SOLUBILITY AND THERMODYNAMIC MODELING OF QUETIAPINE FUMARATE IN SELF NANOEMULSIFYING DRUG DELIVERY SYSTEM (SNEDDS)
DOI:
https://doi.org/10.22159/ijap.2018v10i4.25862Keywords:
Quetiapine Fumarate, SNEDDS, Thermodynamic Modeling, Solubility StudiesAbstract
Objective: The present study gives emphasis on the development of self-nanoemulsifying drug delivery system (SNEDDS) of poorly water-soluble drug using Apelblat model.
Methods: For the development of self-nanoemulsifying drug delivery system (SNEDDS) solubility in surfactant, co-surfactant and in oil phase are considered as an important key to avoid phase separation and precipitation after dilution. The solubility of quetiapine fumarate was determined by the isothermal mechanical shaking method for its individual components in the temperature range from 305.15 to 330.15K was measured. The experimental mole fraction solubility of quetiapine was good correlated with calculated data by using modified Apelblat model. Prepared SNEDDS were evaluated in centrifugation, freeze-thaw cycle study, self-nanoemulsification efficiency test. Physicochemical properties of prepared SNEDDS including particle size, zeta potential, viscosity and refractive index were carried out.
Results: The equilibrium saturated and mole fraction solubility of Quetiapine fumarate was found to be high in tween80 than SNEDDS, Labrafac lipophile WL 1349 and capryol 90. Quetiapine fumarate equilibrium saturated solubility, as well as mole fraction solubility, was found to be increased with increase in temperature in SNEDDS as well as in its individual components Prepared SNEDDS was found to be highly stable at centrifugation, heating and cooling cycles and freeze-thaw cycles and shows no sign of precipitation after dilution in water. All physicochemical parameters were observed within specification including droplet size observed as 26.37 nm, polydispersity index 0.0970, zeta potential-14.69 and the refractive index was observed as 1.458 which was nearer to the refractive index of water indicating the isotropic behavior of prepared SNEDDS.
Conclusion: The solubility study could be an effective approach for the development of thermodynamically stable SNEDDS formulation of poorly soluble drugs using Apelblat model.
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References
Brayfield A, Sweetman SC. Martindale, the complete drug reference. Pharmaceutical Press: London; 2007.
Andrew JC, Jeffrey MG, John AT. Dosing and switching strategies for quetiapine fumarate. Clin Ther 2002;24:209-22.
Talele S, Gudsoorkar VR. Novel approaches for solidification of SMEDDS. Int J Pharm Biosci 2016;15:90-101.
Ihor WR, Lisa AA. Overview of the efficacy of seroquel (quetiapine). Schi Res 1997;24:199.
King DJ, Link C. Seroquel (ICI 204636) an atypical antipsychotic result from phase III. E Neurol 1996;6:202.
SG Talele, DV Derle. Response surface methodology as a tool for optimization of self-nanoemulsified drug delivery system of quetiapine fumarate. Asian J Pharm 2018;11:319-30.
Bouillot B, Teychene S, Biscans B. An evaluation of thermodynamic models for the prediction of drug and drug-like molecule solubility in organic solvents. Fluid Phase Equilib 2011;309:36–52.
Jouyban A, Soltanpour S, Soltani S. Solubility prediction of drugs in water-cosolvent mixtures using Abraham solvation parameters. J Pharm Pharm Sci 2007;10:263–77.
Baka E, Comer JEA, Takac Novak K. Study of equilibrium solubility measurement by saturation shake-flask method using hydrochlorothiazide as a model compound. J Pharm Biomed Anal 2008;46:335–41.
Jimenez JA, Martinez F. Thermodynamic study of the solubility of acetaminophen in propylene glycolþwater cosolvent mixtures. J Braz Chem Soc 2006;17:125–34.
Yang GD, Huang YR, Nan GJ. Solubility of daidzein in the binary system of ethanol and water. J Mol Liq 2013;180:160–3.
Wang Q, Chen Y, Deng L. Determination of the solubility parameter of ionic liquid 1-alkyl-3-methylimidazolium chloride by inverse gas chromatography. J Mol Liq 2013;180:135–8.
Soltanpour S, Jouyban A. Solubility of lamotrigine in binary and ternary mixtures of N-methyl pyrrolidone and water with polyethylene glycols 200, 400, and 600 at 298.2 K. J Mol Liq 2013;180:1–6.
Yang W, Chen Z, Jiang X. Solubility of succinic anhydride in different pure solvents and binary solvent mixtures with the temperature range from 278.15 to 333.15 K. J Mol Liq 2013;180:7–11.
Domanska U, Pobudkowska A, Pelczarska A, Gierycz P pKa and solubility of drugs in water, ethanol, and 1-octanol. J Phys Chem B 2009;113:8941–7.
Sunsandee N, Hronec M, Stolcova M. Thermodynamics of the solubility of 4-acetyl benzoic acid in different solvents from 303.15 to 373.15 K. J Mol Liq 2013;180:252–9.
Wang L, Lv TT. Determination and modeling of the solubility and prediction of the dissolution properties of 2,4-dichlorophenoxyacetic acid in toluene, tetrachloromethane and the binary solvent mixtures of (cyclohexaneþethyl acetate). J Mol Liq 2013;181:29–33.
Zhang CL, Zhao F, Wang Y. Thermodynamics of the solubility of ciprofloxacin in methanol, ethanol, 1-propanol, acetone, and chloroform from 293.15 to 333.15 K. J Mol Liq 2010;156:191–3.
Zhang CL, Zhao F, Wang Y. Thermodynamics of the solubility of sulfamethazine in methanol, ethanol, 1-propanol, acetone, and chloroform from 293.15 to 333.15 K. J Mol Liq 2011;159:170–2.
Zhang CL, Li BY, Wang Y. Solubilities of norfloxacin in methanol, ethanol, 1-propanol, acetone, and chloroform from 294.15 to 318.15 K. Canadian J Chem Eng 2010;88:63–6.
Dharmang Pandya, Bhavin Rana, Nilay Solanki. Oral bioavailability enhancement of bromocryptine mesylate by the self-microemulsifyingdrug delivery system. Int J Pharm Pharm Sci 2016;8:76-81.
Shweta Khade, Yogesh Pare. Formulation and evaluation of neusilin US2 adsorbed amorphous solid self-micro-emulsifyingdelivery system of atorvastatin calcium. Asian J Pharm Clin Res 2016;9:93-10.