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Author: search.filters.author.Singhvi, GautamSubject: search.filters.subject.Liquid crystals

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    Exploring temozolomide encapsulated PEGylated liposomes and lyotropic liquid crystals for effective treatment of glioblastoma: in-vitro, cell line, and pharmacokinetic studies
    (Elsevier, 2023-05) Singhvi, Gautam; Roy, Aniruddha
    Temozolomide (TMZ) is one of the best choices for treating glioblastoma. However, due to the short plasma half-life, only 20–30 % brain bioavailability can be achieved using traditional formulations. In the present study, PEGylated liposomes and lyotropic liquid crystals (LLCs) were developed and investigated to prolong the plasma circulation time of TMZ. Industrially feasible membrane extrusion and modified hot melt emulsification techniques were utilized during the formulation. Liposomes and LLCs in the particle size range of 80–120 nm were obtained with up to 50 % entrapment efficiency. The nanocarriers were found to show a prolonged release of up to 72 h. The cytotoxicity studies in glioblastoma cell lines revealed a ∼1.6-fold increased cytotoxicity compared to free TMZ. PEGylated liposomes and PEGylated LLCs were found to show a 3.47 and 3.18-fold less cell uptake in macrophage cell lines than uncoated liposomes and LLCs, respectively. A 1.25 and 2-fold increase in the plasma t1/2 was observed with PEGylated liposomes and PEGylated LLCs, respectively, compared to the TMZ when administered intravenously. Extending plasma circulation time of TMZ led to significant increase in brain bioavailability. Overall, the observed improved pharmacokinetics and biodistribution of TMZ revealed the potential of these PEGylated nanocarriers in the efficient treatment of glioblastoma.
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    Design of temozolomide-loaded proliposomes and lipid crystal nanoparticles with industrial feasible approaches: comparative assessment of drug loading, entrapment efficiency, and stability at plasma pH
    (Taylor & Francis, 2021-06) Singhvi, Gautam
    Temozolomide is a drug approved for treating glioblastomas, which has 100% oral bioavailability but gets degraded at physiological pH thus having very short half-life and only 20–30% brain bioavailability. Due to its amphiphilic nature, reported nanoformulations exhibits poor drug loading. The objective of this work was to formulate lipid-based drug delivery systems to enhance the brain bioavailability by prolonging the drug release and circulation time of the drug to overcome the limitations of the existing therapies and possible reduction of side effects. The size of the nanocarriers obtained was less than 300 nm and the PDI obtained was less than 0.3. The designed formulation showed higher entrapment efficiency as compared to the other reported nanocarriers of temozolomide. The designed formulations showed prolonged drug release from 12 to 20 h compared to 6 h for the pure drug. About 95% of the pure drug was degraded at plasma pH at the end of 12 h, whereas only 68% and 77% was degraded when entrapped inside the lipid crystal nanoparticles and proliposomes respectively. Further, pharmacokinetic and animal studies can confirm the potential of these for improvement of brain bioavailability.
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    Quality by design assisted optimization of temozolomide loaded PEGylated lyotropic liquid crystals: Investigating various formulation and process variables along with in-vitro characterization
    (Elsevier, 2022-04) Singhvi, Gautam; Roy, Aniruddha
    Temozolomide (TMZ) is approved for the treatment of glioblastoma. The objective of the present study was to develop and characterize TMZ loaded lyotropic liquid crystals (LLCs) for intravenous delivery. Various formulation and process variables were studied in detail, following the quality by design principles. A three-level Box Behnken design was used for optimization. The effect of lipid concentration, surfactant concentration, and co-surfactant concentration on response variables like size, size distribution, zeta potential, entrapment efficiency, and drug loading was investigated using the statistical data obtained by Design Expert® software. The results demonstrated that LLCs were obtained in the size range of 53.15–186.50 nm with PDI less than 0.25. The optimized formulation showed particle size of 97.70 ± 0.481 nm and entrapment efficiency of 36.46 ± 1.48%. TMZ loaded LLCs were found to follow Korsmeyer's Peppas model and showed sustained release up to 72 h. The LLCs were further PEGylated to prevent hemolysis and achieve long plasma circulation. PEGylated LLCs showed less than 5% hemolysis. TMZ loaded LLCs demonstrated higher cytotoxicity towards glioma cell lines as compared to native TMZ. The results revealed that the prepared LLCs could be a potential delivery system to enhance the efficacy of TMZ. Additionally, the preparation method involved a minimum number of steps ensuring reproducibility and scalability.