https://www.selleckchem.com/products/phtpp.html Despite the noticeable advantages of the liposomes and polymersomes, they also revealed some drawbacks that could be minimized by preparing hybrid vesicular systems and integrating the advantage of both vehicles into one system named lipopolymersome. Lipopolymesome incorporates the biodegradability, stability, adjustability and chemical flexibility of polymersomes with the elasticity, soft nature and biocompatibility of liposomes. In the current study, wereported the development of five nanoscale lipopolymersomal hybrid vesicular systems consisting different molar ratios of dipalmitoylphosphatidylcholine (DPPC) and poly (ethylene glycol)-poly (lactic acid) (PEG-PLA) (PEG-PLA DPPC ratio of 1000, 5050 2575, 7525 and 0100). Rhod-6G-loaded hybrid vesicles were prepared via film rehydration. Then, the efficacy of five formulations were evaluated in terms of loading capacity, release pattern, cellular uptake, andin vivobiodistribution in ectopic tumor model in mice. The obtained results demonstrated that the self-assembly, loading capacity, cargo release and stability of hybrid nanoscale lipopolymersomes can be tuned by incorporation of amphiphilic lipid-polymers at various ratios. In this regard, the prepared hybrid nanovesicles consisting of DPPC-PEG-PLA (2575) exhibited great potential through superior loading capacity, stability and tumor accumulation compared with other systems. It could be concluded that the prepared lipopolymersome offers important opportunities for the development of novel hybrid carriers for efficient transportation of therapeutics into tumor site.Minimization of radiation coming from the chamber wall during lyophilization has the potential to reduce the edge-vial-effect. The edge-vial-effect is a phenomenon in which vials positioned at the shelf edges and corners tend to run warmer compared to center vials. A higher product temperature may result in product collapse in these vials. Consequently, mo