Erbium:YAG fractional laser ablation improves cutaneous delivery of pentoxifylline from different topical dosage forms.

Topical application of pentoxifylline (PTX) would enable targeted treatment of radiation-induced skin fibrosis. However, PTX is hydrophilic with limited partitioning into the stratum corneum. The objective of this study was to investigate whether use of Erbium:YAG fractional laser ablation and different topical dosage forms (solution, hydrogel and patch) could be used to improve PTX cutaneous delivery as opposed to transdermal permeation. Initial results confirmed that fractional laser ablation significantly increased PTX delivery from each dosage form compared to passive controls. Delivery efficiencies of âˆ¼ 30% were achieved with each dosage form but a large proportion of PTX permeated across the skin; thus, fluences were decreased to create shallower micropores, their depth being linearly dependent on fluence. The hydrogel was selected as the optimal formulation and PTX delivery efficiencies were further increased (44%-67%) by reducing the amount of hydrogel applied (better mimicking conditions of use). As this resulted in PTX depletion in the formulation, a loss of dependence of delivery on laser fluence was observed. These findings suggest that fractional laser ablation at moderate fluences enables an effective and targeted cutaneous delivery of PTX from a hydrogel formulation, which can be easily produced without the need for complex equipment.

Laser-induced transient skin disruption to enhance cutaneous drug delivery.

The use of pressure waves (PW) to disrupt the stratum corneum (SC) temporarily is an effective strategy to increase the deposition of drug molecules into the skin. However, given the rather modest outcomes when compared with ablation-assisted drug delivery, its potential has been underestimated. Accordingly, the aim of this study was to examine the impact of Resonant Amplitude Waves (RAWs) on increasing cutaneous delivery. RAW phenomena are triggered by focusing a high-peak-power pulsed laser onto an appropriate transducer structure, under space- and time-controlled resolution. In order to determine the optimal conditions for the generation and use of RAWs, a screening of laser parameters setting and an analysis of different geometries of the impact pattern over diverse materials used as transducers was performed, analyzing the footprint of the RAW waves in an agarose gel. The results obtained were then checked and fine-tuned using human skin samples instead of agarose. Furthermore, ex vivo experiments were carried out to characterize the effect of the RAWs in the cutaneous delivery of diclofenac (DIC) and lidocaine (LID) administered in the form of gels. The application of RAWs resulted in an increased delivery of DIC and LID to the skin, whose intensity was dependent on the composition of the formulation. In fact, the maximum observed for DIC and LID in short-time experiments (39.1 ± 11.1 and 153 ± 16 µg/cm2, respectively) was comparable to those observed using ablation-assisted drug delivery under the same conditions. In conclusion, the combination of RAWs with specific formulation strategies is a feasible alternative for the cutaneous delivery of drug candidates when short onset of action is required.

Targeted cutaneous delivery of etanercept using Er:YAG fractional laser ablation.

The aim was to investigate the feasibility of using Er:YAG fractional laser ablation to enable topical cutaneous delivery of etanercept (ETA). Preliminary investigations into the effect of fluence on micropore depth, measured by full-field optical coherence tomography, were followed by quantitative experiments to determine ETA delivery and its cutaneous biodistribution from solution and hydrogel formulations. Visualization studies were performed using confocal laser scanning microscopy and an ETA-fluorescein conjugate. Micropore depth was linearly dependent on laser fluence. However, use of a single pulse or "pulse stacking" (i.e. multiple pulses) to apply a given fluence affected pore depth; this was accommodated mathematically by including a "stacking factor". ETA delivery into porated skin from solution and 0.8% Carbopol® formulations was equivalent: increasing ETA content in the gels from 0.5 to 1 and 2% increased ETA delivery linearly (Formulations 7-9: 5.12 ± 0.95 to 7.48 ± 1.45 and 11.2 ± 2.2 µg/cm2, respectively; 10% FAA, 89.9 J/cm2, 5 ppp); occlusion further increased ETA delivery from Formulation 9 to 23.17 ± 6.62 µg/cm2. Cutaneous biodistribution studies demonstrated that ETA was delivered in therapeutically relevant amounts to the epidermis and dermis. Topical laser-assisted delivery of ETA might expand its range of clinical indications to include recalcitrant but not widespread psoriatic plaques (clinical trial underway).

Enhancing cutaneous delivery with laser technology: Almost there, but not yet.

Preclinical research has shown the potential of different laser-based strategies (direct ablation, photothermolysis and mechanical waves) to overcome the stratum corneum and facilitate the cutaneous delivery of drugs. However, specific protocols for the routine use of these strategies have not been stablished yet. The aim of this review has been to provide the readers with a view of the translational prospects of the different laser technologies with regards to their utility for enhancing the penetration of drugs. For this, we have comparatively analyzed the preclinical research disclosed for laser-assisted delivery of classical small molecules as well as new biologics with the studies performed at the clinical level. In addition, we present the future perspectives of laser technological developments considering the evolution of the global laser market.

Topical iontophoresis of buflomedil hydrochloride increases drug bioavailability in the mucosa: A targeted approach to treat oral submucous fibrosis.

The aim was to investigate the effect of constant current iontophoresis on the delivery and biodistribution of buflomedil hydrochloride (BUF) in the buccal mucosa. Quantification was by UHPLC-MS/MS; in addition to total delivery, the amounts present in the epithelia and the lamina propria (the target tissue) were also determined. Two-compartment vertical diffusion cells were used to investigate the effect of current density (0.5, 1 and 2 mA/cm2), application time (5, 10 and 20 min) and concentration (5, 10 and 20 mM) on iontophoretic delivery of BUF from aqueous solutions. In contrast to passive delivery, iontophoresis for 10 min at 1 mA/cm2 resulted in statistically equivalent transport from a 20 mM solution and a 2% HEC hydrogel (with equivalent BUF loading; 20 µmol). BUF delivery from the hydrogel using diffusion cells and a new coplanar "side-by-side" set-up was statistically equivalent (304.2 ±â€¯28.9 and 278.2 ±â€¯40.3 µg/cm2) - passive delivery was also similar. Iontophoresis (10 min at 1 mA/cm2) using a thin film (20 µmol BUF) was superior to the passive control (323.3 ±â€¯5.9 and 24.8 ±â€¯5.9 µg/cm2). Concentrations in the LP were ~700-fold > IC50 to block collagen production, potentially providing a new therapeutic strategy for oral submucous fibrosis.

Er:YAG fractional laser ablation for cutaneous co-delivery of pentoxifylline and d-α-tocopherol succinate: A new approach for topical treatment of radiation-induced skin fibrosis.

Radiation induced fibrosis is a common side-effect after radiotherapy. Pentoxifylline is reported to reverse radiation injuries when used in conjunction with D-α-tocopherol. However, pentoxifylline has a short half-life, limited oral bioavailability, and induces several systemic adverse effects. The objective of this study was to investigate the feasibility of using Er:YAG fractional laser ablation to enable simultaneous cutaneous delivery of pentoxifylline and D- α -tocopherol succinate from poly(lactide-co-glycolide) microparticles prepared using the freeze-fracture technique. In vitro release experiments demonstrated the different release profiles of the two molecules, which were influenced by their very different lipophilicities and aqueous solubilities. Experiments were then performed to investigate the effect of laser fluence on pore depth and so determine the pore volume available to host the topically applied microparticles. Application of the pentoxifylline and D-α-tocopherol succinate containing microparticles, prepared with RESOMER® RG 502H, to laser porated skin for 48 h, resulted in simultaneous delivery of pentoxifylline (69.63 ±â€¯6.41 µg/cm2; delivery efficiency 46.4%) and D-α-tocopherol succinate (33.25 ±â€¯8.91 µg/cm2; delivery efficiency 22.2%). After deposition into the micropores, the poly(lactide-co-glycolide) microparticles containing pentoxifylline and D-α-tocopherol succinate could serve as an intraepidermal depot to enable sustained drug delivery after micropore closure and thereby reduce the need for repeated microporation.

Fractional laser ablation for the targeted cutaneous delivery of an anti-CD29 monoclonal antibody - OS2966.

Monoclonal antibodies targeting cytokines are administered parenterally for the systemic treatment of severe psoriasis. However, systemic exposure to the biologic increases the risk of side-effects including immunosuppression, whereas only a small fraction of the active molecules actually reaches the target organ, the skin. This preclinical study examines the feasibility of delivering a humanized anti-CD29 monoclonal antibody (OS2966) topically to skin using minimally-invasive fractional laser ablation. This approach would enable the targeted use of a biologic for the treatment of recalcitrant psoriatic plaques in patients with less widespread disease while minimizing the risk of systemic exposure. First, the effect of a wide range of laser poration conditions on skin permeation and deposition of OS2966 was tested in vitro to determine optimal microporation parameters. Subsequently, confocal laser scanning microscopy was employed to visualize the distribution of fluorescently-labelled OS2966 in skin. The results demonstrated that delivery of OS2966 into and across skin was feasible. Above fluences of 35.1 J/cm2, skin deposition and permeation were statistically superior to passive delivery reaching values up to 3.7 ± 1.2 µg/cm2 at the most aggressive condition. Selective targeting of the skin was also possible since ≥70% of the OS2966 was delivered locally to the skin. Although nanogramme quantities were able to permeate across skin, these amounts were orders of magnitude lower than levels seen following subcutaneous or intravenous injection and would result in minimal systemic exposure in vivo. The diffusion of fluorescently-labelled OS2966 into the skin surrounding the pores was clearly higher than in intact skin and demonstrated the feasibility of delivering the antibody at least as deep as the dermo-epithelial junction, a critical border region where inflammatory cells cross to promote disease progression. These preliminary results confirm that fractional laser ablation can be used for the cutaneous delivery of OS2966 and now preclinical/clinical studies are required to demonstrate therapeutic efficacy.

Selective delivery of adapalene to the human hair follicle under finite dose conditions using polymeric micelle nanocarriers.

Drug delivery systems that target the pilosebaceous unit (PSU) selectively could improve the clinical management of diseases that originate in the hair follicle. The aims of this study were (i) to prepare polymeric micelles using d-α-tocopheryl polyethylene glycol succinate diblock copolymer that incorporated adapalene (ADA), a retinoid indicated for Acne vulgaris, and (ii) to investigate the feasibility of delivering ADA preferentially to the PSU under finite dose conditions - thereby better approximating actual conditions of use by patients. Incorporation of ADA into spherical micelles (dn <20 nm) increased aqueous solubility by ∼50 000-fold (from <4 ng mL-1 to 0.2 mg mL-1). Optimized micelle solution and gel formulations (0.02% ADA) were stable after storage for 4 weeks at 4 °C. Finite dose experiments using full-thickness porcine and human skin revealed that ADA delivery efficiency from micelle solution and gel formulations was equivalent and was >2- and 10-fold higher than that from Differin® gel and Differin® cream (products containing ADA at 0.1% (w/w)). Follicular delivery studies in human skin, using a punch biopsy technique to extract the intact PSU, demonstrated that the micelle solution and gel formulations did indeed enable preferential delivery of ADA to the PSU (4.5- and 3.3-fold higher, respectively, than that to PSU-free skin biopsies). Confocal laser scanning microscopy provided visual corroboration that ADA was uniformly distributed in the hair follicles. In conclusion, the results confirmed that polymeric micelle nanocarriers enabled selective, targeted drug delivery to the PSU under finite dose conditions and so might improve therapy of follicular diseases and decrease off-site side-effects.

Targeted intracorneal delivery-Biodistribution of triamcinolone acetonide following topical iontophoresis of cationic amino acid ester prodrugs.

The aim was to investigate intracorneal iontophoresis of biolabile triamcinolone acetonide (TA) amino acid ester prodrugs (TA-AA). Arginine and lysine esters of TA (TA-Arg and TA-Lys, respectively) were synthesized and characterized; quantification was performed by HPLC-UV and UHPLC-MS/MS. The aqueous solubility of the prodrugs (at pH 5.5) was ∼1000-fold greater than TA. Anodal iontophoresis (10min at 3mA/cm2) of TA-AA was investigated using isolated porcine cornea. Although no statistically significant difference was observed in total intracorneal delivery of TA (468.25±59.70 and 540.85±79.16nmolTA/cm2, for TA-Arg and TA-Lys, respectively), the different susceptibilities of the prodrugs to hydrolysis influenced intracorneal biodistribution. Quantification of TA in twenty-five 40µm thick corneal lamellae revealed significantly deeper penetration of TA following TA-Lys iontophoresis. Its superior resistance to hydrolysis enabled sustained electromigration into the deeper cornea suggesting judicious prodrug selection might enable targeted regioselective drug delivery. The intracorneal biodistribution following anodal iontophoresis of TA-Arg (2.3mM; 10min, 3mA/cm2) was visualized by full field optical coherence tomography providing qualitative confirmation of the extensive intracorneal penetration of TA. Short duration iontophoresis of TA-AA prodrugs may improve deep corneal bioavailability and efficacy in vivo, constituting a "single-shot" treatment option for corneal allograft rejection.

Cutaneous iontophoresis of µ-conotoxin CnIIIC-A potent NaV1.4 antagonist with analgesic, anaesthetic and myorelaxant properties.

Cutaneous iontophoretic delivery of µ-conotoxin CnIIIC (XEP), a potent peptide antagonist of the NaV1.4 sodium channel, was investigated using porcine ear skin and validated using human abdominal skin. Initial results demonstrated that cutaneous deposition of XEP following iontophoresis was superior to passive delivery and increased with current density. XEP deposition after iontophoresis at 0.1, 0.3 and 0.5mA/cm2 for 2h and 4h was 22.4±0.4, 34.5±1.4, 57.4±7.6µg/cm2 and 30.6±5.4, 53.9±17.2, 90.9±30.8µg/cm2, respectively (cf. corresponding passive controls - 9.8±1.1 and 16.9±1.0µg/cm2). Moreover, tape-stripping studies showed that XEP was mainly adsorbed on the skin surface when administered passively. Co-iontophoresis of acetaminophen demonstrated that XEP was present in the skin as it significantly reduced convective solvent flow as evidenced by the ∼7-fold decrease in acetaminophen permeation. Shorter duration iontophoresis (15, 30 and 60min) was performed and the effect of current density (0.1, 0.3 and 0.5mA/cm2) and concentration (0.1 and 1mM) investigated. Skin deposition of XEP was already quantifiable after iontophoresis for 15min at the lower concentration. There was no statistically significant difference between XEP deposition in porcine and human skin. Confocal laser scanning microscopy enabled post-iontophoretic visualization of FITC-labelled XEP in the epidermis.

A UHPLC-UV Method to Quantify Skin Deposition and Transdermal Permeation of Tizanidine Hydrochloride.

Tizanidine hydrochloride is an α2-adrenergic agonist used for the symptomatic relief of spasticity associated with multiple sclerosis or with spinal cord injury or disease. The objective of this study was to develop an isocratic, robust and sensitive ultra-high performance liquid chromatography method using UV detection for use in a project to develop a transdermal therapeutic system to deliver tizanidine across the skin. Isocratic separation was achieved using a C18 column and a mobile phase comprising a 80:20 mixture of 0.004% trifluoroacetic acid in water and MeCN (pH* 3.2) at a flow rate of 0.2 mL min(-1) Tizanidine eluted at 1.499 min and the total run time was 2 min. The method was specific, robust and the response was accurate, precise and linear from 17.4 to 290 ng mL(-1) In contrast to existing methods, the method developed here was validated over a concentration range so as to include the low concentrations frequently observed in transdermal permeation studies and in samples extracted from the cutaneous matrix. Its suitability for use in transdermal permeation studies was subsequently tested and confirmed in preliminary experiments using porcine skin in vitro.

Fractional Laser Ablation for the Cutaneous Delivery of Triamcinolone Acetonide from Cryomilled Polymeric Microparticles: Creating Intraepidermal Drug Depots.

The efficacy of some dermatological therapies might be improved by the use of "high dose" intraepidermal drug reservoir systems that enable sustained and targeted local drug delivery, e.g., in the treatment of keloids and hypertrophic scars. Here, a fractionally ablative erbium:YAG laser was used to enable "needle-less" cutaneous deposition of polymeric microparticles containing triamcinolone acetonide (TA). The microparticles were prepared using a freeze-fracture technique employing cryomilling that resulted in drug loading efficiencies of ∼100%. They were characterized by several different techniques, including scanning electron microscopy, powder X-ray diffraction and differential scanning calorimetry. TA was quantified by validated HPLC-UV and UHPLC-MS/MS analytical methods. In vitro release studies demonstrated the effect of polymer properties on TA release kinetics. Confocal laser scanning microscopy enabled visualization of cryomilled microparticles containing fluorescein and Nile Red in the cutaneous micropores and the subsequent release of fluorescein into the micropores and its diffusion throughout the epidermis and upper dermis. The biodistribution of TA, i.e. the amount of drug as a function of depth in skin, following microparticle application was much more uniform than with a TA suspension and delivery was selective for deposition with less transdermal permeation. These findings suggest that this approach may provide an effective, targeted and minimally invasive alternative to painful intralesional injections for the treatment of keloid scars.

Evaluation of percutaneous absorption of esculetin: effect of chemical enhancers.

Percutaneous transdermal absorption of esculetin (6,7-dihydroxycoumarin), an oxidative damage inhibitor, was evaluated by means of in vitro permeation studies in which vertical Franz-type diffusion cells and pig ear skin were employed. To determine the absorption of esculetin, we validated a simple, accurate, precise, and rapid HPLC-UV method. Additionally, the effects of several percutaneous enhancers were studied. Pretreatment of porcine skin was performed with ethanol (control vehicle), decenoic acid, oleic acid, R-(+)-limonene, and laurocapram (Azone®) (5% in ethanol, w/w, respectively). Pretreatment of skin with oleic acid or laurocapram led to statistically significant differences in the transdermal flux of esculetin with respect to controls. Of the two enhancers, laurocapram showed the greatest capacity to enhance the flux of esculetin across pig skin.