Identificação da expressão do vascular endothelial growth factor (VEGF) pela contagem de células marcadas imunoistoquimicamente no omento de ratos após ligadura arterial e após ligadura venosa

Zart, Ronald Paulo Pinto

January 2007

O sistema cardiovascular está estrutural e funcionalmente disposto de modo “circular”. Situações de obstrução do fluxo sanguíneo determinam o aparecimento de mecanismos que visam suplantar tais interrupções e manter a circularidade íntegra. À nível molecular, o principal elemento envolvido nestes mecanismos é o Vascular Endothelial Growth Factor (VEGF). A expressão do VEGF quando há oclusão arterial está bem documentada, faltando elementos com relação à oclusão venosa. Neste estudo objetivamos verificar se a oclusão à nível arterial determina uma expressão do VEGF diferente daquela que ocorre se a oclusão acontecer à nível venoso. Para isso randomizamos dois grupos de ratos de experimentação. Em um grupo realizamos a oclusão da aorta infra-renal e em outro a oclusão da veia cava infra-renal. Posteriormente medimos a expressão do VEGF através da contagem do número de células marcadas imunoistoquimicamente no omento destes ratos. O resultado demonstrou que a expressão do VEGF, quando analisada pelo método proposto foi igual no grupo da oclusão venosa e no grupo da oclusão arterial. / The cardiovascular system is structurally and functionally circular. Situations in which there is obstruction to blood flow trigger mechanisms to bypass these blockages and maintenance the integrity of the circularity. At the molecular level the main factor involved is the Vascular Endothelial Growth Factor (VEGF). The VEGF expression associated with arterial occlusion is well documented but is lacking evidence when venous occlusion occurs. This study aimed to verify if the expression of VEGF when an occlusion occurs at venous level is the same or different from that caused at the arterial level. Two groups of rats were randomized by infra-renal aortic occlusion or inferior vena cava occlusion. VEGF was measured by counting the immunohistochemistry method marked cells at the omentum level. It was demonstrated that the VEGF expression is the same in the venous group obstruction as the arterial obstruction group.

Doença das coronárias

Circulatory system

Growth factors

Vascular endothelial growth factor

Arterial occlusion

Venous occlusion

Angiogenesis

Arteriogenesis

Venogenesis

Collateral circulation

Immunohistochemistry

Vascular density

Cellular densit

Impact of Collateral Enlargement on Smooth Muscle Phenotype

Bynum, Alexander Jerome

01 December 2011

Peripheral Artery Disease is a very serious disease characterized by an arterial occlusion due to atherosclerotic plaques. In response to an arterial occlusion, arteriogenesis occurs, causing smooth muscle cells to transition from a contractile to synthetic state. Also following an arterial occlusion, functional impairment was seen in the collateral circuit. An immunofluorescence protocol was developed in order to assess the impact of collateral enlargement (arteriogenesis) on smooth muscle phenotype at various time points. Smooth muscle α-actin was used to mark all smooth muscle cells, Ki-67 was used to label proliferating smooth muscle cells, and a fluorescent nuclear stain was used to quantify the number of cells present. Samples of the profunda femoris and gracilis were dissected from each mouse hind limb (one ligated, one sham) at three different time points: 3 days, 7 days, and 14 days after a femoral artery ligation surgery. Smooth muscle cell phenotype and luminal cross-sectional area were assessed in the profunda femoris and the midzone of the gracilis collaterals. Smooth muscle cells were proliferating at 3 and 7 days following the occlusion in the gracilis collaterals and significant collateral vessel growth was observed over the two week period. No proliferation was observed in the profunda femoris and although there was an increasing trend in vessel size over the two week period, the averages were not significantly different. The phenotypic transition of the smooth muscle cells was not the cause of vascular impairment in the collateral circuit. This shows that further research is needed to characterize impairment in the collateral circuit.

Vascular Smooth Muscle Cells

Arteriogenesis

Immunofluorescence

Mouse

Collateral Circuit

Peripheral Artery Disease

Cell Biology

Cellular and Molecular Physiology

Pathogenic Microbiology

Structural Biology