Skin permeation mechanism and bioavailability enhancement of celecoxib from transdermally applied nanoemulsion

<p>Abstract</p> <p>Background</p> <p>Celecoxib, a selective cyclo-oxygenase-2 inhibitor has been recommended orally for the treatment of arthritis and osteoarthritis. Long term oral administration of celecoxib produces serious gastrointestinal side effects. It is a highly lipophilic, poorly soluble drug with oral bioavailability of around 40% (Capsule). Therefore the aim of the present investigation was to assess the skin permeation mechanism and bioavailability of celecoxib by transdermally applied nanoemulsion formulation. Optimized oil-in-water nanoemulsion of celecoxib was prepared by the aqueous phase titration method. Skin permeation mechanism of celecoxib from nanoemulsion was evaluated by FTIR spectral analysis, DSC thermogram, activation energy measurement and histopathological examination. The optimized nanoemulsion was subjected to pharmacokinetic (bioavailability) studies on Wistar male rats.</p> <p>Results</p> <p>FTIR spectra and DSC thermogram of skin treated with nanoemulsion indicated that permeation occurred due to the disruption of lipid bilayers by nanoemulsion. The significant decrease in activation energy (2.373 kcal/mol) for celecoxib permeation across rat skin indicated that the stratum corneum lipid bilayers were significantly disrupted (p < 0.05). Photomicrograph of skin sample showed the disruption of lipid bilayers as distinct voids and empty spaces were visible in the epidermal region. The absorption of celecoxib through transdermally applied nanoemulsion and nanoemulsion gel resulted in 3.30 and 2.97 fold increase in bioavailability as compared to oral capsule formulation.</p> <p>Conclusion</p> <p>Results of skin permeation mechanism and pharmacokinetic studies indicated that the nanoemulsions can be successfully used as potential vehicles for enhancement of skin permeation and bioavailability of poorly soluble drugs.</p

Mechanistic approach for the development of ultrafine oil-water emulsions using monoglyceride and blends of medium and long chain triglycerides: enhancement of the solubility and bioavailability of Perphenazine

A kinetically stable ultra-fine oil-water (o/w) emulsion containing Perphenazine and blends of long and medium chain triglycerides was prepared. The purpose of the ultra-fine emulsion was to increase the oral bioavailability of Perphenazine. The formulations were prepared using a low energy emulsification phase titration method. The optimized formulations consisted of blends of linseed oil and Sefsol 218 (1:1) (oil phase), polysorbate 40 (surfactant), polyethylene glycol 400 (cosurfactant) and distilled water (dispersion medium). Characterization of viscosity, refractive index, particle size distribution, spectral transmittance and surface morphology of the formulations was performed. The release rate of Perphenazine from the formulations was quantified using the everted gut sac of rat intestinal mucosa. The ex vivo release data demonstrated that the formulated nanoemulsions increased significantly the permeation rate of Perphenazine when compared with a suspension. Following oral administration of selected nanoemulsions in Wistar rats, the AUC and Cmax of Perphenazine increased by 2.9 and 2.54-fold respectively compared with the Perphenazine suspension. The observed increase in bioavailability may be due to the increase in the dissolution rate from the molecularly dissolved drug in the oil phase and an increased rate of dispersion of the drug in the gastrointestinal (GI) tract which leads to greater absorption into the blood

Dvopulsni sustav za isporuku amoksicilina: Pokušaj sprečavanja bakterijske rezistencije na antibiotike

Bearing in mind the present scenario of the increasing biological tolerance of bacteria against antibiotics, a time controlled two pulse dosage form of amoxicillin was developed. The compression coating inlay tablet approach was used to deliver the drug in two pulses to different parts of the GIT after a well defined lag time between the two releases. This was made possible by formulating a core containing one of the two drug fractions (intended to be delivered as the second pulse), which was spray coated with a suspension of ethyl cellulose and a hydrophilic but water insoluble agent as a pore former (microcrystalline cellulose). Coating of 1 up to 5 % (m/m) was applied over the core tablet, giving a corresponding lag of 3, 5, 7 and 12 h. Increasing the level of coating led to retardation of the water uptake capacity of the core, leading to prolongation of the lag time. Microcrystalline cellulose was used as a hydrophilic but water insoluble porosity modifier in the barrier layer, varying the concentration of which had a significant effect on shortening or prolongation of the lag time. This coated system was further partially compression coated with the remaining drug fraction (to be released as the first immediate release pulse) with a disintegrant, giving a final tablet. The core tablet and the final two pulse inlay tablet were further investigated for the in vitro performance.Zbog sve učestalije pojave rezistencije bakterija na antibiotike, razvijen je dvopulsni sustav s vremenskom kontrolom za isporuku amoksicilina. Sustav čine slojevite tablete s obloženim slojem dobivenim metodom kompresije, koji omogućavaju isporuku lijeka u dva pulsa u različite dijelove gastrointestinalnog trakta, s utvrđenom odgodom između dva oslobađanja. Ovakav način oslobađanja postignut je s pripravkom koji u jezgri tablete sadrži jednu frakciju lijeka (koja se oslobađa kao drugi puls), a u oblozi drugu. Obloženi dio dobiven je sprejanjem sa suspenzijom etilceluloze i hidrofilnog, ali vodonetopljivog sredstva koji tvori pore (mikrokristalinična celuloza). Oblaganje sa slojem koji čini 1 do 5 % (m/m) mase jezgre postignut je vremenski odmak drugog pulsa od 3, 5, 7 i 12 h. Povećanjem mase obložnog sloja smanjuje se kapacitet prodiranja vode u jezgru tablete, što produljuje vrijeme drugog pulsa. Mikrokristalinična celuloza uporijebljena je kao hidrofilno, vodonetopljivo sredstvo za kotrolu poroznosti u barijernom sloju. Promjena koncentracije celuloze značajno je utjecala na skraćenje ili produljenje vremenskog odmaka. Obloženi sustav je potom djelomično obložen s preostalom frakcijom lijeka (koja se oslobađa odmah u prvom pulsu) pomiješanom s dezintegratorom. Tableta s jezgrom i dvopulsna slojevita tableta ispitivane su in vitro

Dizajn, razvoj i vrednovanje novih nanoemulzija za transdermalnu primjenu celekoksiba

The aim of the present study was to investigate the potential of nanoemulsion formulations for transdermal delivery of celecoxib (CXB). The in vitro skin permeation profile of optimized formulations was compared with CXB gel and nanoemulsion gel. Significant increase in the steady state flux (Jss), permeability coefficient (Kp) and enhancement ratio (Er) was observed in nanoemulsion formulations T1 and T2 (p < 0.05). The highest value of these permeability parameters was obtained in formulation T2, which consisted of 2% m/m of CXB, 10% m/m of oil phase (Sefsol 218 and Triacetin), 50% m/m of surfactant mixture (Tween-80 and Transcutol-P) and 40% m/m of water. The anti-inflammatory effects of formulation T2 showed a significant increase (p < 0.05) in inhibition after 24 h compared to CXB gel and nanoemulsion gel on carrageenean-induced paw edema in rats. These results suggested that nanoemulsions are potential vehicles for improved transdermal delivery of CXB.U radu su opisana ispitivanja nanoemulzija za transdermalnu primjenu celekoksiba (CXB). Profil permeacije kroz kožu ispitivan je in vitro i uspoređivan sa CXB gelom i nanoemulzijskim gelom. U formulacijama T1 i T2 postignuto je značajno povećanje ustaljenog fluksa (Jss), koeficijenta permeabilnosti (Kp) i povećanje omjera (Er) (p < 0.05). Najveće vrijednosti parametara permeabilnosti dobivene su u formulaciji T2 koja je sadržala 2% m/m CXB, 10% m/m uljne faze (Sefsol 218 i Triacetin), 50% m/m površinski-aktivnih tvari (Tween-80 i Transcutol-P) i 40% m/m vode. Protuupalno djelovanje formulacije T2 na edem šape štakora uzrokovan karageninom značajno je povećano (p < 0.05) poslije 24 h u usporedbi sa CXB gelom i nanoemulzijskim gelom. Rezultati ukazuju na poboljšanu isporuku celekoksiba putem nanoemulzija

Silymarin: A review of pharmacological aspects and bioavailability enhancement approaches

Silymarin, a flavonolignan from the seeds of ′milk thistle′ (Silybum marianum   ), has been widely used from ancient times because of its excellent hepatoprotective action. It is a mixture of mainly three flavonolignans, viz, silybin, silidianin, and silychristine, with silybin being the most active. Silymarin has been used medicinally to treat liver disorders, including acute and chronic viral hepatitis, toxin/drug-induced hepatitis, and cirrhosis and alcoholic liver diseases. It has also been reported to be effective in certain cancers. Its mechanism of action includes inhibition of hepatotoxin binding to receptor sites on the hepatocyte membrane; reduction of glutathione oxidation to enhance its level in the liver and intestine; antioxidant activity; and stimulation of ribosomal RNA polymerase and subsequent protein synthesis, leading to enhanced hepatocyte regeneration. It is orally absorbed but has very poor bioavailability due to its poor water solubility. This review focuses on the various pharmacological activities of silymarin including the clinical trials. For the first time, the review also looks at the formulation work that has been done to enhance its solubility, so as to increase its bioavailability and thus, its hepatoprotective action

Development and Evaluation of Chronotherapeutic Drug Delivery System for the Management of Nocturnal Asthma

Purpose: To develop an oral capsule-based chronomodulated drug delivery system of salbutamol sulphate for the treatment of nocturnal asthma. Methods: The basic design of the proposed dosage form entails an insoluble cross-linked capsule body filled with drug-loaded pellets sealed with hydrocolloid plug and a soluble capsule cap. Various hydrocolloid polymers, namely, hydroxypropyl methylcellulose, (HPMC), hydroxypropyl cellulose (HPC), sodium alginate, polyethylene oxide (PEO) and guar gum. were used to optimize the plug material in the delivery in order to modulate lag period To avoid gastric transit time variability, the entire system was coated with Eudragit S100/Eudragit L100 dispersion (4:1), an enteric polymer system that dissolves at pH 6.8. Results: Time-specific pulsatile release with 4 h lag period was achieved with crosslinked insoluble gelatin capsule shells containing pellets prepared from Avicel PH 101/lactose (80: 10) and 3 % Acidisol as disintegrant. In vitro data indicate that the developed pulsatile system released almost 98 % of the drug shoertly after the predetermined lag time of 4 h. Conclusion: The developed system is capable of releasing the drug after a 4-h lag period. However, in vivo studies need to be carried out to ascertain the effectiveness of the formulation

Chronomodulated Drug Delivery System of Salbutamol Sulphate for the Treatment of Nocturnal Asthma

A time dependent pulsed release system consisting of an effervescent core surrounded by consecutive layers of swelling and rupturable polymers was prepared and evaluated. The cores containing salbutamol sulphate as bioactive agent were prepared by direct compression method using different ratios of microcrystalline cellulose and effervescent agent and then coated sequentially with an inner swelling layer containing a hydrocolloid, hydroxypropylmethylcellulose E5 and an outer rupturable layer having Eudragit RL/RS (1:1). The effects of various processing and formulative parameters on the performance of system were studied. The rupture and dissolution tests were studied using the USP paddle method at 50 rpm in 0.1 N HCl and phosphate buffer pH 6.8. The lag time of the drug release decreased by increasing the inner swelling layer and increased by increasing the rupturing layer level. All the results obtained in the present study suggest that osmotic pumping effect was involved which eventually lead to the drug release