Therapeutic cancer drug efficacy can be limited by insufficient tumor penetration, rapid clearance, systemic toxicity and (acquired) drug resistance. The poor therapeutic index due to inefficient... Show moreTherapeutic cancer drug efficacy can be limited by insufficient tumor penetration, rapid clearance, systemic toxicity and (acquired) drug resistance. The poor therapeutic index due to inefficient drug penetration and rapid drug clearance and toxicity can be improved by using a liposomal platform. Drug resistance for instance against pemetrexed, can be reduced by combination with docetaxel. Here, we developed a specific liposomal formulation to simultaneously deliver docetaxel and pemetrexed to enhance efficacy and safety. Hydrophobic docetaxel and hydrophilic pemetrexed were co-encapsulated into pH-sensitive liposomes using a thin-film hydration method with high efficiency. The physicochemical properties, toxicity, and immunological effects of liposomes were examined in vitro. Biodistribution, anti-tumor efficacy, and systemic immune response were evaluated in vivo in combination with PD-L1 immune checkpoint therapy using two murine colon cancer models. In cellular experiments, the liposomes exhibited strong cytotoxicity and induced immunogenic cell death. In vivo, the treatment with the liposome-based drug combination inhibited tumor development and stimulated immune responses. Liposomal encapsulation significantly reduced systemic toxicity compared to the delivery of the free drug. Tumor control was strongly enhanced when combined with anti-PDL1 immunotherapy in immunocompetent mice carrying syngeneic MC38 or CT26 colon tumors. We showed that treatment with liposome-mediated chemotherapy of docetaxel and pemetrexed combined with anti-PD-L1 immunotherapy is a promising strategy for the treatment of colon cancers. Show less
Artificial photosynthesis has recognised potential to produce green and sustainable fuels from earth-abundant resources such as water, carbon dioxide (CO2), and sunlight. In an artificial... Show moreArtificial photosynthesis has recognised potential to produce green and sustainable fuels from earth-abundant resources such as water, carbon dioxide (CO2), and sunlight. In an artificial photosynthetic system, two half-reactions, such as water oxidation and proton reduction or CO2 reduction, have to be combined. To achieve such a system, it is crucial to have: a) efficient light-harvesting by the photosensitiser, b) stable catalysts for the oxidation and the reduction reaction, c) unidirectional proton and electron transport between the oxidation and the reduction site, ideally by a recyclable electron relay, d) efficient charge separation, and e) a strong, photostable membrane that does not leak molecular components. In natural photosynthesis, these requirements are achieved altogether using compartmentalisation, which consists in embedding the key components of the system, i.e. for green plants the oxygen evolving complex, photosystem I and II, and the natural electron relays, around the lipid bilayer of the thylakoid membrane. The use of spherical lipid membranes (such as liposomes) as biological mimics of the thylakoid membrane is a promising approach to confine half-reactions, facilitate charge separation, and avoid charge recombination and other undesired side-reactions. In the research described in this thesis, it was attempted to realise a full artificial photosynthetic system based on liposomes and several of the key intermediate steps were achieved: 1) unidirectional electron transfer across a liposomal membrane from an electron donor encapsulated in the interior of the liposome to an electron acceptor located outside (Chapter 2), and 2) photocatalytic reduction of CO2 (Chapter 3) and of protons (Chapter 4) at the surface of liposomes. Special attention was paid in Chapter 2 and Chapter 5 to the question of the (photo)stability of the membrane and light-induced leakage. Show less
