Vascular Biology

Current research projects

• Pre-vascularisation of porous scaffolds for wound healing

  The aim of this study is to form human capillary (small blood vessel) networks from human endothelial cells and transplant into animal wound models. This project aims to increase the number of blood vessels in difficult to heal wounds.

  Staff members involved: Dr Anne Kong and Associate Professor Geraldine Mitchell

  Relevant publications

  Kong AM, Yap KK, Lim SY, Marre D, Pebay A, Gerrand Y-W, Palmer JA, Lees JG, Morrison WA and Mitchell GM, Bio-engineering a tissue flap utilizing a porous scaffold incorporating a human induced pluripotent stem cell derived endothelial cell capillary network connected to a vascular pedicle. Acta Biomaterialia. 2019 Aug;94:281-294.

  Kong AM, Lim SY, Palmer JA, Rixon A, Gerrand Y-W, Yap KK, Morrison WA and Mitchell GM, Engineering transplantable human lymphatic and blood capillary networks in a porous scaffold, Accepted for publication in the Journal of Tissue Engineering, November 7, 2022.

  Creating a human liver organoid to treat liver disease

  The project aims to assemble human liver organoids from liver progenitor cells, liver endothelial cells and mesenchymal stem cells. The cells are isolated from human liver and fat tissues available from discarded tissues at operation. In parallel, we are also deriving these cells from human induced pluripotent stem cells and also forming human liver-like organoids. All organoids are formed in the laboratory, with the aim of using them to replace diseased liver tissue in a patient.

  Dr Kiryu Yap and Ms Yi-wen Gerrand are completing this project. They have had other staff members and students involved, including: Mr Samarth Khandelwal and Ms Evelyn Makris (Honours students), Ms Pu-Han Lo and Mr Denis Shi (Research Assistants).

  Relevant publications

  Yap KK, Dingle AM, Palmer JA, Dhillon R, Lokmic Z, Penington AJ, Yeoh GC, Morrison WA, Mitchell GM, Enhanced liver progenitor cell survival and differentiation in vivo by spheroid implantation in a vascularized tissue engineering chamber, Biomaterials. 2013 May;34(16):3992-4001.

  Yap KK, Yeoh GC, Morrison WA, Mitchell GM. The vascularised chamber as an in vivo bioreactor. Trends in Biotechnology, 2018 Oct;36(10):1011-1024.

  Dingle AM^*, Yap KK^*, Gerrand Y-W, Taylor CJ, Keramidaris E, Lokmic Z, Kong AM, Peters HL, Morrison WA and Mitchell GM. Characterization of isolated liver sinusoidal endothelial cells for liver bio-engineering. Angiogenesis, 2018, 21(3), 581-597. *joint first authors.

  Yap KK, Gerrand Y-W, Dingle AM, Yeoh GC, Morrison WA, Mitchell GM, Liver sinusoidal endothelial cells promote the differentiation and survival of mouse vascularised hepatobiliary organoids. Biomaterials. 2020 Aug;251:120091. doi: 10.1016/j.biomaterials.2020.120091.

  Yap KK, Mitchell GM, Recapitulating the liver niche in vitro. In Nilsson S (editor): ‘Recapitulating the stem cell niche ex vivo’ Chapter 1, published by Elsevier, July 2022.

  Bio-engineering a skin flap

  Tissue flaps are used routinely in reconstructive surgery for coverage of acute or chronic wounds caused by trauma, cancer resection, and diabetes. Flaps consist of a large artery and vein (vascular pedicle) connected to a capillary network within a block of skin/fat/muscle. Flaps are harvested from one area of the body to cover defects at another site. However, tissue flaps have limited availability, are morbid and involve complex, costly surgery with high complication rates. A bioengineered alternative would be a major advance in the field of reconstructive surgery.

  This research project aims to connect human induced Pluripotent Stem Cell (hiPSC)-derived small blood vessels assembled in the lab to a 3D printed branched larger vessel seeded with hiPSC endothelial cells (ECs), and hiPSC derived vascular smooth muscle cells (vSMC), thus forming a human tissue flap in vitro. The blood vessel components will be covered by hiPSC-derived skin.

   

  Dr Cathal O’Connell (RMIT) supervises the 3D printing of the branched vessels. Dr Anne Kong and Dr Kate Firipis and Associate Professor Geraldine Mitchell are other group members involved in this project.