References
- Abreu, A.S., et al., 2011. Nanoliposomes for encapsulation and delivery of the potential antitumoral methyl 6-methoxy-3-(4-methoxyphenyl)-1H-indole-2-carboxylate. Nanoscale Research Letters, 6 (1), 482.
- Ahmed, F., and Discher, D.E., 2004. Self-porating polymersomes of PEG-PLA and PEG-PCL: hydrolysis-triggered controlled release vesicles. Journal of controlled release : official journal of the controlled release society, 96 (1), 37–53.
- Bangham, A.D., Standish, M.M., and Watkins, J.C., 1965. Diffusion of univalent ions across the lamellae of swollen phospholipids. Journal of molecular biology, 13 (1), 238–252.
- Ciobanasu, C., Dragomir, I., and Apetrei, A., 2019. The penetrating properties of the tumor homing peptide LyP-1 in model lipid membranes. Journal of Peptide Science : An Official Publication of the European Peptide Society, 25 (3), e3145.
- D'avanzo, N., et al., 2021. LinTT1 peptide-functionalized liposomes for targeted breast cancer therapy. International journal of pharmaceutics, 597, 120346.
- Deplazes, E., et al., 2018. The effect of H(3)O(+) on the membrane morphology and hydrogen bonding of a phospholipid bilayer. Biophysical reviews, 10, 1371–1376.
- Ferrauto, G., et al., 2021. Detection of U-87 Tumor Cells by RGD-Functionalized/Gd-Containing Giant Unilamellar Vesicles in Magnetization Transfer Contrast Magnetic Resonance Images. Investigative Radiology, 56 (5), 301–312.
- Fritze, A., et al., 2006. Remote loading of doxorubicin into liposomes driven by a transmembrane phosphate gradient. Biochimica et Biophysica Acta, 1758 (10), 1633–1640.
- Göpfrich, K., et al., 2019. One-pot assembly of complex giant unilamellar vesicle-based synthetic cells. ACS synthetic biology, 8 (5), 937–947.
- Guo, C., et al., 2021. Asymmetric polymersomes, from the formation of asymmetric membranes to the application on drug delivery. Journal of controlled release : official journal of the controlled release society, 338, 422–445.
- Hajal, C., et al., 2018. In vitro models of molecular and nano-particle transport across the blood-brain barrier. Biomicrofluidics, 12 (4), 042213.
- Has, C., Phapal, S.M., and Sunthar, P., 2018. Rapid single-step formation of liposomes by flow assisted stationary phase interdiffusion. Chemistry and physics of lipids, 212, 144–151.
- Hwang, S.Y., et al., 2012. Effects of operating parameters on the efficiency of liposomal encapsulation of enzymes. Colloids and surfaces. B, biointerfaces, 94, 296–303.
- Jahn, A., et al., 2010. Microfluidic mixing and the formation of nanoscale lipid vesicles. American chemical society nano, 4 (4), 2077–2087.
- Jin, Z., et al., 2021. Dual functional nanoparticles efficiently across the blood-brain barrier to combat glioblastoma via simultaneously inhibit the PI3K pathway and NKG2A axis. Journal of drug targeting, 29 (3), 323–335.
- Kaddah, S., et al., 2018. Cholesterol modulates the liposome membrane fluidity and permeability for a hydrophilic molecule. Food and chemical toxicology : an international journal published for the british industrial biological research association, 113, 40–48.
- Kang, T., et al., 2016. Synergistic targeting tenascin C and neuropilin-1 for specific penetration of nanoparticles for anti-glioblastoma treatment. Biomaterials, 101, 60–75.
- Kastner, E., et al., 2014. High-throughput manufacturing of size-tuned liposomes by a new microfluidics method using enhanced statistical tools for characterization. International journal of pharmaceutics, 477 (1-2), 361–368.
- Khondee, S., et al., 2018. Doxorubicin-loaded micelle targeting muc1: a potential therapeutic for muc1 triple negative breast cancer treatment. Current drug delivery, 15 (3), 406–416.
- Li, M., et al., 2019a. Composition design and medical application of liposomes. European journal of medicinal chemistry, 164, 640–653.
- Li, X., et al., 2019b. Enhanced copper-temozolomide interactions by protein for chemotherapy against glioblastoma multiforme. ACS applied materials & interfaces, 11 (45), 41935–41945.
- Liang, X., Mao, G., and Ng, K.Y., 2004. Mechanical properties and stability measurement of cholesterol-containing liposome on mica by atomic force microscopy. Journal of colloid and interface science, 278 (1), 53–62.
- Lou, G., et al., 2019. A novel microfluidic-based approach to formulate size-tuneable large unilamellar cationic liposomes: formulation, cellular uptake and biodistribution investigations. European journal of pharmaceutics and biopharmaceutics : official journal of arbeitsgemeinschaft fur pharmazeutische verfahrenstechnik e.v, 143, 51–60.
- Lu, F., et al., 2017. Angiopep-2-conjugated poly(ethylene glycol)-co- poly(ε-caprolactone) polymersomes for dual-targeting drug delivery to glioma in rats. International journal of nanomedicine, 12, 2117–2127.
- Maritim, S., Boulas, P., and Lin, Y., 2021. Comprehensive analysis of liposome formulation parameters and their influence on encapsulation, stability and drug release in glibenclamide liposomes. International journal of pharmaceutics, 592, 120051.
- Mazarei, M., et al., 2021. Anticancer potential of temozolomide-loaded eudragit-chitosan coated selenium nanoparticles: in vitro evaluation of cytotoxicity, apoptosis and gene regulation. Nanomaterials (Basel, Switzerland), 11, 1704.
- Moga, A., et al., 2019. Optimization of the inverted emulsion method for high-yield production of biomimetic giant unilamellar vesicles. Chembiochem : a European journal of chemical biology, 20 (20), 2674–2682.
- Nakhaei, P., et al., 2021. Liposomes: structure, biomedical applications, and stability parameters with emphasis on cholesterol. Frontiers in bioengineering and biotechnology, 9, 705886.
- Panahi, Y., et al., 2017. Recent advances on liposomal nanoparticles: synthesis, characterization and biomedical applications. Artificial cells, nanomedicine, and biotechnology, 45 (4), 788–799.
- Patil, Y.P., and Jadhav, S., 2014. Novel methods for liposome preparation. Chemistry and physics of lipids, 177, 8–18.
- Ramachandran, C., et al., 2012. Potentiation of etoposide and temozolomide cytotoxicity by curcumin and turmeric force™ in brain tumor cell lines. Journal of complementary & integrative medicine, 9, Article 20.
- Roque, M.C., et al., 2019. Development of long-circulating and fusogenic liposomes co-encapsulating paclitaxel and doxorubicin in synergistic ratio for the treatment of breast cancer. Current drug delivery, 16 (9), 829–838.
- Shah, S., et al., 2020. Liposomes: advancements and innovation in the manufacturing process. Advanced drug delivery reviews, 154–155, 102–122.
- Su, X., et al., 2020. Preparation and characterization of angiopep-2 functionalized Ginsenoside-Rg3 loaded nanoparticles and the effect on C6 Glioma cells. Pharmaceutical development and technology, 25 (3), 385–395.
- Vijayakumar, M.R., et al., 2016. Pharmacokinetics, biodistribution, in vitro cytotoxicity and biocompatibility of Vitamin E TPGS coated trans resveratrol liposomes. Colloids and surfaces. B, biointerfaces, 145, 479–491.
- Wang, Q., et al., 2017. Ion concentration effect (Na(+) and Cl(-)) on lipid vesicle formation. Colloids and surfaces. B, biointerfaces, 155, 287–293.
- Wang, Y., et al., 2020. A dual receptors-targeting and size-switchable "cluster bomb" co-loading chemotherapeutic and transient receptor potential ankyrin 1 (TRPA-1) inhibitor for treatment of triple negative breast cancer. Journal of controlled release : official journal of the controlled release society, 321, 71–83.
- Wang, Y., et al., 2022. Investigations on the influence of the structural flexibility of nanoliposomes on their properties. Journal of liposome research, 32 (1), 92–103.
- Winterhalter, M., and Lasic, D.D., 1993. Liposome stability and formation: experimental parameters and theories on the size distribution. Chemistry and physics of lipids, 64 (1-3), 35–43.
- Wu, W., et al., 2020. A new molecular probe: an NRP-1 targeting probe for the grading diagnosis of glioma in nude mice. Neuroscience letters, 714, 134617.
- Xu, X., Costa, A., and Burgess, D.J., 2012a. Protein encapsulation in unilamellar liposomes: high encapsulation efficiency and a novel technique to assess lipid-protein interaction. Pharmaceutical research, 29 (7), 1919–1931.
- Xu, X., Khan, M.A., and Burgess, D.J., 2012b. Predicting hydrophilic drug encapsulation inside unilamellar liposomes. International journal of pharmaceutics, 423 (2), 410–418.
- Yang, Z.Z., et al., 2014. Tumor-targeting dual peptides-modified cationic liposomes for delivery of siRNA and docetaxel to gliomas. Biomaterials, 35 (19), 5226–5239.
- Zhang, Y., et al., 2020. Effect of cholesterol on the fluidity of supported lipid bilayers. Colloids and surfaces. B, biointerfaces, 196, 111353.
- Zhang, G., and Sun, J., 2021. Lipid in chips: a brief review of liposomes formation by microfluidics. International journal of nanomedicine, 16, 7391–7416.