Effects of Formulation Variables on the Particle Size and Drug Encapsulation of Imatinib-Loaded Solid Lipid Nanoparticles

Gupta, Biki; Poudel, Bijay Kumar; Pathak, Shiva; Tak, Jin Wook; Lee, Hee Hyun; Jeong, Jee–Heon; Choi, Han‐Gon; Yong, Chul Soon; Kim, Jong Oh

doi:10.1208/s12249-015-0384-z

Cited by 57 publications

(38 citation statements)

References 32 publications

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“…This might be attributed to the ability of surfactant to reduce the interfacial tension and hence the interfacial free energy, so that higher amount of surfactant results to an emulsion with high interfacial area, that means smaller particle size with good stability (Sinko, 2017). The results were in agreement with those reported by Rehfeld in case of benzene-in-water emulsions (Rehfeld, 1967); and also with those reported by Gupta et al(2015) in case of solid lipid nanoparticles (Gupta et al, 2015). The particle size was found to be influenced by the type of polymer as bigger size particles were observed with PLGA RG503H followed by PLA R203H and smaller size particles were observed with PLGA RG502H.…”

Section: Particle Sizesupporting

confidence: 92%

Study on influence of polymer and surfactant on in vitro performance of biodegradable aqueous-core nanocapsules of tenofovirdisoproxil fumarate by response surface methodology

Srikar

Rani

2019

Braz. J. Pharm. Sci.

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The major objective of this study was to investigate the effect of biodegradable polymer type and surfactant concentration on various characteristics viz. particle size, entrapment efficiency and drug release rate constant of aqueous core nanocapsules (ACNs) containing tenofovirdisoproxil fumarate. In this study, the nanocapsules were prepared by modified multiple emulsion technique with biodegradable polymers viz. poly(lactide-co-glycolide) of two different grades (PLGA RG502H and PLGA RG503H) and poly lactic acid (PLA R203H); and the surfactant employed was span 80. The experiments were designed under response surface methodology by employing the Design Expert software. Entrapment efficiency, particle size and drug release rate constant were taken as response variables. The prepared nanocapsules were subjected to characterization studies and the obtained results were statistically analyzed by Analysis of Variance (ANOVA) for response surface 2-Factorial Interaction model. ANOVA studies showed that the influence of both factors on all the response variables were significant at p<0.05. The optimized formulation was found to have the entrapment efficiency of 71.58%, particle size of 252.41 nm and the drug release rate constant of 0.045 h-1 ; thus, indicating that the ACNs were obtained with finest characteristics. SEM studies showed that the particles were spherical.

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Section: Particle Sizesupporting

confidence: 92%

Study on influence of polymer and surfactant on in vitro performance of biodegradable aqueous-core nanocapsules of tenofovirdisoproxil fumarate by response surface methodology

Srikar

Rani

2019

Braz. J. Pharm. Sci.

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“…Therefore, higher amount of surfactant results an emulsion with smaller particle size and good stability. These results related to those reported by Rehfeld [29] for benzene-in-water emulsions; and also with those reported by Gupta et al [30] for solid lipid nanoparticles. The particle size of ACNs prepared with PLGA RG503H was found to be high, and it was decreased in the order of PLA R203H and PLGA RG502H.…”

Section: Particle Sizesupporting

confidence: 92%

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Srikar¹

2019

AJP

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Aim: The prior objective of the current work was to optimize the surfactant concentration and type of polymer to achieve high entrapment efficiency, less particle size, and less drug release rate constant of aqueous core nanocapsules (ACNs) containing lamivudine. Materials and Methods: Modified multiple emulsion technique was used to prepare the nanocapsules with biodegradable polymers, namely, poly (lactide-co-glycolide) and polylactic acid; and the surfactant employed was Span 80. The experiments were designed by one factorial design that was repeated for every categoric factor under response surface methodology of design of experiments using Stat-Ease Design-Expert software. Results: The obtained results of response variable, namely, entrapment efficiency, particle size, and drug release rate constant were statistically treated by ANOVA for response surface quadratic model and found that influence of both factors on all the response variables was significant at P < 0.05. The optimized formulation was found to have the entrapment efficiency of 77.12%, particle size of 250.3 nm, and the drug release rate constant of 0.106 h −1. Conclusion: The results indicated that the objective of this was achieved and ACNs technique was efficient to develop nanoparticles for water-soluble drugs with improved efficiency.

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“…Similar results were obtained while formulating different multiparticulate systems (Patel et al, 2006;Piyakulawat et al,. 2007;Mobarak et al, 2014;Gupta et al, 2016). In this study, VP and the polymers were completely soluble in methylene chloride and fast solidification of the beads occurred due to the high volatility of the solvent.…”

Section: Effect Of Drug Loadmentioning

confidence: 80%

Ultrahigh verapamil-loaded controlled release polymeric beads using superamphiphobic substrate: D-optimal statistical design, in vitro and in vivo performance

et al. 2018

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Controlled-release multiparticulate systems of hydrophilic drugs usually suffer from poor encapsulation and rapid-release rate. In the present study, ultra-high loaded controlled release polymeric beads containing verapamil hydrochloride (VP) as hydrophilic model drug were efficiently prepared using superamphiphobic substrates aiming to improve patient compliance by reducing dosing frequency. Superamphiphobic substrates were fabricated using clean aluminum sheets etched with ammonia solution and were treated with 1.5% (w/v) perfluorodecyltriethoxysilane (PFDTS) alcoholic solution. The effect of the main polymer type (lactide/glycolide (PLGA) 5004A, PLGA 5010, and polycaprolactone (PCL)), copolymer (Eudragit RS100) content together with the effect of drug load on encapsulation efficiency (EE%) and in vitro drug release was statistically studied and optimized via D-optimal statistical design. In vivo pharmacokinetic study was carried out to compare the optimized system relative to the market product (Isoptin). Results revealed that superamphiphobic substrates were successfully prepared showing a rough micro-sized hierarchical structured surface upon observing with scanning electron microscope and were confirmed by high contact angles of 151.60 ± 2.42 and 142.80°±05.23° for water and olive oil, respectively. The fabricated VP-loaded beads showed extremely high encapsulation efficiency exceeding 92.31% w/w. All the prepared systems exhibited a controlled release behavior with Q12 h ranging between 5.46 and 95.90%w/w. The optimized VP-loaded system composed of 150 mg (1.5% w/v) PCL without Eudragit RS100 together with 160 mg VP showed 2.7-folds mean residence time compared to the market product allowing once daily administration instead of three times per day.

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Effects of Formulation Variables on the Particle Size and Drug Encapsulation of Imatinib-Loaded Solid Lipid Nanoparticles

Cited by 57 publications

References 32 publications

Study on influence of polymer and surfactant on in vitro performance of biodegradable aqueous-core nanocapsules of tenofovirdisoproxil fumarate by response surface methodology

Study on influence of polymer and surfactant on in vitro performance of biodegradable aqueous-core nanocapsules of tenofovirdisoproxil fumarate by response surface methodology

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Ultrahigh verapamil-loaded controlled release polymeric beads using superamphiphobic substrate: D-optimal statistical design, in vitro and in vivo performance

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