16 research outputs found

    Dizajniranje i vrednovanje bioadhezijskog filma za transdermalnu isporuku propranolol hidroklorida

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    The objective of the study was to develop a suitable transdermal delivery system for propranolol hydrochloride (PPL) via employing chitosan as a film former. Drug concentration uniformity, thickness, moisture uptake capacity and skin bioadhesion of the films were characterized. The effects of chitosan and PPL concentration and different penetration enhancers on the release and permeation profiles from the films were investigated. Skin irritation of the candidate film was evaluated. Chitosan film (PPL 2 mg cm2, chitosan 2 % m/m, cineol 10 %, m/m) was found non-irritant and achieved 88.2 % release after 8 hours in phosphate buffer. Significant high (p < 0.001) permeation of PPL through rat skin was obtained using this film compared to the film without enhancer (about 8 times enhancement factor), making it a promising transdermal delivery system for PPL.Cilj rada bio je razvoj pogodnog transdermalnog sustava na bazi kitozana za isporuku propranolol hidroklorida (PPL). Svim pripravcima ispitana je jednoličnost udjela lijeka, debljina, sposobnost vlaženja i bioadhezivnost na kožu. Ispitivan je i utjecaj kitozana, koncentracije PPL-a i sredstva za povećanje permeacije na oslobađanje i permeacijski profil, te potencijalni iritacijski učinak na kožu. Iz kitozanskog filma (PPL 2 mg cm2, 2 %, m/m, kitozana i 10 %, m/m, cineola), koji nije djelovao iritabilno, postignuto je 88,2 % oslobađanja nakon 8 sati u fosfatnom puferu. S ovim pripravkom postignuta je i vrlo značajna (p < 0,001) permeacija PPL kroz kožu štakora, oko osam puta veća u usporedbi s filmom bez sredstva za povećanje permeacije. Pripravak bi se mogao upotrijebiti za transdermalnu isporuku PPL

    Enhancement strategies for transdermal drug delivery systems: current trends and applications

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    Screening of Venlafaxine Hydrochloride for Transdermal Delivery: Passive Diffusion and Iontophoresis

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    The objective of the study was to investigate in vitro transdermal delivery of venlafaxine hydrochloride across the pigskin by passive diffusion and iontophoresis. For passive diffusion, experiments were carried out in Franz diffusion cell whereas for iontophoretic permeation, the diffusion cell was modified to contain both the donor and return electrode on the same side of skin. Anodal iontophoresis was carried out using a current density of 0.5 mA/cm2. Donor concentrations used were 585.5 mg/ml (saturated solution) and 100 mg/ml. Experiments initially performed to determine the transport efficiency of venlafaxine ions showed promising results. Iontophoresis increased the permeation rate at both concentration levels over their passive counterparts (P < 0.01), but surprisingly higher steady-state flux was obtained from lower donor drug load (P < 0.01). The favorable pH of the unsaturated solutions is suggested to be the cause for this effect. Mild synergistic effect was observed when iontophoresis was carried out incorporating peppermint oil in the donor but the same was not found in passive diffusion. Highest steady-state flux obtained in the experiment was 3.279 μmol/cm2/h when peppermint oil (0.1%) was included in the donor. As the maintenance requirement of venlafaxine hydrochloride is approximately 9.956 μmol/h, the results suggested that the drug is a promising candidate for iontophoretic delivery

    Polymeric Matrix System for Prolonged Delivery of Tramadol Hydrochloride, Part I: Physicochemical Evaluation

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    Management of moderate or severe chronic pain conditions is the burden of clinicians dealing with patients trying to improve their quality of life and diminish their suffering. Although not a new opioid, tramadol has been recently rediscovered and widely used; this may be due to its favorable chronic safety and dependence profiles together with its high potency. Tramadol is a centrally acting analgesic with half-life of ~6 h; therefore, it requires frequent dosing. It is freely soluble in water; hence, judicious selection of retarding formulations is necessary. The current study is focused on the innovation of a novel, simple, monolayer, easy-to-use, cost-effective, and aesthetically acceptable bioadhesive transdermal delivery system overcoming the defects of the conventional “patch” as carrier system for tramadol, ensuring its adequate delivery, along with the physicochemical evaluation of the designed formulations. Monolithic tramadol matrix films of chitosan, different types of Eudragit®, and binary mixtures of both were prepared. As a single-polymer film, chitosan film showed best properties except for somewhat high moisture uptake capacity, insufficient strength and rapid release, and permeation. Polymer blends were monitored in order to optimize both properties and performance. Promising results were obtained, with chitosan–Eudragit® NE30D (1:1) film showing the most desirable combined, sufficiently rapid as well as prolonged release and permeation profiles along with satisfactory organoleptic and physicochemical properties
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