Tissue engineering of the stomach.

Tissue engineering combines engineering principles with the biological sciences to create functional replacement tissues. The underlying principle of tissue engineering is that isolated cells combined with biomaterials can form new tissues and organs in vitro and in vivo. This review focuses on stomach tissue engineering, which is a promising approach to the treatment of gastric cancer, the fourth most common malignancy in the world and the second-leading cause of cancer mortality worldwide.

Assessment of a tissue-engineered gastric wall patch in a rat model.

Stenosis or deformity of the remaining stomach can occur after gastrectomy and result in stomach malfunction. The objective of this study is to demonstrate the feasibility of transplanting a tissue-engineered gastric wall patch in a rat model to alleviate the complications after resection of a large area of the gastric wall. Tissue-engineered gastric wall patches were created from gastric epithelial organoid units and biodegradable polymer scaffolds.

A tissue-engineered stomach shows presence of proton pump and G-cells in a rat model, resulting in improved anemia following total gastrectomy.

Despite advances in surgical reconstruction, total gastrectomy still is accompanied by various complications, especially chronic ones, such as pernicious anemia, resulting in refractory malnutrition. As an alternative approach, we have proposed a tissue-engineered stomach as a replacement of the native stomach. This study aimed to assess the secretory functions of a tissue-engineered stomach in a rat model and the nutritional status of the recipients over an extended time period.

Initial assessment of a tissue engineered stomach derived from syngeneic donors in a rat model.

The objective of this study is to assess the feasibility of creating a tissue engineered stomach using isolated stomach epithelium organoid unit from syngeneic adult donors and a biodegradable polymer scaffold in a rat model. Despite recent advances in reconstruction techniques, total gastrectomy is still accompanied by various complications. As an alternative treatment, a tissue engineered stomach that replaces the mechanical and metabolic functions of a normal stomach is proposed.

A tissue-engineered stomach as a replacement of the native stomach.

Background: Despite recent advances in reconstruction techniques, total gastrectomy is still accompanied by various complications. As an alternative treatment, we propose a tissue-engineered stomach that replaces the mechanical and metabolic functions of a normal stomach. The objective of this study was to demonstrate the function of a tissue-engineered stomach as a replacement of the native stomach.