Abstract
AIMS
A hyaluronic acid-based hydrogel with mechanical properties comparable to human brain tissue is being investigated as an implantable drug-delivery vehicle for post-surgical treatment of IDH1 wild-type glioblastoma (GBM). Hydrogels are to be loaded with polymeric pro-drug nanoparticles to enable controlled drug release and increased drug penetration through brain parenchyma for enhanced treatment of residual disease within and beyond the invasive margin.
METHOD
A panel of patient-derived glioblastoma cell lines resected from tumour core and invasive margin, have been used to generate tumour spheroids. Chemotherapeutic drug screening has been performed to select lead compounds for formulation and gel loading. Synergies of drug combinations have been studied for potential combination loading. Upcoming work will investigate nanoparticle internalisation, spheroid penetration and prodrug nanoparticle potency. Nanoparticle loaded hydrogels are then to be studied for validation of effective in vitro application.
RESULTS
Current results demonstrate that patient-derived cell lines can generate robust, reproducible tumour spheroids with diameters approx. 350-400 µm. Patient-to-patient differences in drug potencies were observed, with differences also noted between counterpart core and marginal cells from the same patients, illustrating the importance of using patient-derived cells and distinct regional cells to study heterogenous disease such as GBM. Drug combination experiments indicated synergy of topoisomerase I inhibitor (Irinotecan) with PARP inhibitor (Ola-parib). Interestingly, combination of PARP inhibition with topoisomerase II inhibitors (Doxorubicin, Etoposide) was found not synergistic.
CONCLUSION
Together, data gathered on single drug and drug-drug combinations will inform upcoming formulation and in vitro application of hydrogels planned, with eventual translation to pre-clinica l in vivo models.
Δεν υπάρχουν σχόλια:
Δημοσίευση σχολίου