. Remarkably however, only adenosine initiated a consistent remote arteriolar dilation when applied to the tissue site. Thus, increases in tissue adenosine may be critical for vascular communication of metabolic demands without regard to the specific blood flow path.

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Functional capillary organization in striated muscle

Cited by 42 publications

References 0 publications

A computational model of oxygen delivery by hemoglobin-based oxygen carriers in three-dimensional microvascular networks

A computational model of oxygen delivery by hemoglobin-based oxygen carriers in three-dimensional microvascular networks

Downstream Exposure to Growth Factors Causes Elevated Velocity and Dilation in Arteriolar Networks

Network Vascular Communication Initiated by Increases in Tissue Adenosine

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