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- ItemLocal delivery to malignant brain tumors: potential biomaterial-based therapeutic/adjuvant strategies(Cambridge : RSC, 2021) Alghamdi, Majed; Gumbleton, Mark; Newland, BenGlioblastoma (GBM) is the most aggressive malignant brain tumor and is associated with a very poor prognosis. The standard treatment for newly diagnosed patients involves total tumor surgical resection (if possible), plus irradiation and adjuvant chemotherapy. Despite treatment, the prognosis is still poor, and the tumor often recurs within two centimeters of the original tumor. A promising approach to improving the efficacy of GBM therapeutics is to utilize biomaterials to deliver them locally at the tumor site. Local delivery to GBM offers several advantages over systemic administration, such as bypassing the blood-brain barrier and increasing the bioavailability of the therapeutic at the tumor site without causing systemic toxicity. Local delivery may also combat tumor recurrence by maintaining sufficient drug concentrations at and surrounding the original tumor area. Herein, we critically appraised the literature on local delivery systems based within the following categories: polymer-based implantable devices, polymeric injectable systems, and hydrogel drug delivery systems. We also discussed the negative effect of hypoxia on treatment strategies and how one might utilize local implantation of oxygen-generating biomaterials as an adjuvant to enhance current therapeutic strategies. © 2021 The Royal Society of Chemistry.
- ItemPoly(ethylene glycol) based nanotubes for tuneable drug delivery to glioblastoma multiforme(Cambridge : Royal Society of Chemistry, 2020) Alghamdi, Majed; Chierchini, Filippo; Eigel, Dimitri; Taplan, Christian; Miles, Thomas; Pette, Dagmar; Welzel, Petra B.; Werner, Carsten; Wang, Wenxin; Neto, Catia; Gumbleton, Mark; Newland, BenGlioblastoma multiforme (GBM) is the most aggressive type of malignant brain tumour, which is associated with a poor two-year survival rate and a high rate of fatal recurrence near the original tumour. Focal/local drug delivery devices hold promise for improving therapeutic outcomes for GBM by increasing drug concentrations locally at the tumour site, or by facilitating the use of potent anti-cancer drugs that are poorly permeable across the blood brain barrier (BBB). For inoperable tumours, stereotactic delivery to the tumour necessitates the development of nanoscale/microscale injectable drug delivery devices. Herein we assess the ability of a novel class of polymer nanotube (based on poly(ethylene glycol) (PEG)) to load doxorubicin (a mainstay breast cancer therapeutic with poor BBB permeability) and release it slowly. The drug loading properties of the PEG nanotubes could be tuned by varying the degree of carboxylic acid functionalisation and hence the capacity of the nanotubes to electrostatically bind and load doxorubicin. 70% of the drug was released over the first seven days followed by sustained drug release for the remaining two weeks tested. Unloaded PEG nanotubes showed no toxicity to any of the cell types analysed, whereas doxorubicin loaded nanotubes decreased GBM cell viability (C6, U-87 and U-251) in a dose dependent manner in 2Din vitroculture. Finally, doxorubicin loaded PEG nanotubes significantly reduced the viability ofin vitro3D GBM models whilst unloaded nanotubes showed no cytotoxicity. Taken together, these findings show that polymer nanotubes could be used to deliver alternative anti-cancer drugs for local therapeutic strategies against brain cancers. © The Royal Society of Chemistry 2020.
- ItemHeparin-based, injectable microcarriers for controlled delivery of interleukin-13 to the brain(Cambridge : Royal Soc. of Chemistry, 2020) Schirmer, Lucas; Hoornaert, Chloé; Le Blon, Debbie; Eigel, Dimitri; Neto, Catia; Gumbleton, Mark; Welzel, Petra B.; Rosser, Anne E.; Werner, Carsten; Ponsaerts, Peter; Newland, BenInterleukin-13 (IL-13) drives cells of myeloid origin towards a more anti-inflammatory phenotype, but delivery to the brain remains problematic. Herein, we show that heparin-based cryogel microcarriers load high amounts of IL-13, releasing it slowly. Intra-striatal injection of loaded microcarriers caused local up-regulation of ARG1 in myeloid cells for pro-regenerative immunomodulation in the brain. © 2020 The Royal Society of Chemistry.