ABSTRACT
Objective: Among the veins used as a graft in myocardial revascularizations and ends, great saphenous vein is the most used. Knowing the presence and location of valves has great importance when evaluating the surgical anatomy of the great saphenous vein. Despite major surgical application and many works involving great saphenous vein, the number of valves present in it from the saphenous hiatus to the medial epicondyle of the femur is still described inaccurately. The objective of this study is to quantify the valves of the great saphenous vein from the saphenous hiatus to the medial epicondyle of the femur to determine the best portion of the great saphenous vein to perform revascularization surgeries. Methods: This is a crosssectional observational study in which it was analyzed great saphenous vein extracted from 30 cadavers. It was measured the length of the veins; (diameter) at its proximal, middle and distal, quantifying the number of valves in each one and the total number of valves at the great saphenous vein. Results: The frequency of valves in the great saphenous vein taken from the medial epicondyle of the femur to the saphenous hiatus was 4.82, ranging between 2 and 9. Moreover, there is a significant difference in the number of valves in the proximal and distal relative to the average. Conclusion: the median and distal portions of the saphenous vein in the thigh, are the best options for the realization of bridges due to the fact that these portions have fewer valves which therefore would tend to decrease the risk of complications connected with the valves in these grafts. .
Objetivo: Dentre as veias empregadas para revascularizações do miocárdio e de extremidades, a veia safena magna é a mais utilizada. Conhecer a presença e localização de válvulas é de grande importância quando se avalia a anatomia cirúrgica da veia safena magna. Apesar de grande aplicação cirúrgica e de muitos trabalhos envolvendo a veia safena magna, o número de válvulas presente nela desde o hiato safeno até o epicôndilo medial do fêmur ainda é descrito de forma imprecisa. O objetivo do presente trabalho é quantificar as válvulas da veia safena magna desde o hiato safeno até o epicôndilo medial do fêmur para determinar a melhor porção da veia safena magna para a realização de cirurgias de revascularização. Métodos: Este é um estudo transversal e observacional em que foram analisadas veias safena magna extraídas de 30 cadáveres. Foram realizadas as medidas das variáveis do comprimento das veias; (diâmetro) em suas porções proximal, média e distal; quantificação do número de válvulas nestas e número de válvulas total na veia safena magna. Resultados: A frequência de válvulas da veia safena contadas desde o epicôndilo medial do fêmur até o hiato safeno foi de 4,82, podendo variar entre 2 e 9. Além disso, houve diferença significante do número de válvulas da porção proximal em relação à média e distal. Conclusão: As porções média e distal da veia safena magna na coxa são as melhores opções para a realização de pontes em decorrência do fato destas porções terem menor quantidade de válvulas o que, portanto, tenderia a diminuir o risco de complicações relacionadas as válvulas nestes enxertos. .
Subject(s)
Adolescent , Adult , Aged , Aged, 80 and over , Female , Humans , Male , Middle Aged , Young Adult , Saphenous Vein/anatomy & histology , Venous Valves/anatomy & histology , Age Factors , Analysis of Variance , Cadaver , Cross-Sectional Studies , Coronary Artery Bypass/methods , Reference Values , Sex FactorsABSTRACT
BACKGROUND:Chronic venous insufficiency is a major health problem worldwide. Clinical treatments include venous valve repair and venous segment containing valve transplantation. However, these are invasive procedures, and the supply of vein containing valves is limited. Significant progress in the fields of tissue engineering and regenerative medicine has been made towards the creation of tissue engineered vascular grafts for the repair of damaged or malformed vessels. It has been reported that using tissue engineering, a tissue engineered vein containing valves constructed with self-derived endothelial cells and al ogeneic acellular matrices can provide the complex physiological valve structure and mechanical stability, but this elicited an immunogenic response. OBJECTIVE:To create a viable and functional vein containing valves, which has the ability to grow, repair, and imitate natural tissues. METHODS:Bone marrow mesenchymal stem cells were obtained from Beagle dogs by density gradient centrifugation and adherence methods. Bone marrow mesenchymal stem cells were cultured in vitro. Fol owing isolation and culture the cells were examined using flow cytometry and identified by direct induction towards the osteogenic and adipogenic lineages. We fabricated biodegradable venous scaffold containing valves using the method of injection molding combined with thermal y induced phase separation. Based on the self-made cast, a three-dimensional biodegradable vein scaffold containing valves was constructed from poly(lactic-co-glycolic acid). Morphological structure was tested. Bone marrow mesenchymal stem cells were used as seed cells to be seeded onto the lumen of the tissue engineered vein scaffold containing valves in vitro and then incubated for 2 weeks. RESULTS AND CONCLUSION:Scanning electron microscopy images showed that the scaffold demonstrated sufficient porosity. Cultured cells expressed mesenchymal cellmarkers, CD44 and CD29, but did not express hematopoietic cellmarkers, CD34 and CD45 at the same time point. Scaffolds were nontoxic to cells and were favorable for the growth and migration of bone marrow mesenchymal stem cells. cells attached on the surface of poly(lactic-co-glycolic acid) scaffolds formed a confluent layer after incubation. The cellular constructs were tested in vitro, and the valve leaflets were functional y capable of opening and closing when stimulated. These results suggested that the tissue engineered vein containing valves have been successful y constructed by using a three-dimensional poly(lactic-co-glycolic acid) scaffold and bone marrow mesenchymal stem cells as seed cells. Tissue engineered vein containing valves is potential y useful for the substitution and regeneration of vein valves.
ABSTRACT
Venous valve plays an important role in regulating the venous flow,especially in preventing the blood backflow.It has heen observed that when deep vein thrombosis and dissolved,the valves in the lesions had been destroied or dysfunction.The mechanism of damage of vein valve has not been fully clarified,but as we know,it's common that the inflammatory reaction,due to many unfavorable factors,can cause thrombosis.On the other hand,deep vein thrombosis could bring out the inflammatory reaction as well.So the author will review the development of researching of the destruction of venous valves in recent years.