Transdermal Delivery of Insulin Using Trypsin as a Biochemical Enhancer

Li, Ying-zhe; Quan, Ying‐Shu; Zang, Lei; Jin, Mengdi; Kamiyama, Fumio; Katsumi, Hidemasa; Yamamoto, Akira; Tsutsumi, Sadami

doi:10.1248/bpb.31.1574

Cited by 33 publications

(24 citation statements)

References 45 publications

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“…Trypsin enhanced the penetration of insulin, resulting in reduction of blood glucose levels in rats. [186] Mechanistic studies suggested that trypsin could disturb the structure of keratin in the SC via proteolysis but appeared to have no effect on the lipid bilayers. [186] Trypsin can also enhance the transdermal permeation of other macromolecules such as FITC-labelled dextrans and FITC-insulin.…”

Section: Transdermal Drug Deliverymentioning

confidence: 99%

Getting Drugs Across Biological Barriers

et al. 2017

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The delivery of drugs to a target site frequently involves crossing biological barriers. The degree and nature of the impediment to flux, as well as the potential approaches to overcoming it, depend on the tissue, the drug, and numerous other factors. Here we present an overview of approaches that have been taken to crossing biological barriers, with special attention to transdermal drug delivery. Technology and knowledge pertaining to addressing these issues in a variety of organs could have a significant clinical impact.

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Section: Transdermal Drug Deliverymentioning

confidence: 99%

Getting Drugs Across Biological Barriers

et al. 2017

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“…Many scientists have taken up the challenge of developing a transdermal DDS for insulin. [22][23][24][25] Iontophoresis is a powerful device for the transdermal delivery of poorly permeable drugs. TDDS have already been developed for lidocaine and are now used clinically.…”

Section: Discussionmentioning

confidence: 99%

Self-Dissolving Micropile Array Chip as Percutaneous Delivery System of Protein Drug

Ito

Hasegawa

Fukushima

et al. 2010

Biological & Pharmaceutical Bulletin

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Transdermal drug delivery systems (TDDS) have been challenged to increase the permeation rate of drugs through the skin and experimental strategies have included the use of chemical enhancers and physical methods. Of these, chemical enhancers have contributed most to the development of TDDS. Approximately 20 products of TDDS were launched on the US market by the end of 2008. Thus the penetration of small molecules through the skin can be enhanced by chemical enhancers.1) However, triggering of skin irritation and other safety concerns limit their use. As examples of physical absorption enhancement methods, iontophoresis, electroporation, and ultrasound have been investigated.2-6) Iontophoresis uses an electric field to drive ionized molecules across the skin by electrophoresis and nonionized molecules by electroosmosis. Despite concerns about skin irritation, iontophoresis may be useful for delivery of some peptides including insulin. 7) In particular, TDDS of lidocaine by iontophoresis was launched onto the US market in 2004. Also, transient enhancement of skin permeability of both small drugs and macromolecules has been shown by electroporation and ultrasound. 8,9) Recent advances in microfabrication technology have made it possible to prepare microneedles that have a possible application as novel TDDS. Since the first publication by Henry et al. 10) in 1998, microfabrication techniques for the production of silicon, metal, glass and polymer microneedle arrays with micrometer dimensions have been reported. [11][12][13][14] The microneedles are either solid or hollow and possess a geometrical shape. Microneedle TDDS are roughly defined by a micron-sized needle preparation through and by which drug is percutaneously administered. Microneedle TDDS are classified as follows: (1) extremely small needles through which drug solution can be injected into the skin; (2) metallic and/or silastic microneedles on whose surface drug is coated; and (3) metallic and/or silastic microneedles with which conduits (micropores) are made on the skin and drug solution is applied after removing the microneedles. Fully to understand the function of microneedles, the physiology of the skin must be considered. There are no blood vessels in the epidermis. Deeper, there are blood capillaries in the dermis, which forms the bulk of skin volume and contains living cells and nerves. When microneedle arrays are inserted into the skin, conduits are created for the penetration of drug across stratum corneum (SC). Once a drug penetrates the SC, it can diffuse rapidly through the deeper tissue and permeate into the underlying capillaries for systemic absorption.Our previous studies suggest that macromolecules such as insulin, 15,16) erythropoietin (EPO), 17,18) interferon, 19) and recombinant human growth hormone 20) are well absorbed through rat skin by self-dissolving micropile preparations about 2-3 mm in length with an outer diameter of 0.3-0.4 mm. In addition, a self-dissolving micropile array (SDMA), comprising 10 lines and 10 columns, was...

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“…Endmember 5 has high abundances in the periphery of the mapped area and shows a relatively high amount of lipid, as indicated by the strong band at 1744 cm À1 , assigned to ester carbonyl mode of lipids [30,31]. It also naturally has a large amount of protein, as evinced by the intensity of the bands at 1648 and 1532 cm À1 [3,28,32].…”

Section: Overall Morphology and Protein Distribution According To Ir mentioning

confidence: 99%