Generación in vitro de un sustituto de pared vesical humana obtenido mediante ingeniería tisular / In vitro generation of a human bladder wall substitute by tissue engineering

Objetivos. Numerosas patologías que afectan a la vejiga, de origen congénito (extrofia) o adquirido (traumatismos, tumores), requieren la reconstrucción de la pared vesical utilizando intestino delgado, sigma o estómago, los cuales no están exentos de complicaciones. Por ese motivo, en el presente trabajo pretendemos desarrollar un nuevo modelo de pared vesical humana mediante ingeniería tisular que pudiese tener una utilidad clínica. Material y métodos. En primer lugar, se procedió a generar cultivos primarios de células epiteliales y estromales de la mucosa vesical a partir de pequeñas biopsias de la pared vesical humana, utilizando para ello técnicas de digestión enzimática mediante tripsina-EDTA y colagenasa. Posteriormente, se generó un sustituto tridimensional de la mucosa vesical utilizando como soporte biomateriales de fibrina-agarosa. El análisis de las muestras se realizó a los 14 días mediante examen histológico de muestras teñidas con hematoxilina-eosina. Resultados. La aplicación de los métodos de digestión enzimática permitió generar eficientemente cultivos primarios de células epiteliales y estromales de la mucosa vesical humana, comprobándose que la tasa de proliferación de las células estromales era superior a la de las células epiteliales. Una vez generados los sustitutos de la pared vesical, se comprobó el adecuado nivel de biocompatibilidad del biomaterial y las células estromales y epiteliales. La estructura histológica de los sustitutos de pared vesical presentaba una gran analogía con la mucosa vesical humana nativa. Conclusiones. El tejido vesical generado por ingeniería tisular muestra importantes similitudes estructurales e histológicas con el tejido vesical nativo. Estos resultados sugieren que los tejidos generados mediante ingeniería tisular podrían tener utilidad terapéutica en el futuro (AU)

Introduction. Certain urological congenital conditions, such as bladder exstrophy and acquired conditions such as trauma and tumors may require the use of different tissues like small bowel, sigmoid colon or stomach for bladder reconstruction. However, these tissues are often associated to important complications. The aim of this study is to develop a novel substitute of the human bladder wall by tissue engineering. Material and methods. We first generated primary cell cultures of epithelial and stromal bladder mucosa cells from small tissue biopsies of human bladder by using enzymatic methods based on trypsin-EDTA and collagenase I. Then, a three-dimensional substitute of the bladder mucosa was generated using fibrin-agarose biomaterials. The analysis of the tissue substitutes was carried out at day 14th of development by histological examination of samples stained with hematoxylin-eosin. Results. The use of enzymatic digestion methods allowed us to efficiently generate primary cell cultures of the human bladder epithelial and stromal cells. The proliferation rate was higher in stromal cells as compared to epithelial cells. Once the bladder mucosa substitutes were generated, a good biocompatibility of the stromal and epithelial cells into the biomaterial was found. The histological structure of the bladder wall substitutes was analogue to that of the native human bladder mucosa. Conclusions. The bladder mucosa substitute generated by tissue engineering showed structural and histological similarities with the native human bladder tissues and open the door to the future therapeutic use of these bioengineered tissues (AU)

[In vitro generation of a human bladder wall substitute by tissue engineering]. / Generación in vitro de un sustituto de pared vesical humana obtenido mediante ingeniería tisular.

INTRODUCTION: Certain urological congenital conditions, such as bladder exstrophy and acquired conditions such as trauma and tumors may require the use of different tissues like small bowel, sigmoid colon or stomach for bladder reconstruction. However, these tissues are often associated to important complications. The aim of this study is to develop a novel substitute of the human bladder wall by tissue engineering. MATERIAL AND METHODS: We first generated primary cell cultures of epithelial and stromal bladder mucosa cells from small tissue biopsies of human bladder by using enzymatic methods based on trypsin-EDTA and collagenase I. Then, a three-dimensional substitute of the bladder mucosa was generated using fibrin-agarose biomaterials. The analysis of the tissue substitutes was carried out at day 14th of development by histological examination of samples stained with hematoxylin-eosin. RESULTS: The use of enzymatic digestion methods allowed us to efficiently generate primary cell cultures of the human bladder epithelial and stromal cells. The proliferation rate was higher in stromal cells as compared to epithelial cells. Once the bladder mucosa substitutes were generated, a good biocompatibility of the stromal and epithelial cells into the biomaterial was found. The histological structure of the bladder wall substitutes was analogue to that of the native human bladder mucosa. CONCLUSIONS: The bladder mucosa substitute generated by tissue engineering showed structural and histological similarities with the native human bladder tissues and open the door to the future therapeutic use of these bioengineered tissues.