Optimization of nanoemulsion formulation containing phenytoin
Epilepsy is a Central Nervous System (CNS) disease caused by abnormal neuron signalling causing repeated seizures. CNS is protected by a barrier known as blood-brain barrier (BBB). The selective membrane on the BBB which only allow small lipophilic particle to pass through complicates the penetr...
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| Format: | Thesis |
| Language: | English |
| Published: |
2017
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| Subjects: | |
| Online Access: | http://psasir.upm.edu.my/id/eprint/98056/1/FS%202019%2089%20UPMIR.pdf http://psasir.upm.edu.my/id/eprint/98056/ |
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| Summary: | Epilepsy is a Central Nervous System (CNS) disease caused by abnormal
neuron signalling causing repeated seizures. CNS is protected by a barrier
known as blood-brain barrier (BBB). The selective membrane on the BBB
which only allow small lipophilic particle to pass through complicates the
penetration of antiepileptic drugs. Phenytoin is a classic antiepileptic drug
(AED) listed on the World Health Organization’s List of Essential Medicines,
which exhibits potent therapeutic efficacy in controlling seizure attacks thus
signifying its importance in a basic healthcare system. However, due to poor
solubility and bioavailability of phenytoin, large dosage had to be given in its
salt form (phenytoin sodium) to reach therapeutic concentration with
numerous side effects. Hence, incorporating phenytoin in a nanocarrier
would increase its bioavailability while minimizing the dosage required with
reduced side effects.
From the formulation study, it was discovered that phenytoin could only be
retained in alkali solution. Therefore to address the solubility issue of
phenytoin, a two-step method based on the pH solubility profile of phenytoin
was used to formulate phenytoin into the nanoemulsion. First step involves
the formulation of blank nanoemulsion (without phenytoin) through magnetic
stirring followed by high shear homogenization. Second step involves the
incorporation of phenytoin onto the nanocarrier by adjusting pH of blank
nanoemulsion to alkali condition. Incorporation of phenytoin was confirmed
through Transmission Electron Microscopy (TEM) which showed the
position of phenytoin on the surface of oil droplets. Mixture Experimental Design (MED) and Artificial Neural Network (ANN)
were employed to optimize the composition of phenytoin-loaded
nanoemulsion. Effects of isopropyl myristate (3.00-6.00%, wt%), Tween
80:85 (1.50-3.00% wt%), glycerol (4.00-7.00%, wt%), and water (84.00-
91.50%, wt%) on the droplet size of nanoemulsion were investigated. The
optimum formulation obtained from the mathematical model with desirable
criteria were 3.00% isopropyl myristate, 2.04% Tween 80:85, 7.00% glycerol
and 87.96% water. Based on the optimum formulation from MED, the
predicted response value for droplet size was 99.58 nm, while the predicted
value from ANN was 98.27 nm, which showed in excellent agreement with
the actual value obtained from the experiment which was 98.69 nm.
Toxicity comparison between Dilantin (parenteral phenytoin sodium) and
phenytoin-loaded nanoemulsion showed that the nanoemulsion to be four
times less toxic compared to Dilantin towards Vero (kidney) cells. Stability
evaluation based on the droplet size for three months showed that the
droplet size remained in nano-size with less than 5% change. Entrapment
study showed that more than 95% of phenytoin was encapsulated
throughout 3 months storage. In conclusion, the nanoemulsion formulation
is a safer and promising vehicle for the delivery of phenytoin through
intravenous route. |
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