Formulation,characterisation and in vivo evaluation of lipid-based nanocarrier for topical delivery of diflunisal

Diflunisal (DIF) is non-steroidal anti-inflammatory drug used in the treatment of rheumatoid arthritis, osteoarthritis. The current engrossment was aimed at formulation and assessment of DIF-loaded solid lipid nanoparticles (SLNs) for topical/dermal application. SLNs formulated by hot homogenisation method based on microemulsification technique were spherical with a mean size of 124.0?±?2.07?nm; PDI 0.294?±?0.15. The cumulative amount permeated/area was 109.99?±?0.008?μg/cm², along with permeation flux (6.30?±?0.09?μg/cm²/h) and skin retention (11.74?±?0.155?μg/cm²) across mice skin. The SLNs of DIF showed significant decrease in fluid volume, granuloma tissue weight, leukocyte count/mm³ after application of SLN formulation in mice air pouch model. Similarly, in mice ear oedema and rat paw oedema model, there was 2.30 and 1.29 time increase in percentage inhibition of oedema after SLN formulation application, respectively, as compared with conventional cream. Hence, the SLNs of DIF may prove to be a potential nanocarrier to effectively treat the local inflammatory conditions associated with arthritis.     

Optimization and evaluation of pluronic lecithin organogels as a transdermal delivery vehicle for sinomenine

The purpose of the present study was to prepare and optimize sinomenine (SIN) pluronic lecithin organogels system (PLO), and to evaluate the permeability of the optimized PLO in vitro and in vivo. Box–Behnken design was used to optimize the PLO and the optimized formulation was pluronic F127 of 19.61%, lecithin of 3.60% and SIN of 1.27%. The formulation was evaluated its skin permeation and drug deposition both in vitro and in vivo compared with gel. Permeation and deposition studies of PLO were carried out with Franz diffusion cells in vitro and with microdialysis in vivo. In vitro studies, permeation rate (J_ss) of SIN from PLO was 146.55?±?2.93?μg/cm²/h, significantly higher than that of gel (120.39?μg/cm²/h) and the amount of SIN deposited in skin from the PLO was 10.08?±?0.86?μg/cm², significantly larger than that from gel (6.01?±?0.04?μg/cm²). In vivo skin microdialysis studies showed that the maximum concentration (C_max) of SIN from PLO in “permeation study” and “drug-deposition study” were 150.27?±?20.85?μg/ml and 67.95?μg/ml, respectively, both significantly higher than that of SIN from gel (29.66 and 6.73?μg/ml). The results recommend that PLO can be used as an advantageous transdermal delivery vehicle to enhance the permeation and skin deposition of SIN.     

Influence of sonophoresis and chemical penetration enhancers on percutaneous transport of penbutolol sulfate

The effect of ultrasound and chemical penetration enhancers on transcutaneous flux of penbutolol sulfate across split-thickness porcine skin was investigated. Penbutolol sulfate is a potent, noncardioselective beta-blocker, which is used for the management of hypertension. The drug is one of the most lipid soluble of the β-adrenoceptor antagonists used clinically. It has an n-octanol/pH 7.4 buffer partition coefficient of 179 compared to a value of 22 for propranolol. The amount of penbutolol sulfate transported across the skin is low. In this project, we studied the effect of sonophoresis and chemical penetration enhancers on transdermal delivery of penbutolol sulfate. Low-frequency sonophoresis at a frequency of 20?kHz increased transcutaneous flux of penbutolol sulfate by 3.5-fold (27.37?±?μg?cm^?2?h^?1) compared to passive delivery (7.82?±?1.72?μg?cm^?2?h^?1). We also investigated the effect of 50% ethanol, 1% limonene and 2% isopropyl myristate (IPM) on transcutaneous permeation of penbutolol sulfate. IPM, ethanol and limonene at the concentration of 1%, 50% and 2%, respectively, increased the steady-state flux values of penbutolol sulfate 2.2- (17.07?±?3.24?μg?cm^?2?h^?1), 2.6?- (19.40?±?6.40?μg?cm^?2?h^?1) and 3.4-times (26.38?±?5.01?μg?cm^?2?h^?1) compared to passive delivery (7.76?±?2.9?μg?cm^?2?h^?1). The results demonstrate that although there were slight increases in flux values, ultrasound, ethanol, limonene and IPM did not significantly enhance the transdermal delivery of penbutolol sulfate. Future studies will examine ways of optimizing sonophoretic and chemical enhancer parameters to achieve flux enhancement.     

Formulation and optimization of nanoemulsion using antifungal lipid and surfactant for accentuated topical delivery of Amphotericin B

The objective of the study was to develop, optimize and evaluate a nanoemulsion (NE) of Amphotericin B (AmB) using excipients with inherent antifungal activities (Candida albicans and Aspergillus niger) for topical delivery. AmB-loaded NE was prepared using Capmul PG8 (CPG8), labrasol and polyethylene glycol-400 by spontaneous titration method and evaluated for mean particle size, polydispersity index, zeta potential and zone of inhibition (ZOI). NE6 composed of CPG8 (15%w/w), S_mix (24%w/w) and water (61%w/w) was finally selected as optimized NE. AmB-NE6 was studied for improved in vitro release, ex vivo skin permeation and deposition using the Franz diffusion cell across the rat skin followed with drug penetration using confocal laser scanning microscopy (CLSM) as compared to drug solution (DS) and commercial Fungisome^®. The results of in vitro studies exhibited the maximum ZOI value of NE6 as 19.1?±?1.4 and 22.8?±?2.0?mm against A. niger and C. albicans, respectively, along with desired globular size (49.5?±?1.5?nm), zeta potential (?24.59?mV) and spherical morphology. AmB-NE6 revealed slow and sustained release of AmB as compared to DS in buffer solution (pH 7.4). Furthermore, AmB-NE6 elicited the highest flux rate (22.88?±?1.7?μg/cm²/h) as compared to DS (2.7?±?0.02?μg/cm²/h) and Fungisome^® (11.5?±?1.0?μg/cm²/h). Moreover, the enhancement ratio and drug deposition were found to be highest in AmB-NE6 than DS across the stratum corneum barrier. Finally, CLSM results corroborated enhanced penetration of the AmB-NE6 across the skin as compared to Fungisome^® and DS suggesting an efficient, stable and sustained topical delivery.     

Controlled delivery of ropinirole hydrochloride through skin using modulated iontophoresis and microneedles

Abstract

The objective of this study was to investigate the effect of modulated current application using iontophoresis- and microneedle-mediated delivery on transdermal permeation of ropinirole hydrochloride. AdminPatch® microneedles and microchannels formed by them were characterized by scanning electron microscopy, dye staining and confocal microscopy. In vitro permeation studies were carried out using Franz diffusion cells, and skin extraction was used to quantify drug in underlying skin. Effect of microneedle pore density and ions in donor formulation was studied. Active enhancement techniques, continuous iontophoresis (74.13?±?2.20?µg/cm²) and microneedles (66.97?±?10.39?µg/cm²), significantly increased the permeation of drug with respect to passive delivery (8.25?±?2.41?µg/cm²). Modulated iontophoresis could control the amount of drug delivered at a given time point with the highest flux being 5.12?±?1.70?µg/cm²/h (5–7?h) and 5.99?±?0.81?µg/cm²/h (20–22?h). Combination of modulated iontophoresis and microneedles (46.50?±?6.46?µg/cm²) showed significantly higher delivery of ropinirole hydrochloride compared to modulated iontophoresis alone (84.91?±?9.21?µg/cm²). Modulated iontophoresis can help in maintaining precise control over ropinirole hydrochloride delivery for dose titration in Parkinson’s disease therapy and deliver therapeutic amounts over a suitable patch area and time.     

Elastic Liposomal Formulation for Sustained Delivery of Colchicine: In Vitro Characterization and In Vivo Evaluation of Anti-gout Activity

Colchicine, an alkaloid found in extracts of the plants Colchicum autumnale and Gloriosa superb, is effective in the treatment of acute gout and dermatological conditions like leuko-cytoclastic vasculitis, psoriasis, and Sweet’s syndrome. Oral administration of colchicine is associated with gastrointestinal side effects and its accumulation in the body leads to bone marrow suppression. In the present study, an attempt has been made for development and in vitro and in vivo evaluation of elastic liposomal formulation for topical delivery of colchicine. The in vitro skin permeation study across rat skin found transdermal flux for different elastic liposomal formulations to range between 32.8?±?1.2 and 44.4?±?1.9 μg h^?1 cm^?2, which was approximately seven to 11 times higher than obtained using drug solution (4.3?±?0.6 μg h^?1 cm^?2). The results of skin deposition study showed that elastic liposomal formulation provide 12.5-fold higher skin deposition as compared to drug solution of colchicine. Confocal laser scanning microscopy also revealed better accumulation and deeper penetration (up to 200 μm) of elastic liposomes than drug solution (up to 12 μm). The biological evaluation of various vesicular formulations and drug solution was carried out using monosodium urate-induced air pouch model. The results of anti-gout activity in rats showed better and sustained biological effects in 24 h measured in terms of exudate volume (63.1?±?5.7% and 9.6?±?0.5% reduction with elastic liposomes and drug solution, respectively), reduction in leukocyte count (74.2?±?6.0% and 4.1?±?0.3% reduction with elastic liposomes and drug solution, respectively), decrease in inflammatory cells accumulation, and collagen deposition with elastic liposomal formulation than drug solution. Hence, the present study reveals that elastic liposomal formulation of colchicine possesses greater potential to enhance skin accumulation, prolong drug release, and improve the site-specificity of colchicine.     

Preparation and evaluation of dl-praeruptorin A microemulsion based hydrogel for dermal delivery

Abstract

The purpose of the present investigation was to develop and optimize the microemulsion (ME) as a transdermal system for Pd-Ia, a poor water soluble and low bioavailable drug. The pseudo-ternary phase diagrams were constructed for various ME formulations including oleic acid as the oil phase, Cremophor RH40 as the surfactant, ethanol as the cosurfactant, and water. The maximum cumulative amount permeated through rat abdominal skins per unit area in 32?h (Q₃₂), and the maximum flux were evaluated using the Franz diffusion cell in order to optimize the ME formulation. The results indicated that the optimized ME formulation was composed of oleic acid (5%, W/W), Cremophor RH40 (13.33%, W/W), ethanol (26.67%, W/W), and water (55%, W/W); the maximum cumulative amount of Pd-Ia was 354.330?±?12.006?μg?cm^?2, the maximum flux was 11.467?±?0.500?μg?cm^?2?h^?1. ME-gel was administered transdermally to rats. The mean plasma concentration of Pd-Ia following transdermal application of ME-gel could be maintained for 32?h at least and the half-life was evidently prolonged. It shows that the ME-gel could be a promising vehicle for dermal delivery of Pd-Ia.     

Transdermal iontophoretic delivery of selegiline hydrochloride,in vitro

Transdermal iontophoretic delivery of selegiline hydrochloride (SH) across dermatomed human skin was studied. Electrochemical stability and various factors affecting the skin permeation were investigated. SH was stable under the influence of an electrical field. The permeation of SH was very low by passive delivery (2.29?±?0.05 μg/cm²/h) as compared to iontophoresis at 0.5 mA/cm² (65.10?±?5.04 μg/cm²/h). An increase in drug concentration from 1 to 20?mg/mL increased the iontophoretic flux by 13-fold. Optimal pH and salt (NaCl) concentration for iontophoretic delivery of SH were found to be pH 5 and 100?mM, respectively. Overall, with 20?mg/mL SH and a current density of 0.4 mA/cm², a maximum flux of 305.5?μg/cm²/h was obtained. Based on reported pharmacokinetic parameters, input target delivery rate to achieve effective plasma concentration of SH (2.2?ng/mL) was calculated. With a surface area of 40?cm², iontophoretic delivery can provide six to seven times higher levels of SH than the target delivery rate, which enables lowering of the dose and/or patch surface area. Further in vivo studies will be required to prove the efficacy of ionophoresis for enhanced delivery of SH.     

Investigation of true nanoemulsions for transdermal potential of indomethacin: characterization,rheological characteristics,and ex vivo skin permeation studies

The aim of the present study was to investigate the potential of true nanoemulsions for transdermal delivery of indomethacin. Thermodynamically stable true nanoemulsions were characterized for morphology using transmission electron microscopy (TEM), droplet size, rheological characteristics, and refractive index. The rheological behavior for all true nanoemulsions was found to be Newtonian as viscosity was unchanged by increasing the rate of shear. The ex vivo skin permeation studies were performed using Franz diffusion cell with rat skin as permeation membrane. The ex vivo skin permeation profile of optimized formulation was compared with marketed Indobene gel and nanoemulsion gel. Significant increase in permeability parameters was observed in nanoemulsion formulations (P?<?0.05). The steady-state flux (J_ss) and permeability coefficient (K_p) for optimized nanoemulsion formulation were found to be 73.96?±?2.89?μg/cm²/h and 1.479?×?10^?2?±?0.289?×?10^??2?cm/h, respectively, which were significant compared with Indobene gel and nanoemulsion gel (P?<?0.05). Enhancement ratio (E_r) was found to be 7.88 in optimized formulation F6 compared with other formulations. These results suggested that nanoemulsions can be used as potential vehicles for improved transdermal delivery of indomethacin.     

Effect of pH and penetration enhancers on electroosmotic flow and flux through skin

We have investigated the effect of pH and four penetration enhancers on the electroosmotic volume flow (EVF) and flux through skin to get more detailed understanding of this phenomenon and its effect on flux. The results were evaluated in relation EVF and the permeability change by current induced skin damage. At pH 7.4, we have confirmed that the direction of convective solvent flow is from anode to cathode. At pH 4.0, no permselectivity was observed and it seems that this pH is close to the isoelectric point of skin. At pH 3.0, the permselectivity of skin is reversed. From the difference in flux between just before (47 μg/cm² h) and after (32 μg/cm² h) cathodal current-off, the magnitude of EVF is estimated to be smaller than 1.5 μl/cm² h, if we consider the recovery of skin to a lower permeability after current-off. At pH 7.4, Oleic acid (OA) and propylene glycol monolaurate (PGML) increased the passive flux markedly. Synergistic effect in flux between OA and current was observed for both anodal and cathodal current. The use of isopropyl myristate (IPM) in combination with anodal current resulted in reduced flux when compared to the flux of anodal current alone. Cathodal flux of OA or PGML treated skin increased continuously until the current was off. However, to the contrary of our expectation, flux decreased after current-off. We think this is mainly due to the recovery of damaged skin (flux decreasing effect), though the disappearance of EVF may slightly increase the flux. For IPM and propylene glycol, the combination of enhancer with cathodal current inhibited the flux, similar to that observed for anodal delivery. Overall, these results provide further information on the role of electroosmosis and the effect of penetration enhancers in combination with current on flux through skin.     

Evaluation of progesterone permeability from supercritical fluid processed dispersion systems

Abstract

The aim of this study was to investigate the permeability of unique dispersion systems prepared by supercritical fluid (SCF) processing, to deliver bioidentical progesterone (PGN) across mouse skin. Semisolid dispersions of PGN were made up of either polyethylene glycol (PEG) 400/4000, Gelucire 44/14, d-α-tocopheryl PEG 1000 succinate (TPGS), tanscutol P or myritol 318. SCF dispersion systems were compared with various control formulations; a market cream, aqueous suspension, and three conventionally prepared dispersions comelted, cosolvent and physically mixed systems. The permeability coefficient in the absence or presence of a permeation enhancer was evaluated using ex vivo mouse skin. The permeation study results for the TPGS/myritol/transcutol P dispersion system prepared using supercritical carbon dioxide (SC-CO₂) had a two-fold improvement in transdermal permeation over 24?h compared to the control formulation, 245.7 and 126?µg?cm^?2, respectively (p value?<?0.05). In this study, the skin integrity and morphology was also investigated for changes due to the formulation constituents using histological examination and Fourier transform infrared spectroscopy. The particles from the gas-saturated suspension method and SC-CO₂ together with TPGS/myritol/transcutol P may offer potential advantages over the available cream on the market based on the vastly improved lag time and flux of PGN across the skin.     

Ethosomes-based topical delivery system of antihistaminic drug for treatment of skin allergies

Abstract

Cetirizine is indicated for the treatment of allergic conditions such as insect bites and stings, atopic and contact dermatitis, eczema, urticaria. This investigation deals with development of a novel ethosome-based topical formulation of cetirizine dihydrochloride for effective delivery. The optimised formulation consisting of drug, phospholipon 90 G? and ethanol was characterised for drug content, entrapment efficiency, pH, vesicular size, spreadability and rheological behaviour. The ex vivo permeation studies through mice skin showed highest permeation flux (16.300?±?0.300?µg/h/cm²) and skin retention (20.686?±?0.517?µg/cm²) for cetirizine-loaded ethosomal vesicles as compared to conventional formulations. The in vivo pharmacodynamic evaluation of optimised formulation was assessed against oxazolone-induced atopic dermatitis (AD) in mice. The parameters evaluated were reduction in scratching score, erythema score, skin hyperplasia and dermal eosinophil count. Our results suggest that ethosomes are effective carriers for dermal delivery of antihistaminic drug, cetirizine, for the treatment of AD.     

Solid lipid micro-dispersions (SLMs) based on PEGylated solidified reverse micellar solutions (SRMS): a novel carrier system for gentamicin

Abstract

The purpose of this study was to formulate and evaluate novel PEGylated solidified reverse micellar solutions (SRMS)-based solid lipid microparticles (SLMs) for improved delivery of gentamicin. Lipid matrix (SRMS) [consisting of 15% w/w Phospholipon® 90G (P90G) in 35% w/w dika wax (Irvingia gabonensis) was formulated and characterized by differential scanning calorimetry (DSC). SLMs were formulated by melt-emulsification using the SRMS, PEG 4000 and gentamicin (1.0, 2.0, 3.0% w/w), and their physicochemical as well as pharmacokinetic parameters determined. In vitro permeation of gentamicin from the SLMs through artificial membrane (0.22?μm pore size) was carried out using Franz’s cell and phosphate-buffered saline (PBS, pH 7.4) as acceptor medium, while bioevaluation was performed using clinical isolates of Pseudomonas aeruginosa and Staphylococcus aureus. Stable and irregularly-shaped gentamicin-loaded SLMs of size range 34.49?±?2.56 to 53.52?±?3.09?µm were obtained. The SLMs showed sustained drug permeation and exhibited time-dependent and capacity-limited bioactivity. Overall, SLMs containing 2% w/w SRMS, 3% w/w gentamicin and PEG 4000 entrapped the highest amount of drug, gave highest IZD against the test organisms and highest permeation flux (5.239?μg/cm².min) and permeation coefficient (1.781?×?10^?6?cm/min) within 420?min, while pure gentamicin gave the least. Preliminary in vivo pharmacokinetic studies also showed an AUC-₂₄ of 1507?µg/h/ml for the optimized formulation, while that of oral drug solution was 678?µg/h/ml. This showed a 2.2-fold increase in the systemic bioavailability of gentamicin from the optimized formulation. PEGylated SRMS-based SLMs prepared with heterolipid from Irvingia gabonensis would likely offer a reliable delivery system for gentamicin.     

In Vitro Cutaneous and Percutaneous Delivery and in Vivo Efficacy of Tetracaine from Liposomal and Conventional Vehicles

The aim of this study was to quantitate drug delivery and correlate drug concentration in the skin with anesthetic effect. The rate of delivery of radiolabelled tetracaine from two different liposome formulas (1F2 and 23C2) and two conventional dosage forms (PEG Ointment USP and Glaxal^® base) was investigated in Flow-thru diffusion cells using human breast skin from mammoplasty. The results indicated a 1.5 and 4 times higher concentration of tetracaine within the skin when the liposomal formula (1F2) was used, compared to tetracaine in Glaxal^® base and PEG Ointment USP, respectively. The amount of drug delivered into the skin in 24 h from the liposomal formula was 5.3% of total applied whereas from Glaxal^® base it was 3.3% and from PEG Ointment base it was 1.2%. The amount of liposomal (1F2) phospholipids in the skin after 24h was 68.3 µg/cm² (0.2% of total applied). The steady state flux of tetracaine from liposomes (1F2) was 16.06 µg/cm²/h with a lag time of 3.1h, from Glaxal^® base 10.24 µg/cm/h with a lag time of 11.2h and from PEG Ointment it was 5.70 µg/cm²/h with a lag time of 9.0h. The second liposome formula (23C2) showed similar flux and permeability coefficient than the Glaxal^® base, however the lag time was about half. The results indicated that optimized liposome formulation is necessary to achieve maximum drug delivery. The concentration of drug within the skin and the flux measured in vitro showed correlation with in vivo efficacy. The in vivo data showed that liposomal (1F2) tetracaine produced the deepest anesthesia with shortest onset in volunteers, followed by Glaxal^® base, liposome formula 23C2 while tetracaine in PEG Ointment had a lack of effect.     

Comparative buccal permeability enhancement of didanosine and tenofovir by potential multifunctional polymeric excipients and their effects on porcine buccal histology

Abstract

This study identified and compared the buccal permeability properties of antiretroviral drugs, didanosine (ddI) and tenofovir (TNF), and the permeability effects of polymeric excipients – i.e. carboxymethylcellulose (CMC), sodium alginate (SA), polyacrylic acid (PAA) and polyethylene glycol (PEG) – as potential multifunctional excipients for buccal drug delivery. Permeation studies across porcine buccal mucosa were performed and the drug was quantified using UV spectrophotometry. The mean flux for both ddI (113–181?µg/cm²h) and TNF (40–102?µg/cm²h) increased linearly with increasing donor concentration. All polymeric excipients improved permeability of TNF while only PEG was effective for ddI. Permeability enhancement ratios at 20?mg/mL for ddI and TNF were 1.63 and 1.74, respectively, using PEG (0.5% w/v) and CMC (0.5% w/v), respectively. The maximum enhancement ratio of 2.13 for TNF was achieved with 4% w/v PEG. Light and transmission electron microscopy revealed no significant loss in cellular integrity of mucosa treated with either TNF or ddI alone or when coupled with PEG as a polymeric enhancer. Histomorphological observations correlated with flux values obtained for TNF and ddI alone, as well as with PEG’s effects on drug mass flux. TNF and ddI have demonstrated buccal delivery potential. Selective polymeric excipients provide an effective means to increase their penetration and may serve as potential formulation multifunctional excipients in a delivery system for delivery via the buccal route.     

High-efficient nano-carrier gel systems for testosterone propionate skin delivery

Abstract

The purpose of the current investigation was to evaluate the skin delivery potential of the different nano-carrier gels including liposomal gel, ethosomal gel and microemulsion gel bearing testosterone propionate (TP) as a testosterone deficient therapy. The prepared nano-particles were characterized for their shape, particle size distribution and zeta potential. In vitro skin permeation and in vivo transdermal delivery of nano-carrier gels were studied with the Franz diffusion cells and confocal laser scanning microscopy (CLSM). The results showed that all of nano-particles were almost spherical with low polydispersity and nano-metric size range from 40 to 200?nm. TP ethosomal gel also provided an enhanced transdermal flux of 7.64?±?1.4?μg/cm²/h and a decreased lag time of 0.69?h across rat skin as compared with the other two formulations. The skin penetration efficiency of TP nano-carrier gels also revealed that TP ethosomal gel would enhanced penetration of rhodamine red (RR)-loaded formulation to the deeper layers of the skin (268?µm) than the liposomal gel (192?µm) and microemulsion gel (228?µm). This study demonstrated TP ethosomal gel is a promising nano-carrier for delivering TP through the skin.     

Mucoadhesive buccal film containing ornidazole and dexamethasone for oral ulcers: in vitro and in vivo studies

A bilayered mucoadhesive buccal film containing a combination of ornidazole (OD) and dexamethasone sodium phosphate (DEX) was prepared using solvent casting to treat oral ulcers. Films were systematically evaluated in vitro to obtain the optimum formulation. The therapeutic effects of these films were investigated in the rabbit oral ulcer model and the in vivo release of OD and DEX in the human oral cavity was also evaluated. The backing layer contained ethyl cellulose and an optimal mucoadhesive layer containing both OD and DEX was produced. Films from the optimum formulation were 0.427?±?0.015?mm thick, weighed 55.89?±?0.79?mg, and had a surface pH of 6.34?±?0.01. The drug content of the optimum formulation approximated the theoretical value with good uniformity (2.959?±?0.106?mg/cm² for OD and 0.877?±?0.031?mg/cm² for DEX). The formulation showed favorable swelling characteristics and both drugs were released at >95% after 4?h. Moreover, the compound film had a statistically significant effect on mucosal repair and reduced ulcer inflammation without stimulating the human oral mucosa. C_max of OD in saliva was 37.04?μg/ml and that of DEX was 9.737?μg/ml. Given promising therapeutic effects, the compound film developed here could become a local drug delivery device for treating oral ulcers.     

Radioiodinated Hypericin: Its Biodistribution, Necrosis Avidity and Therapeutic Efficacy are Influenced by Formulation

Purpose

To study whether formulation influences biodistribution, necrosis avidity and tumoricidal effects of the radioiodinated hypericin, a necrosis avid agent for a dual-targeting anticancer radiotherapy.

Methods

Iodine-123- and 131-labeled hypericin (¹²³I-Hyp and ¹³¹I-Hyp) were prepared with Iodogen as oxidant, and formulated in dimethyl sulfoxide (DMSO)/PEG400 (polyethylene glycol 400)/water (25/60/15, v/v/v) or DMSO/saline (20:80, v/v). The formulations with excessive Hyp were optically characterized. Biodistribution, necrosis avidity and tumoricidal effects were studied in rats (n?=?42) without and with reperfused liver infarction and implanted rhabdomyosarcomas (R1). To induce tumor necrosis, R1-rats were pre-treated with a vascular disrupting agent. Magnetic resonance imaging, tissue-gamma counting, autoradiography and histology were used.

Results

The two formulations differed significantly in fluorescence and precipitation. ¹²³I-Hyp/Hyp in DMSO/PEG400/water exhibited high uptake in necrosis but lower concentration in the lung, spleen and liver (p?<?0.01). Tumor volumes of 0.9?±?0.3 cm³ with high radioactivity (3.1?±?0.3% ID/g) were detected 6 days post-treatment. By contrast, ¹³¹I-Hyp/Hypin DMSO/saline showed low uptake in necrosis but high retention in the spleen and liver (p?<?0.01). Tumor volumes reached 2.6?±?0.7 cm³ with low tracer accumulation (0.1?±?0.04%ID/g).

Conclusions

The formulation of radioiodinated hypericin/hypericin appears crucial for its physical property, biodistribution, necrosis avidity and tumoricidal effects.     

Novel carbopol-based transfersomal gel of 5-fluorouracil for skin cancer treatment: in vitro characterization and in vivo study

Abstract

5-fluorouracil (5-Fu) is an antineoplastic drug, topically used for the treatment of actinic keratosis and nonmelanoma skin cancer. It shows poor percutaneous permeation through the conventionally applicable creams and thus inefficient for the treatment of deep-seated skin cancer. In the present article, transfersomal gel containing 5-Fu was investigated for the treatment of skin cancer. Different formulation of tranfersomes was prepared using Tween-80 and Span-80 as edge activators. The vesicles were characterized for particle size, shape, entrapment efficiency, deformability and in vitro skin permeation. Optimized formulation was incorporated into 1% carbopol 940 gel and evaluated for efficacy in the treatment of skin cancer. 5-Fu-loaded transfersomes (TT-2) has the size of 266.9?±?2.04?nm with 69.2?±?0.98% entrapment efficiency and highest deformability index of 27.8?±?1.08. Formulation TT-2 showed maximum skin deposition (81.3%) and comparable transdermal flux of 21.46?µg/cm²?h. The TT-2-loaded gel showed better skin penetration and skin deposition of the drug than the marketed formulation. Composition of the transfersomal gel has been proved nonirritant to the skin. We concluded that the developed 5-Fu-loaded transfersomal gel improves the skin absorption of 5-Fu and provide a better treatment for skin cancer.     

Microneedle-assisted delivery of verapamil hydrochloride and amlodipine besylate

The aim of this project was to study the effect of stainless steel solid microneedles and microneedle rollers on percutaneous penetration of verapamil hydrochloride and amlodipine besylate.Verapamil, 2-(3,4-dimethooxyphenyl)-5-[2-(3,4 dimethoxyphenyl)ethyl-methyl-amino]-2-propan-2-yl-pentanenitrile is a calcium channel blocker agent that regulates high blood pressure by decreasing myocardial contractilty, heart rate and impulse conduction. Amlodipine, (R, S)-2-[(2-aminoethoxy) methyl]-4-(2-chlorophenyl)-3-ethoxycarbonyl-5-methoxycarbonyl-6-methyl-1, 4-dihydropyridine, is a calcium channel blocker that is used for the management of hypertension and ischemic heart disease. Passive penetration of verapamil and amlodipine across the skin is low. In vitro studies were performed with microneedle-treated porcine ear skin using vertical static Franz diffusion cells (PermeGear, Hellertown, PA, USA). The receiver chamber contained 5 ml of PBS (pH7.4) and was constantly maintained at 37 °C temperature with a water circulation jacket. The diffusion area of the skin was 1.77 cm². The donor compartment was loaded with 1 ml of the solution containing 2.5 mg/ml of amlodipine besylate. The donor chamber was covered with parafilm to avoid evaporation. Passive diffusion across untreated porcine skin served as control. Aliquots were taken every 2 h for 12 h and analyzed by liquid chromatography–mass spectrometry. Transcutaneous flux of verapamil increased significantly from 8.75 μg/cm²/h to 49.96 μg/cm²/h across microneedle-roller treated porcine skin. Percutaneous flux of amlodipine besylate following the use of stainless steel microneedles was 22.39 μg/cm²/h. Passive flux for the drug was 1.57 μg/cm²/h. This enhancement of amlodipine flux was statistically significant. Transdermal flux of amlodipine with microneedle roller was 1.05 μg/cm²/h in comparison with passive diffusion flux of 0.19 μg/cm²/h. The difference in flux values was also statistically significant. Stainless steel solid microneedles and microneedle rollers increased percutaneous penetration of verapamil hydrochloride and amlodipine besylate. It may be feasible to develop transdermal microneedle patches for these drugs.