- Affas, Saif;
- Schäfer, Frank-Mattias;
- Algarrahi, Khalid;
- Cristofaro, Vivian;
- Sullivan, Maryrose P;
- Yang, Xuehui;
- Costa, Kyle;
- Sack, Bryan;
- Gharaee-Kermani, Mehrnaz;
- Macoska, Jill A;
- Gundogdu, Gokhan;
- Seager, Catherine;
- Estrada, Carlos R;
- Mauney, Joshua R
Impact statement
The search for an ideal "off-the-shelf" biomaterial for augmentation cystoplasty remains elusive and current scaffold configurations are hampered by mechanical and biocompatibility restrictions. In addition, preclinical evaluations of potential scaffold designs for bladder repair are limited by the lack of tractable large animal models of obstructive bladder disease that can mimic clinical pathology. The results of this study describe a novel, minimally invasive, porcine model of partial bladder outlet obstruction that simulates clinically relevant phenotypes. Utilizing this model, we demonstrate that acellular, bi-layer silk fibroin grafts can support the formation of vascularized, innervated bladder tissues with functional properties.