Engineering transplantable human lymphatic and blood capillary networks in a porous scaffold
Journal article
Kong, Anne M., Lim, Shiang Y., Palmer, Jason A., Rixon, Amanda, Gerrand, Yi-Wen, Yap, Kiryu K., Morrison, Wayne A. and Mitchell, Geraldine M.. (2022). Engineering transplantable human lymphatic and blood capillary networks in a porous scaffold. Journal of Tissue Engineering. 13, pp. 1-21. https://doi.org/10.1177/20417314221140979
Authors | Kong, Anne M., Lim, Shiang Y., Palmer, Jason A., Rixon, Amanda, Gerrand, Yi-Wen, Yap, Kiryu K., Morrison, Wayne A. and Mitchell, Geraldine M. |
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Abstract | Due to a relative paucity of studies on human lymphatic assembly in vitro and subsequent in vivo transplantation, capillary formation and survival of primary human lymphatic (hLEC) and blood endothelial cells (hBEC) ± primary human vascular smooth muscle cells (hvSMC) were evaluated and compared in vitro and in vivo. hLEC ± hvSMC or hBEC ± hvSMC were seeded in a 3D porous scaffold in vitro, and capillary percent vascular volume (PVV) and vascular density (VD)/mm2 assessed. Scaffolds were also transplanted into a sub-cutaneous rat wound with morphology/morphometry assessment. Initially hBEC formed a larger vessel network in vitro than hLEC, with interconnected capillaries evident at 2 days. Interconnected lymphatic capillaries were slower (3 days) to assemble. hLEC capillaries demonstrated a significant overall increase in PVV (p = 0.0083) and VD (p = 0.0039) in vitro when co-cultured with hvSMC. A similar increase did not occur for hBEC + hvSMC in vitro, but hBEC + hvSMC in vivo significantly increased PVV (p = 0.0035) and VD (p = 0.0087). Morphology/morphometry established that hLEC vessels maintained distinct cell markers, and demonstrated significantly increased individual vessel and network size, and longer survival than hBEC capillaries in vivo, and established inosculation with rat lymphatics, with evidence of lymphatic function. The porous polyurethane scaffold provided advantages to capillary network formation due to its large (300–600 μm diameter) interconnected pores, and sufficient stability to ensure successful surgical transplantation in vivo. Given their successful survival and function in vivo within the porous scaffold, in vitro assembled hLEC networks using this method are potentially applicable to clinical scenarios requiring replacement of dysfunctional or absent lymphatic networks. |
Keywords | primary human lymphatic endothelial cells; primary human blood endothelial cells; capillary networks in vitro 3D coculture; in vivo transplantation |
Year | 2022 |
Journal | Journal of Tissue Engineering |
Journal citation | 13, pp. 1-21 |
Publisher | SAGE Publications |
ISSN | 2041-7314 |
Digital Object Identifier (DOI) | https://doi.org/10.1177/20417314221140979 |
PubMed ID | 36600999 |
Scopus EID | 2-s2.0-85145021340 |
PubMed Central ID | PMC9806376 |
Open access | Published as ‘gold’ (paid) open access |
Page range | 1-21 |
Funder | St Vincent’s Hospital, Melbourne |
Australian Catholic University (ACU) | |
Stafford Fox Medical Research Foundation | |
Operational Infrastructure Support (OIS) Program, Victorian Government | |
Research Training Program Scholarship (RTP), Australian Government | |
National Health and Medical Research Council (NHMRC) | |
Australian and Aotearoa New Zealand, Hepatic, Pancreatic & Biliary Association | |
St Vincent’s Institute of Medical Research | |
Publisher's version | License File Access Level Open |
Output status | Published |
Publication dates | |
Online | 26 Dec 2022 |
Publication process dates | |
Accepted | 08 Nov 2022 |
Deposited | 03 Aug 2023 |
https://acuresearchbank.acu.edu.au/item/8z715/engineering-transplantable-human-lymphatic-and-blood-capillary-networks-in-a-porous-scaffold
Download files
Publisher's version
OA_Kong_2022_Engineering_transplantable_human_lymphatic_and_blood.pdf | |
License: CC BY-NC 4.0 | |
File access level: Open |
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