Transdermal Delivery of Macromolecules Using Skin Electroporation

Purposes. (1) To evaluate the feasibility of transdermal delivery ofmacromolecules by skin electroporation. (2) To assess the influenceof the molecular weight of the permeant on transport and examinewhether there exists a cut-off value of molecular weight. (3) Tolocalize the transport pathways of the macromolecules in the skin. Methods. FITC-dextran (FD) of increasing molecular weight (4.4, 12and 38 kDa) were used as model macromolecules to study the extentof transport across hairless rats skin in vitro and to localize theirdistribution in the skin by confocal scanning laser microscopy. Results. Electroporation enhanced the transport of the macromoleculesas compared to passive diffusion. The transdermal delivery by skinelectroporation of FITC and FD 4.4 was equivalent whereas transportof higher molecular weight FD was lower but significant. FITC and FD38 were observed in the epidermis both around and in the keratinocytes. Conclusions. Transdermal and topical delivery of macromolecules ofat least 40 kDa can be achieved by skin electroporation.     

Permeation enhancer strategies in transdermal drug delivery

Abstract

Today, ～74% of drugs are taken orally and are not found to be as effective as desired. To improve such characteristics, transdermal drug delivery was brought to existence. This delivery system is capable of transporting the drug or macromolecules painlessly through skin into the blood circulation at fixed rate. Topical administration of therapeutic agents offers many advantages over conventional oral and invasive techniques of drug delivery. Several important advantages of transdermal drug delivery are prevention from hepatic first pass metabolism, enhancement of therapeutic efficiency and maintenance of steady plasma level of the drug. Human skin surface, as a site of drug application for both local and systemic effects, is the most eligible candidate available. New controlled transdermal drug delivery systems (TDDS) technologies (electrically-based, structure-based and velocity-based) have been developed and commercialized for the transdermal delivery of troublesome drugs. This review article covers most of the new active transport technologies involved in enhancing the transdermal permeation via effective drug delivery system.     

Topical drug delivery systems: a patent review

Introduction: Topical administration is the favored route for local delivery of therapeutic agents due to its convenience and affordability. The specific challenge of designing a therapeutic system is to achieve an optimal concentration of a certain drug at its site of action for an appropriate duration.

Areas covered: This review summarizes innovations from the past 3 years (2012–2015) in the field of topical drug delivery for the treatment of local infections of the vagina, nose, eye and skin. The review also throws some light on the anatomy and physiology of these organs and their various defensive barriers which affect the delivery of drugs administered topically.

Expert opinion: Topical administration has been gaining attention over the last few years. However, conventional topical drug delivery systems suffer from drawbacks such as poor retention and low bioavailability. The successful formulation of topical delivery products requires the careful manipulation of defensive barriers and selection of a soluble drug carrier. Extensive research is required to develop newer topical drug delivery systems aiming either to improve the efficacy or to reduce side effects compared to current patented systems.     

Topical delivery of acyclovir and ketoconazole

Abstract

Context: Viral and fungal cutaneous manifestations are regularly encountered in immunocompromised human immunodeficiency virus/acquired immunodeficiency syndrome individuals and can be treated by drugs such as acyclovir and ketoconazole, respectively.

Objective: The aim of this study was to determine whether the novel Pheroid? delivery system improved the transdermal delivery and/or dermal delivery of acyclovir and ketoconazole when incorporated into semi-solid formulations.

Materials and methods: Semi-solid products (creams and emulgels) containing these drug compounds were formulated, either with or without (control) the Pheroid? delivery system. The stability of the formulated semi-solid products was examined over a period of six months and included the assay of the actives, pH, viscosity, mass loss and particle size observation. Vertical Franz cell diffusion studies and tape stripping methods were used to determine the in vitro, stratum corneum (SC)-epidermis and epidermis-dermis delivery of these formulations.

Results and discussion: Stability tests showed that none of the formulations were completely stable. Acyclovir showed a biphasic character during the in vitro skin diffusion studies for all the tested formulations. The Pheroid? cream enhanced the transdermal, SC-epidermis and epidermis–dermis delivery of acyclovir the most. The average amount of ketoconazole diffused over 12?h showed improved delivery of ketoconazole, with the Pheroid? emulgel exhibiting the best transdermal and epidermis–dermis delivery.

Conclusion: The Pheroid? formulae increased transdermal penetration as well as delivery to the dermal and epidermal skin layers. The Pheroid? emulgel and the Pheroid? cream increased the topical delivery of ketoconazole and acyclovir, respectively.     

Trypsin as a novel potential absorption enhancer for improving the transdermal delivery of macromolecules

Objectives The aim was to assess the effect of trypsin on the transdermal delivery of macromolecules by applying its specific biochemical properties to the stratum corneum of the skin. Methods Fluorescein isothiocyanate (FITC)‐labelled dextrans (FDs), with molecular weights of 4 to 250 kDa, and FITC‐insulin were used as model macromolecules and a model polypeptide, and the in‐vitro transdermal permeation experiments, with or without trypsin (0.1–2.5%), were carried out using rat skin and cultured human epidermis. The mechanism for the enhancement of trypsin was also studied using fluorescence and conventional light microscopy. Key findings Trypsin significantly increased the transdermal permeability of all FDs through the rat skin (2.0‐ to 10.0‐fold). It also markedly enhanced the permeation of FD4 through three‐dimensional cultured human epidermis (3.1‐fold), which was used to evaluate the transport pathways other than the transfollicular route. Furthermore, the permeation flux of FITC‐insulin was increased by 10.0‐fold with trypsin pretreatment (from 0.02 ± 0.00 to 0.20 ± 0.07 μg/cm² per h). Mechanistic studies indicated that trypsin affects both the intercellular pathway and the hair follicular route, and may alter stratum corneum protein structures, thereby affecting skin barrier properties. Conclusions This study suggests that trypsin could be effective as a biochemical enhancer for the transdermal delivery of macromolecules including peptide and protein drugs.     

Transdermal iontophoresis patch with reverse electrodialysis

Reverse electrodialysis (RED) technology generates energy from the salinity gradient by contacting waters with different salinity. Herein, we develop the disposable skin patch using this eco-friendly energy. The current density, which can be controlled easily without special circuit, is enough to iontophoretic drug delivery. In vitro study, this iontophoretic system enhanced the transdermal delivery of peptide, which is difficult to penetrate the skin barrier by simple diffusion. We design the disposable iontophoretic skin patch using RED system and suggest this patch can be apply on new cosmetic patch or disposable drug patch.     

Enhancement of transdermal delivery of progesterone using medium-chain mono and diglycerides as skin penetration enhancers

We evaluated whether medium-chain mono and diglycerides (MCG) can be utilized to optimize the transdermal delivery of progesterone (PGT). MCG was studied at 10–70% (w/w) in propylene glycol (a polar solvent) or Myvacet oil (nonpolar solvent); PGT was used at 1% (w/w). The topical (to the skin) and transdermal (across the skin) delivery of PGT were evaluated in vitro using porcine ear skin. When incorporated in propylene glycol, MCG at 10% enhanced the topical and transdermal delivery of PGT by 2.5- and 7-fold, respectively. At 20–50%, topical delivery was further enhanced while transdermal delivery gradually returned towards baseline. At 70%, MCG enhanced neither the delivery to viable skin nor the transdermal delivery of PGT. Similar concentration-dependent effects were observed when MCG was incorporated in Myvacet oil, but their magnitudes were 2- to 3-fold smaller. The relative safety of MCG was assessed in cultured fibroblasts and compared to propylene glycol (regarded as safe) and sodium lauryl sulfate (moderate-to-severe irritant). Both MCG and propylene glycol were substantially less cytotoxic than sodium lauryl sulfate. We conclude that formulations containing 10% MCG in propylene glycol may be a simple and safe method to improve the transdermal delivery of progesterone and promote its use in hormone replacement therapy.     

皮肤给药的经皮吸收与测量技术研究进展

经皮给药系统（TDDS）可避免首关效应、胃肠道破坏，为新型皮肤给药系统，可通过控制释放而延长治疗效果，成为药物制剂开发研究的热点之一。但是，药物的理化性质以及皮肤屏障影响药物的经皮吸收。综述了TDDS常用的促渗透技术，包括化学、物理、纳米、天然促渗透技术；介绍了促渗透能力的测定方法，包括体外、离体和体内评估皮肤渗透性的方法。通过对经皮药物递送系统和经皮吸收能力测定方法的归纳与总结，以期为TDDS的合理使用和快速发展提供参考。     

Hyaluronan-modified transfersomes based hydrogel for enhanced transdermal delivery of indomethacin

Hyaluronic acid (HA), as a hygroscopic and biocompatible molecule, has displayed unique permeation enhancement in transdermal delivery systems. Hence, indomethacin (IND) was encapsulated in HA-modified transfersomes (IND-HTs) to enhance transdermal IND delivery to reduce adverse effects in this study. The physiochemical properties of IND-HTs were characterized. Results showed that the prepared IND-HTs were spherical and revealed good entrapment efficiency (87.88 ± 2.03%), with a nanometric particle size (221.8 ± 93.34 nm). Then, IND-HTs were further incorporated into a carbopol 940 hydrogel (IND-HTs/Gel) to prolong retention capacity on the skin. The in vitro release and skin permeation experiments of IND-HTs/Gel were carried out with the Franz diffusion cells. It was found that IND-HTs/Gel exhibited sustained drug release, as well as superior drug permeation and flux across the skin. Confocal laser scanning microscopy showed improved penetration of HTs/Gel with a wider distribution and higher fluorescence intensity. The hematoxylin–eosin stained showed that HA improved the transdermal effect by changing the microstructure of skin layers and decreasing skin barrier function. In addition, IND-HTs/Gel showed significant analgesic activity in hot plate test and no potentially hazardous skin irritation. This study indicated that the developed IND-HTs/Gel could be a promising alternative to conventional oral delivery of IND by topical administration.     

Self-double-emulsifying drug delivery system incorporated in natural hydrogels: a new way for topical application of vitamin C

This study aimed at the in vitro evaluation of topical hydrogels containing vitamin C-loaded self-double-emulsifying drug delivery system (SDEDDS). The liquid SDEDDS was converted into suitable unmodified xanthan gum hydrogels formulation and the prepared semi-solid hydrogels provided appropriate gel characteristics like pH, viscosity, spreadability, etc. The 5-week storage test displayed that the prepared hydrogels possessed good physicochemical stability. In addition, no significant cytotoxicity to L929 cells was observed for the vitamin C-loaded SDEDDS-based hydrogels, and the prepared hydrogels depicted a sustained drug release over an 8-h period. In vitro permeation study showed that the vitamin C-loaded SDEDDS-based hydrogels could significantly enhance vitamin C retention in the skin and permeation through the skin. The overall results demonstrated that the hydrogels containing vitamin C-loaded SDEDDS could be considered as a promising formulation for topical application.     

Comparative Study of the Skin Penetration of Protein Transduction Domains and a Conjugated Peptide

Purpose. We examined the ability of a protein transduction domain (PTD), YARA, to penetrate in the skin and carry a conjugated peptide, P20. The results with YARA were compared to those of a well-known PTD (TAT) and a control, nontransducing peptide (YKAc). The combined action of PTDs and lipid penetration enhancers was also tested.Methods. YARA, TAT, YKAc, P20, YARA-P20, and TAT-P20 were synthesized by Fmoc chemistry. Porcine ear skin mounted in a Franz diffusion cell was used to assess the topical and transdermal delivery of fluorescently tagged peptides in the presence or absence of lipid penetration enhancers (monoolein or oleic acid). The peptide concentrations in the skin (topical delivery) and receptor phase (transdermal delivery) were assessed by spectrofluorimetry. Fluorescence microscopy was used to visualize the peptides in different skin layers.Results. YARA and TAT, but not YKAc, penetrated abundantly in the skin and permeated modestly across this tissue. Monoolein and oleic acid did not enhance the topical and transdermal delivery of TAT or YARA but increased the topical delivery of YKAc. Importantly, YARA and TAT carried a conjugated peptide, P20, into the skin, but the transdermal delivery was very small. Fluorescence microscopy confirmed that free and conjugated PTDs reached viable layers of the skin.Conclusions. YARA and TAT penetrate in the porcine ear skin in vitro and carry a conjugated model peptide, P20, with them. Thus, the use of PTDs can be a useful strategy to increase topical delivery of peptides for treatment of cutaneous diseases.     

Microemulsions: applications in transdermal and dermal delivery

Microemulsions have gained much interest as second-generation colloidal carrier systems for the dermal/transdermal delivery of the various hydrophilic and lipophilic drugs. The advantages associated with microemulsions include spontaneity of formation, ease of manufacturing, high solubilization capacity, and improved drug stability. This review focuses on the excipients available for the formulation of topical microemulsions and the potential mechanisms responsible for improvements in the dermal/transdermal delivery of therapeutic agents. It also describes the in vitro and in vivo investigations reported for the various classes of therapeutic agents, along with the recent developments.     

Nanoemulsions as potential vehicles for transdermal and dermal delivery of hydrophobic compounds: an overview

Introduction: In recent years, nanoemulsions have been investigated as potential drug delivery vehicles for transdermal and dermal delivery of many compounds especially hydrophobic compounds in order to avoid clinical adverse effects associated with oral delivery of the same compounds. Droplet size and surface properties of nanoemulsions play an important role in the biological behavior of the formulation.

Areas covered: In this review, current literature of transdermal and dermal delivery of hydrophobic compounds both in vitro as well as in vivo has been summarized and analyzed.

Expert opinion: Nanoemulsions have been formulated using a variety of pharmaceutically acceptable excipients. In many cases of dermal and transdermal nanoemulsions, the skin irritation or skin toxicity issues on human beings have not been considered which needs to be evaluated properly. In the last decade, much attention has been made in exploring new types of nanoemulsion-based drug delivery system for dermal and transdermal delivery of many hydrophobic compounds. This area of research would be very advantageous for formulation scientists in order to develop some nanoemulsion-based formulations for their commercial exploitation and clinical applications.     

凝胶材料及其在经皮给药系统中的应用与研究进展

凝胶材料具有触感舒适、透气性好、高粘弹性等其他材料所无法比拟的优势,在经皮给药系统中备受青睐,被广泛应用于现代经皮给药制剂如贴剂、贴膏剂、凝胶剂、膜剂当中。随着医药材料的创新发展,许多具有优异功能的新型凝胶材料涌现,使经皮给药制剂的应用范围得到扩大,性能得以优化。通过综述凝胶材料的分类、性能及其在经皮给药系统中的应用,总结最新研究进展,为凝胶材料在经皮给药系统的创新应用提供借鉴和参考。     

In vitro and in vivo assessment of polymer microneedles for controlled transdermal drug delivery

Microneedles (MNs) system for transdermal drug delivery has the potential to improve therapeutic efficacy, proving an approach that is more convenient and acceptable than traditional medication systems. This study systematically researched dissolving polymer MNs fabricated from various common FDA-approved biocompatible materials, including gelatine, chitosan, hyaluronic acid (HA) and polyvinyl alcohol (PVA). Upon application of MN patches to the porcine cadaver skin, the MNs effectively perforated the skin and delivered drugs to subcutaneous tissue on contact with the interstitial fluid. Both the in vitro and in vivo drug release tests showed the similar trends but different release rates among the prepared MNs. Interestingly, the drug-release kinetics of PVA MNs were able to be altered by changing the molecular weight. To evaluate the feasibility using the proposed MNs for treating diabetes, an in vivo insulin absorption study in diabetic mice was performed. The results showed different insulin release properties of MNs fabricated from various kinds of polymer, leading to different decrease in blood glucose levels. We made a systematic and comprehensive study of some drug-loaded polymer MNs, and anticipated that dissolving polymer MNs have potential to improve therapeutic efficacy through controlled drug release.     

Veterinary drug delivery: potential for skin penetration enhancement

A range of topical products are used in veterinary medicine. The efficacy of many of these products has been enhanced by the addition of penetration enhancers. Evolution has led to not only a highly specialized skin in animals and humans, but also one whose anatomical structure and skin permeability differ between the various species. The skin provides an excellent barrier against the ingress of environmental contaminants, toxins, and microorganisms while performing a homeostatic role to permit terrestrial life. Over the past few years, major advances have been made in the field of transdermal drug delivery. An increasing number of drugs are being added to the list of therapeutic agents that can be delivered via the skin to the systemic circulation where clinically effective concentrations are reached. The therapeutic benefits of topically applied veterinary products is achieved in spite of the inherent protective functions of the stratum corneum (SC), one of which is to exclude foreign substances from entering the body. Much of the recent success in this field is attributable to the rapidly expanding knowledge of the SC barrier structure and function. The bilayer domains of the intercellular lipid matrices within the SC form an excellent penetration barrier, which must be breached if poorly penetrating drugs are to be administered at an appropriate rate. One generalized approach to overcoming the barrier properties of the skin for drugs and biomolecules is the incorporation of suitable vehicles or other chemical compounds into a transdermal delivery system. Indeed, the incorporation of such compounds has become more prevalent and is a growing trend in transdermal drug delivery. Substances that help promote drug diffusion through the SC and epidermis are referred to as penetration enhancers, accelerants, adjuvants, or sorption promoters. It is interesting to note that many pour-on and spot-on formulations used in veterinary medicine contain inert ingredients (e.g., alcohols, amides, ethers, glycols, and hydrocarbon oils) that will act as penetration enhancers. These substances have the potential to reduce the capacity for drug binding and interact with some components of the skin, thereby improving drug transport. However, their inclusion in veterinary products with a high-absorbed dose may result in adverse dermatological reactions (e.g., toxicological irritations) and concerns about tissue residues. These are important considerations when formulating a veterinary transdermal product when such compounds are added, either intentionally or otherwise, for their penetration enhancement ability.     

Preparation and characterization of HA–PEG–PCL intelligent core–corona nanoparticles for delivery of doxorubicin

The objective of the present study was to synthesize core–corona nanoparticles of doxorubicin (DOX) using hyaluronic acid–polyethyleneglycol–polycaprolactone (HA–PEG–PCL) copolymer for tumor targeting. Targeting efficiency of HA–PEG–PCL nanoparticles was compared with non-HA-containing nanoparticles (methoxy poly ethylene glycol (MPEG)–PCL). The copolymers were chemically synthesized and characterized by IR and NMR spectroscopies. The nanoparticles were characterized for shape and morphology by transmission electron microscopy, particle size, percentage of drug entrapment, and in vitro drug release profile. Differential scanning calorimetry and X-ray diffraction studies were also performed to appraise the crystalline or amorphous nature of DOX inside the polymer matrix. Formulations were prepared using different DOX:polymer ratios (1:1–1:3 w/w) and the optimum formulation with the drug:polymer ratio of 1:1 showed the mean particle size of 95 ± 5 nm and entrapment efficiency of 95.56% in the case of HA–PEG–PCL nanoparticles, while the values were 115 nm and 95.50%, respectively, in the case of MPEG–PCL nanoparticles. The HA–PEG–PCL nanoparticles could release DOX for up to 17 days, whereas the MPEG–PCL nanoparticles could release it for up to 14 days. The hemolytic toxicity and hematological studies confirmed that both DOX-loaded HA–PEG–PCL and MPEG–PCL nanoparticles were safe and suitable for sustained and targeted drug delivery. The tissue distribution study and tumor growth inhibition were performed after intravenous injection of nanoparticles in Ehrlich ascites tumor (EAT)-bearing mice. The nanoparticles of HA–PEG–PCL copolymer accomplishes efficient delivery of DOX in EAT tumor when compared with the MPEG–PCL nanoparticles by the process of receptor-mediated endocytosis, as well as enhanced permeability and retention effect.     

Biomedical applications of microneedles in therapeutics: recent advancements and implications in drug delivery

Introduction: The skin, as the largest organ, is a better option for drug delivery in many diseases. However, most transdermal delivery is difficult due to the low permeability of therapeutics across the various skin layers. There have been many innovations in transdermal drug delivery to enhance the therapeutic efficacy of the drugs administered. Microneedles (MN), micron sized needles, are of great interest to scientists as a new therapeutic vehicle through transdermal routes, especially for vaccines, drugs, small molecules, etc.

Areas covered: This review covers new insights into different types of MNs such as solid, hollow, coated and dissolving MNs (SMNs, HMNs, CMNs, and DMNs) for selected biomedical applications in detail. Specific focus has been given to CMNs and DMNs for vaccine and drug delivery applications with recent developments in new MNs covered.

Expert opinion: This review explores the feasibility of innovative MNs used as a drug delivery carrier. Because most of the SMNs and HMNs have many limitations, it is difficult to achieve therapeutic efficacy. Therefore, many scientists are investigating functional modifications of MNs through covalent and non-covalent methods, especially for CMNs and DMNs. The biomedical applications of MNs are growing and new exciting improvements could be achieved, thus resulting in better micro/nano technologies in the near future.     

Penetration depth,concentration and efficiency of transdermal α-arbutin delivery after ultrasound treatment with albumin-shelled microbubbles in mice

Recently, the feasibility and effects of using microbubbles (MBs) as an ultrasound (US) contrast agent for enhancing the penetration in transdermal delivery in vivo have been demonstrated, but the mechanism and efficiency are unclear. This study demonstrates the penetration depth, concentration and efficiency of transdermal α-arbutin delivery during 4 weeks after US treatment with MBs in mice. Experimental animals were randomly divided into the following four groups (n?=?5 animals per group): (1) penetrating α-arbutin alone (C), (2) US combined with penetrating α-arbutin, (3) US combined with MBs and penetrating α-arbutin, and (4) US combined with diluted MBs and penetrating α-arbutin (UBD). The penetration depths in agarose phantoms and pigskin were 47 and 84% greater for group UBD, respectively, than for group C. The in vitro skin penetration by 2% α-arbutin after 3?h was 83% greater in group UBD than in group C. The degree of in vivo skin whitening (quantified as the luminosity index) in group UBD significantly increased by 25% after 1 week, 34% after 2 weeks, and then stabilized after 3 weeks at 37% in C57BL/6J mice over a 4-week experimental period. Our results indicate that combined treatment with optimal US and MBs can increase skin permeability so as to enhance α-arbutin delivery to inhibit melanogenesis without damaging the skin in mice.