Antimicrobial Properties of Extracellular Matrix Scaffolds for Tissue Engineering.

The necessity to manufacture graft materials with superior biocompatibility capabilities and biodegradability characteristics for tissue regeneration has led to the production of extracellular matrix- (ECM-) based scaffolds. Among their advantages are better capacity to allow cell colonization, which enables its successful integration into the tissue surrounding the area to be repaired. In addition, it has been shown that some of these scaffolds have antimicrobial activity, preventing possible infections; therefore, it could be used as an alternative to control surgical infection and decrease the use of antimicrobial agents. The purpose of this review is to collect the existing information about antimicrobial activity of the ECM and their components.

Evaluation of decellularized matrix and ß-tricalcium phosphate as biomaterials for bone neoformation: in vivo study / Evaluación de la matriz descelularizada y ß-fosfato tricálcico como biomateriales para neoformación ósea: estudio in vivo

The aim of this study was to evaluate histologically the effect of two biomaterials, a biomaterial derived from porcine Urinary submucosa Bladder Matrix (UBM) and beta-TriCalcium Phosphate (ß-TCP), on bone defects. Twenty male New Zealand rabbits were used; the models were divided in two groups: the UBM group; the ß-TCP group, and a Negative Control (NC) group. Five-mm defects were created in the femur of each model and then the different biomaterials were set in place depending on each group. At 4 and 8 weeks, the animals in the models were sacrificed and samples of the defect site were collected to perform a Hematoxylin and Eosin stain (H&E). Histologically, ß-TCP group at 4 and 8 weeks presented neoformation of bone-like and cartilage-like tissue, with the presence of inflammatory infiltrate; at 4 and 8 weeks, the UBM group presented neoformation of bone-like and cartilage-like tissue with a low presence of inflammatory infiltrate, and the NC group presented the formation of connective tissue and, in a low proportion, neoformation of bone tissue and cartilage. Both biomaterials, UBM and ß-TCP, exhibited the capacity to promote bone neoformation; however, the UBM-based biomaterial produced a better-organized tissue with a lower inflammatory response compared with the ß-TCP group.

El objetivo de este estudio fue evaluar histológicamente el efecto de dos biomateriales: derivado de matriz de submucosa de vejiga urinaria porcina (UBM) y b-fosfato tricálcico (ß-TCP) en defectos óseos. Veinte conejos macho de raza Nueva Zelanda fueron empleados para este estudio; los modelos fueron divididos en dos grupos: UBM, ß-TCP y un grupo control negativo. Se crearon defectos de 5 mm en el fémur de cada uno de los modelos y posteriormente se colocó el biomaterial correspondiente de acuerdo a cada uno de los grupos. A las 4 y 8 semanas los modelos fueron sacrificados y se tomaron muestras del sitio del defecto óseo para realizar una tinción de Hematoxilina y Eosina. Histológicamente el grupo de ß-TCP tanto a las 4 como a las 8 semanas mostró neoformación de tejido óseo y tejido cartilaginoso con presencia de infiltrado inflamatorio; el grupo de UBM a las 4 y 8 semanas presentó neoformación de tejido óseo, tejido cartilaginoso y un bajo infiltrado inflamatorio; el grupo control negativo presentó formación de tejido conectivo y en baja proporción neoformación de tejido óseo y cartílago. Ambos biomateriales, UBM y ß-TCP mostraron la capacidad de promover la neoformación de tejido óseo; sin embargo, el biomaterial basado en UBM produjo un tejido mejor organizado y un menor infiltrado inflamatorio en comparación con el ß-TCP.

Quantification of DNA in urinary porcine bladder matrix using the ACTB gene.

Extracellular matrix (ECM) is a rich network of proteins and proteoglycans that has proved to be very useful in tissue regeneration. Porcine ECM has been proposed as a biological scaffold, and urinary bladder matrix (UBM) has demonstrated superior biological properties; however, its use in human treatment requires ensuring that it is DNA free. Several protocols have been used for decellularization and to demonstrate the absence of DNA, but until now, a porcine housekeeping gene for quantifying DNA by real-time quantitative PCR (qPCR) has been limiting. The aim of this study was to propose a protocol to quantify the DNA content of decellularized UBM by qPCR for the beta-actin gene (ACTB). A total of 20 porcine bladders were used, and each bladder was divided into three pieces: one as a control and the others decellularized with either SDS or Triton X-100 detergent. The presence of DNA was assessed by histology, spectrophotometry, conventional PCR, and qPCR for the ACTB. Histological analysis demonstrated the absence of nuclei using both protocols. Spectrophotometrical evaluation resulted in DNA concentrations of 1561.4 ± 357.1 and 1211.9 ± 635.2 ng of DNA/mg dry weight after the SDS and Triton X-100 protocols, respectively. DNA was not detected in any protocol by conventional PCR. In contrast, using qPCR, we found 3.9 ± 2.8 ng of DNA/mg dry weight in the Triton X-100 protocol. Therefore, the use of qPCR is a reliable method to quantify residual DNA content after decellularization procedures.