1.
Generation and characterisation of decellularised human corneal limbus.
Spaniol, K, Witt, J, Mertsch, S, Borrelli, M, Geerling, G, Schrader, S
Graefe's archive for clinical and experimental ophthalmology = Albrecht von Graefes Archiv fur klinische und experimentelle Ophthalmologie. 2018;(3):547-557
Abstract
PURPOSE Limbal epithelial stem cells (LESC) reside in a niche in the corneo-scleral transition zone. Deficiency leads to pain, corneal opacity, and eventually blindness. LESC transplantation of ex-vivo expanded human LESC on a carrier such as human amniotic membrane is a current treatment option. We evaluated decellularised human limbus (DHL) as a potential carrier matrix for the transplantation of LESC. METHODS Human corneas were obtained from the local eye bank. The limbal tissue was decellularised by sodium desoxychelate and DNase solution and sterilised by γ-irradiation. Native limbus- and DHL-surface structures were assessed by scanning electron microscopy and collagen ultrastructure using transmission electron microscopy. Presence and preservation of limbal basement membrane proteins in native limbus and DHL were analysed immunohistochemically. Absence of DNA after decellularisation was assessed by Feulgen staining and DNA quantification. Presence of immune cells was explored by CD45 staining, and potential cytotoxicity was tested using a cell viability assay. RESULTS In the DHL, the DNA content was reduced from 1.5 ± 0.3 μg/mg to 0.15 ± 0.01 μg/mg; the three-dimensional structure and the arrangement of the collagen fibrils were preserved. Main basement membrane proteins such as collagen IV, laminin, and fibronectin were still present after decellularisation and γ-irradiation. CD45-expressing cells were evident neither in the native limbus nor in the DHL. DHL did not convey cytotoxicity. CONCLUSIONS The extracellular matrix (ECM) of the limbus provides a tissue specific morphology and three-dimensionality consisting of particular ECM proteins. It therefore represents a substantial component of the stem cell niche. The DHL provides a specific limbal niche surrounding, and might serve as an easily producible carrier matrix for LESC transplantation.
2.
Protein-inspired multilayer nanofilms: science, technology and medicine.
Haynie, DT, Zhang, L, Zhao, W, Rudra, JS
Nanomedicine : nanotechnology, biology, and medicine. 2006;(3):150-7
Abstract
The field of polypeptide multilayer nanofilm research flourishes where study of protein structure and function shares a border with development of polyelectrolyte multilayers. The soil is fertile for creative input and promises a harvest of interesting results: the structure of a film can be predetermined on a layer-by-layer (LBL) basis, a huge variety of polypeptide sequences can be realized in large quantities by modern methods of synthesis, and the fabrication process is environmentally benign. In electrostatic LBL assembly, multilayer film assembly is driven primarily by coulombic interactions, but hydrophobic interactions and hydrogen bonds also contribute to film formation and stability, the amount depending on polypeptide design. Most peptides suitable for LBL assembly form films with a large percentage of beta-sheet at neutral pH; it would appear that beta-sheet is favored over alpha-helix in this context by the contribution to entropy of the number of ways of forming a beta-sheet from a single polypeptide chain. Film thickness and roughness depend rather substantially on amino acid composition. Promising applications of the polypeptide multilayer film platform technology include coatings for medical implant devices, scaffolds for tissue engineering, coatings for targeted drug delivery, artificial cells for oxygen therapeutics, and artificial viruses for immunization. In each case peptide structure is tailored to the application. Here we summarize recent results of experimental studies and computational work from our laboratory, showing how the study of protein structure has inspired the design of polypeptide films and pointing out new opportunities for technology development. This work also provides a brief introduction to polypeptide structure and multilayer films.