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Anatomical and Histological Factors Affecting Intranasal Drug and Vaccine Delivery  9(6): Pp. 566 - 582 Sveinbjorn Gizurarson [View Abstract] [Open Access Plus]

The aim of this review is to provide an understanding of the anatomical and histological structure of the nasal cavity, which is important for nasal drug and vaccine delivery as well as the development of new devices. The surface area of the nasal cavity is about 160 cm2, or 96 m2 if the microvilli are included. The olfactory region, however, is only about 5 cm2 (0.3 m2 including the microvilli). There are 6 arterial branches that serve the nasal cavity, making this region a very attractive route for drug administration. The blood flow into the nasal region is slightly more than reabsorbed back into the nasal veins, but the excess will drain into the lymph vessels, making this region a very attractive route for vaccine delivery. Many of the side effects seen following intranasal administration are caused by some of the 6 nerves that serve the nasal cavity. The 5th cranial nerve (trigeminus nerve) is responsible for sensing pain and irritation following nasal administration but the 7th cranial nerve (facial nerve) will respond to such irritation by stimulating glands and cause facial expressions in the subject. The first cranial nerve (olfactory nerve), however, is the target when direct absorption into the brain is the goal, since this is the only site in our body where the central nervous system is directly expressed on the mucosal surface. The nasal mucosa contains 7 cell types and 4 types of glands. Four types of cells and 2 types of glands are located in the respiratory region but 6 cell types and 2 types of glands are found in the olfactory region.

Enhanced Delivery of Topically-Applied Formulations Following Skin Pre-Treatment with a Hand-Applied, Plastic Microneedle Array  8(5): Pp. 557 - 565 Dan Duan, Craig Moeckly, Jerry Gysbers, Chris Novak, Gayatri Prochnow, Kris Siebenaler, Leila Albers and Kris Hansen [View Abstract] [Open Access Plus]

The purpose of this work is to characterize microchannels created by polymeric microneedles, applied by hand, and to demonstrate enhanced delivery of topically applied formulations of lidocaine hydrochloride and methylprednisolone sodium succinate (MPSS). 3Ms Microstructured Transdermal System (MTS) arrays were applied to domestic swine to demonstrate reliability of penetration, depth of penetration and durability of the structures to repeat application and high force. Tissue levels of lidocaine and MPSS following topical application with and without microneedle pretreatment were determined by HPLC-MS analysis following digestion of biopsies. Almost all microneedles penetrate the stratum corneum upon hand force application. The depth of penetration varies from < 100μm to nearly 150μm depending on the application force and the firmness of the underlying tissue. The arrays show excellent durability to repeated in-vivo application, with less than 5% of the structures evidencing even minimal tip bending after 16 applications. Under extreme force against a rigid surface, the microneedles bend but do not break. A lidocaine hydrochloride formulation applied topically in-vivo showed ∼340% increase in local tissue levels when the MTS arrays were used to twice pre-treat the skin prior to applying the drug. Local delivery of a topically applied formulation of MPSS was over one order of magnitude higher when the application site was twice pre-treated with the MTS array. 3Ms MTS array (marketed as 3M™ Microchannel Skin System) provides repeatable and robust penetration of the stratum corneum and epidermis and enhances delivery of some formulations such as lidocaine hydrochloride.

Pharmacogenetics of Intestinal Absorption  5(3): Pp. 153 - 169 Tsutomu Nakamura, Motohiro Yamamori and Toshiyuki Sakaeda [View Abstract] [Open Access Plus]

The small intestine is the primary site of absorption for many drugs administered orally and so is the target tissue for pharmacotherapeutic strategies to control the oral absorption of drugs. Drug transporters, including the ATP-binding cassette (ABC) superfamily and the solute carrier (SLC) superfamily, have been considered to play a physiological role in regulating the absorption of xenobiotics, and variations in their expression level and function in the small intestine cause intra- and inter-individual variation in the oral absorption of drugs. Recent advances in molecular biology have suggested that genetic polymorphisms are associated with the expression level and function, and thereby inter-individual variation. In this review, the pharmacogenetics of these transporters is summarized, and their future significance in the clinical setting is discussed.