In cardiovascular tissue engineering approaches, efficient seeding methods are essential. To achieve this and to save time, cells can be encapsulated in gels. Combining the advantages of a gel as a cell carrier with the advantages of a fiber-based scaffold, providing structural integrity to the developing tissue, might offer several advantages. In this study, seeding by using fibrin as a cell carrier is compared to the conventional static seeding method with regard to tissue development. Seeding with fibrin resulted in less loss of soluble collagen into the medium and a more mature extracellular matrix in a shorter period of time. The use of fibrin degradation inhibitors was shown to inhibit extracellular matrix formation, although it did n...
Fibrin gels are an ideal natural biological scaffold for tissue engineering because they are biocomp...
Background—In heart valve tissue engineering, the optimization of tissue properties has to be combin...
Fibrin has been proposed as cell scaffold for numerous tissue engineering applications. While most o...
In cardiovascular tissue engineering approaches, efficient seeding methods are essential. To achieve...
Fibrin is a natural biopolymer with many interesting properties, such as biocompatibility, bioresorb...
Due to the increasing needs for organ transplantation and a universal shortage of donated tissues, t...
Objective: In tissue engineering, three-dimensional biodegradable scaffolds are generally used as a ...
This review looks at the use of fibrin in vascular tissue engineering (VTE). Autologous fibrin is on...
Cardiac tissue engineering aims at restoring cell compartment along with myocardial extracellular mi...
Therapeutic angiogenesis aims at promoting the growth of blood vessels to restore perfusion in ische...
Cardiac tissue engineering (CTE) is a promising approach to replace and regenerate the injured and n...
Due to the increasing needs for organ transplantation and a universal shortage of donated tissues, t...
Aims: Peripheral blood endothelial progenitor cells (EPC) are promising therapies for irreversible m...
Vascular tissue engineering combines cells with scaffold materials in vitro aiming the development o...
Fibrin gels are an ideal natural biological scaffold for tissue engineering because they are biocomp...
Background—In heart valve tissue engineering, the optimization of tissue properties has to be combin...
Fibrin has been proposed as cell scaffold for numerous tissue engineering applications. While most o...
In cardiovascular tissue engineering approaches, efficient seeding methods are essential. To achieve...
Fibrin is a natural biopolymer with many interesting properties, such as biocompatibility, bioresorb...
Due to the increasing needs for organ transplantation and a universal shortage of donated tissues, t...
Objective: In tissue engineering, three-dimensional biodegradable scaffolds are generally used as a ...
This review looks at the use of fibrin in vascular tissue engineering (VTE). Autologous fibrin is on...
Cardiac tissue engineering aims at restoring cell compartment along with myocardial extracellular mi...
Therapeutic angiogenesis aims at promoting the growth of blood vessels to restore perfusion in ische...
Cardiac tissue engineering (CTE) is a promising approach to replace and regenerate the injured and n...
Due to the increasing needs for organ transplantation and a universal shortage of donated tissues, t...
Aims: Peripheral blood endothelial progenitor cells (EPC) are promising therapies for irreversible m...
Vascular tissue engineering combines cells with scaffold materials in vitro aiming the development o...
Fibrin gels are an ideal natural biological scaffold for tissue engineering because they are biocomp...
Background—In heart valve tissue engineering, the optimization of tissue properties has to be combin...
Fibrin has been proposed as cell scaffold for numerous tissue engineering applications. While most o...