Maturation and development of fetal pig intestinal tissue in immunodeficient mice.

PURPOSE: This study aimed to compare the degree of maturation and development of fetal pig segmental intestinal tissue with that of spheroids created by in-vitro reaggregation of dissociated fetal intestinal cells after transplantation into immunodeficient mice. METHODS: Fetal pig small intestines were transplanted as segmental grafts into the omentum and subrenal capsules of immunodeficient mice or enzymatically treated to generate single cells. Spheroids made by in-vitro reaggregation of these cells were transplanted into the subrenal capsules of immunodeficient mice. The segmental grafts and spheroids were harvested four and eight weeks after transplantation, and the structural maturity and in-vivo development of these specimens were histologically evaluated. RESULTS: The spheroids were engrafted and supplied blood vessels from the host mice, but an intestinal layered structure was not clearly observed, and there was almost no change in size. On the other hand, the segmental grafts formed deep crypts in the mucus membrane, the inner circular layer, and outer longitudinal muscles. The crypts of the transplanted grafts harvested at eight weeks were much deeper, and the smooth muscle layer and the enteric nervous system were more mature than those of grafts harvested at the fourth week, although the intestinal peristaltic wave was not observed. CONCLUSIONS: Spheroids created from fetal small intestinal cells could not form layered structures or mature sufficiently. Conversely, segmental tissues structurally matured and developed after in-vivo transplantation and are therefore potential grafts for transplantation.

Maturation and development of fetal pig intestinal tissue in immunodeficient mice

Purpose: This study aimed to compare the degree of maturation and development of fetal pig segmental intestinal tissue with that of spheroids created by in-vitro reaggregation of dissociated fetal intestinal cells after transplantation into immunodeficient mice. Methods: Fetal pig small intestines were transplanted as segmental grafts into the omentum and subrenal capsules of immunodeficient mice or enzymatically treated to generate single cells. Spheroids made by in-vitro reaggregation of these cells were transplanted into the subrenal capsules of immunodeficient mice. The segmental grafts and spheroids were harvested four and eight weeks after transplantation, and the structural maturity and in-vivo development of these specimens were histologically evaluated. Results: The spheroids were engrafted and supplied blood vessels from the host mice, but an intestinal layered structure was not clearly observed, and there was almost no change in size. On the other hand, the segmental grafts formed deep crypts in the mucus membrane, the inner circular layer, and outer longitudinal muscles. The crypts of the transplanted grafts harvested at eight weeks were much deeper, and the smooth muscle layer and the enteric nervous system were more mature than those of grafts harvested at the fourth week, although the intestinal peristaltic wave was not observed. Conclusions: Spheroids created from fetal small intestinal cells could not form layered structures or mature sufficiently. Conversely, segmental tissues structurally matured and developed after in-vivo transplantation and are therefore potential grafts for transplantation.

"Seat belt and air bag" technique for cerebral protection during carotid stenting.

PURPOSE: To present a 2-device technique for cerebral protection during carotid stenting of the internal carotid artery (ICA) in patients with high-grade lesions, contralateral occlusion, and/or an aberrant or nonfunctioning circle of Willis. TECHNIQUE: A reverse flow system (Parodi Anti-Embolism System [PAES]) is first placed with a 260-cm exchange wire in the common carotid artery 3 cm below the carotid bifurcation. Flow reversal is obtained by inflating the balloons in the external and common carotid arteries. Via an external connector, a guidewire and E-Trap filter are delivered to the distal ICA with active suction from a syringe on the PAES catheter. Once the filter is above the stenosis, the reversed flow is discontinued, and the procedure proceeds under cerebral protection with the filter. CONCLUSIONS: The combination of 2 existing cerebral protection devices could, at least in theory, achieve what neither of them could independently. The "seat belt and air bag" approach may represent the ideal means of treating ICA stenoses in patients with a non-functioning circle of Willis.