https://orcid.org/0000-0002-2987-2967
References
- Adin, S.N., et al., 2022a. A developed high-performance thin-layer chromatography method for the determination of baicalin in Oroxylum indicum L. and its antioxidant activity. JPC – Journal of planar chromatography – modern TLC, 35 (4), 383–393.
- Adin, S.N., et al., 2022d. Investigation on utility of some novel terpenes on transungual delivery of fluconazole for the management of onychomycosis. Journal of cosmetic dermatology, 21 (10), 5103–5110.
- Adin, S.N., et al., 2022b. Computer-aided Box-Behnken outlook towards optimization of extraction of baicalin from Oroxylum indicum L. stem barks. Pharmacognosy magazine, 18 (80), 808–814.
- Adin, S.N., et al., 2023a. Application of QbD based approach in development and validation of RP-HPLC method for simultaneous estimation of Methotrexate and Baicalin in Dual-Drug Loaded Liposomes. Biomedical chromatography, 37 (4), e5581.
- Adin, S.N., et al., 2023b. Baicalin loaded Transethosomes for Rheumatoid arthritis: Development, Characterization, Pharmacokinetic and Pharmacodynamic evaluation. Journal of drug delivery science and technology, 81, 104209.
- Adin, S.N., et al., 2022c. BBD driven optimization of extraction of therapeutically active Xanthanoid mangiferin from Mangifera indica L. leaves and its antioxidant activity. Pharmacognosy Research, 15 (1), 84–93.
- Adin, S.N., et al., 2023c. Nanotransethosomes for enhanced transdermal delivery of mangiferin against rheumatoid arthritis: formulation, characterization, invivo pharmacokinetic and pharmacodynamic evaluation. Drug delivery, 30 (1), 2173338.
- Agrawal, S.P., et al., 2016. Transferrin receptor-targeted vitamin E TPGS micelles for brain cancer therapy: preparation, characterization and brain distribution in rats. Drug delivery, 23 (5), 1788–1798.
- Ahmed, S., et al., 2019. Therapeutic potential of naringin in neurological disorders. Food and chemical toxicology, 132, 110646.
- Alharbi, W.S., et al., 2022. Spanlastics as a Potential Platform for Enhancing the Brain Delivery of Flibanserin: In Vitro Response-Surface Optimization and In Vivo Pharmacokinetics Assessment. Pharmaceutics, 14 (12), 2627.
- Badria, F., and Mazyed, E., 2020. Formulation of Nanospanlastics as a Promising Approach for Improving the Topical Delivery of a Natural Leukotriene Inhibitor (3-Acetyl-11-Keto-β-Boswellic Acid): Statistical Optimization, in vitro Characterization, and ex vivo Permeation Study. Drug design, development and therapy, 14, 3697–3721.
- Beyrami, M., Karimi, E., and Oskoueian, E., 2020. Synthesized chrysin-loaded nanoliposomes improves cadmium-induced toxicity in mice. Environmental science and pollution research international, 27 (32), 40643–40651.
- Chen, B., et al., 2017. Psychiatric and behavioral side effects of antiepileptic drugs in adults with epilepsy. Epilepsy & behavior : E&B, 76, 24–31.
- Chen, R., et al., 2016. Therapeutic potential of naringin: an overview. Pharmaceutical biology, 54 (12), 3203–3210.
- Ettinger, A.B., and Argoff, C.E., 2007. Use of antiepileptic drugs for nonepileptic conditions: psychiatric disorders and chronic pain. Neurotherapeutics: the journal of the american society for experimental neurotherapeutics, 4 (1), 75–83.
- Favela-Hernández, J.M., et al., 2016. Chemistry and pharmacology of citrus sinensis. Molecules, 21 (2), 247.
- Gupta, I., et al., 2022a. High-performance thin-layer chromatography method development and validation for quantification of naringin in different extracts of Citrus sinensis L. and its antioxidant activity. JPC – Journal of planar chromatography – Modern TLC, 35 (5), 463–471.
- Gupta, I., et al., 2022b. Computer-aided box–Behnken outlook towards optimization of extraction of piperine from piper longum l. Fruits. World journal of pharmaceutical research, 11, 1439–1455.
- Gupta, I., et al., 2022c. Quality by design-based development and validation of an HPLC method for simultaneous estimation of pregabalin and piperine in dual drug-loaded liposomes. Biomedical chromatography, 37 (1), e5510.
- Gupta, I., et al., 2022d. QbD-based extraction of naringin from Citrus sinensis L. peel and its antioxidant activity. Pharmacognosy research, 15 (1), 145–154.
- Gupta, I., et al., 2022e. Investigation on utility of some novel terpenes on transungual delivery of terbinafine for the management of onychomycosis. Dermatology practical & conceptual, 12 (4), e2022202.
- Gupta, I., et al., 2023a. Application of QbD based approach in development and validation of RP-HPLC method for simultaneous estimation of pregabalin and naringin in Dual-Drug Loaded Liposomes. Biomedical chromatography, 37 (6), e5623. doi:10.1002/bmc.5623.
- Gupta, I., et al., 2023b. Spanlastics as a potential approach for enhancing the nose-to-brain delivery of piperine: In vitro prospect and in vivo therapeutic efficacy for the management of epilepsy. Pharmaceutics, 15 (2), 641.
- Gupta, P.N., et al., 2005. Non-invasive vaccine delivery in transfersomes, niosomes and liposomes: a comparative study. International journal of pharmaceutics, 293 (1-2), 73–82.
- Hesdorffer, D.C., et al., 2013. Research implications of the Institute of medicine report, epilepsy across the Spectrum: Promoting health and understanding. Epilepsia, 54 (2), 207–216.
- Kazi, K.M., et al., 2010. Niosome: A future of targeted drug delivery systems. Journal of advanced pharmaceutical technology & research, 1 (4), 374–380.
- Kola, P.K., et al., 2017. Protective effect of naringin on pentylenetetrazole (PTZ)-induced kindling; possible mechanisms of antikindling, memory improvement, and neuroprotection. Epilepsy & behavior : E&B, 75, 114–126.
- Masaeli, R., et al., 2016. Preparation, characterization and evaluation of drug release properties of simvastatin-loaded PLGA microspheres. Iranian journal of pharmaceutical research : IJPR, 15 (Suppl), 205–211.
- Moeini, S., Karimi, E., and Oskoueian, E., 2022. Antiproliferation effects of nanophytosome-loaded phenolic compounds from fruit of Juniperus polycarpos against breast cancer in mice model: synthesis, characterization and therapeutic effects. Cancer nanotechnology, 13 (1), 20.
- Nday, C.M., Eleftheriadou, D., and Jackson, G., 2019. Naringin nanoparticles against neurodegenerative processes: A preliminary work. Hellenic journal of nuclear medicine, 22, 32–41.
- Opatha, S.A.T., Titapiwatanakun, V., and Chutoprapat, R., 2020. Transfersomes: a promising nanoencapsulation technique for transdermal drug delivery. Pharmaceutics, 12 (99), 855.
- Praveen, A., et al., 2019. Lamotrigine encapsulated intra-nasal nanoliposome formulation for epilepsy treatment: Formulation design, characterization and nasal toxicity study. Colloids and surfaces B: biointerfaces, 174, 553–562.
- Saleh, A., et al., 2021. Zolmitriptan Intranasal spanlastics for enhanced migraine treatment; Formulation parameters optimized via Quality by Design Approach. Scientia pharmaceutica, 89 (2), 24.
- Saleha, R., et al., 2022. Unraveling enhanced brain delivery of paliperidone-loaded lipid nanoconstructs: pharmacokinetic, behavioral, biochemical, and histological aspects. Drug delivery, 29 (1), 1409–1422.
- Scharfman, H.E., 2007. The neurobiology of epilepsy. Current neurology and neuroscience reports, 7 (4), 348–354.
- Shafaei, N., et al., 2020. Protective effects of anethum graveolens seed’s oil nanoemulsion against cadmium-induced oxidative stress in mice. Biological trace element research, 198 (2), 583–591.
- Uruaka, C.I., and Georgwill, O., 2020. Evaluation of the anticonvulsant, hypnotic and anxiolytic-like effects of methanol seed extract of Dennettia tripetala in mice. Journal of African association of physiological sciences, 8 (1), 41–49.
- Vieira, D.B., and Gamarra, L.F., 2016. Getting into the brain: liposome-based strategies for effective drug delivery across the blood-brain barrier. International journal of nanomedicine, 11, 5381–5414.
- Yassin, G.E., Amer, R.I., and Fayez, A.M., 2019. Carbamazepine Loaded Vesicular Structures for Enhanced Brain Targeting via Intranasal Route: Optimization, in Vitro Evaluation, and in Vivo Study. International journal of applied pharmaceutics, 11, 264–274.
- Yu, L., et al., 2021. Rhein attenuates PTZ‑induced epilepsy and exerts neuroprotective activity via inhibition of the TLR4-NFκB signaling pathway. Neuroscience letters, 758, 136002.
- Zhang, G., et al., 2021. Naringenin nanocrystals for improving anti-rheumatoid arthritis activity. Asian journal of pharmaceutical sciences, 16 (6), 816–825.