Abstract:
Transdermal Drug Delivery Systems (TDDS) exists for a long time such as creams,
and ointments for topical ailments. Incorporating drugs in transdermal patch is more
recent application. Liquid reservoir system, solid reservoir/peripheral adhesive system
or matrix (drug in adhesive) system may be used to deliver the drug through skin. In
present work thirty six matrix type transdermal patch formulations of diclofenac
sodium, diclofenac potassium, diclofenac diethylamine and flurbiprofen (nine each)
were developed by using hydroxypropylmethylcellulose (HPMC 4000 cps,),
polyvinylpyrolidine (PVP K-30,) and ammonio methacrylate copolymer type A
(Eudragit RL-100). Different skin permeation enhancers like isopropyl myristate,
isopropyl palmitate and tween 80 were incorporated in the formulations. The
influence of various formulation variables, such as initial drug load and certain skin
permeation enhancers on permeation characteristics of selected analgesics from the
prepared formulations was studies through hairless abdominal rabbit skin by using the
modified Franz diffusion cell. The permeation parameters were estimated by Chow
method following the Fick’s law of diffusion. The penetration profiles of all
formulations were influenced significantly (p <0.05) by the addition of enhancers in
comparison to formulation controls (without enhancers) and commercially available
product (market control). Among the enhancers studied, isopropyl myristate and
isopropyl palmitate produced better results with high relative permeation ratio (14.61,
27.40) and enhancing factor (32, 7.83). All the formulations showed good stability
and reproducibility. The prepared patch formulations resulted better permeability as
compared to the controls with high apparent permeation rates (121.18 ± 34.37 µg.h-1
cm-2) and diffusion coefficients (8.68 ± 0.43 cm2/s × 10-4) with shorter lag times (1.0 ±
0.15 h). The diffusion coefficients were found independent of initial drug load for all
formulations. Release profiles were evaluated by model-dependent approaches. The
drug release from almost all formulations was best explained by zero order equation,
as the plots showed highest linearity (r2 > 0.952), followed by Higuchi equation. The
mechanism of drug release for most of formulations was super case II transport and in
few, non-Fickian diffusion. The pharmacokinetic parameters of optimized
formulations for each drug were determined from blood levels which revealed a
profile typical of sustained release formulation having low elimination rate constants
and high Mean Residence Time with the ability to maintain adequate plasma levels for
24 h i.e. up to the next application.
The higher steady-state flux, diffusion coefficient and permeability coefficient, as
well as the decreased lag time of permeation of diclofenac sodium 5% with IPP, 5%
diclofenac potassium with IPM, 5% diclofenac diethylamine with IPP and
flurbiprofen 10% with IPM as compared to formulation control (without enhancer)
and commercially available gel (market control) was obtained. The faster permeation
of the drug as compared to the controls could be attributed to the incorporation of skin
penetration enhancer. The pharmacokinetic analysis confirmed that the optimized
formulations exhibit typical sustained release phenomenon having low elimination
rate constants and high MRT with the ability to maintain adequate plasma levels for
24 h i.e. up to the next application. Therefore it is concluded that the incorporation of
skin penetration enhancers like IPM and IPP are promising in developing matrix type
patch formulation.