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Peptides pulmonary drug delivery

A composition based on diketopiperazine derivatives (3,6-bis (N-fumaryl-N-(n-butyl) amino-2, 5-diketopiperazine) has been investigated as a pulmonary drug delivery system, termed Technospheres (Pharmaceutical Discovery Corp., Elmsford, NY) (Pohl et al. 2000 Steiner et al. 2002). The diketopiperazine derivatives self-assemble into microparticles at low pH with a mean diameter of approximately 2 pm. During self-assembly, diketopiperazine derivatives microencapsulate peptides present in the solution. Insulin incorporated in diketopiperazine derivatives (TI) was administered to five healthy humans by the use of a capsule-based inhaler with a passive powder deagglomeration mechanism. Relative and absolute bioavailability of TI in the first 3 hours (0-180 min) were 26 12% and 15 5%, and for 6 hours (0-360 min) 16 8% and 16 6%, respectively (Steiner et al. 2002). The time to peak action for glucose infusion rates was shorter with both IV (14 6 min) injection and inhalation (39 36 min), as compared to SC administration (163 25 min). This rapid absorption of insulin would be beneficial for diabetic patients who need to rapidly affect their glucose levels. [Pg.272]

One of the main drivers for the development of new pulmonary drug delivery systems has been the potential for noninvasive systemic delivery of protein and peptide compounds. The systemic delivery of macromolecules via the airways would overcome the inconvenience and cost associated with current methods of administration (injection), and appears likely given the large surface area of the airways and the thin pulmonary epithelium. Most research has concentrated on pulmonary delivery of insulin for the treatment of diabetes. Recently, one insulin product has completed phase three studies and is now undergoing review by European regulatory agencies for marketing approval. [Pg.243]

Due to the lack of activity after oral administration for most peptides and proteins, administration by injection or infusion - that is, by intravenous (IV), subcutaneous (SC), or intramuscular (IM) administration - is frequently the preferred route of delivery for these drug products. In addition, other non-oral administration pathways have been utilized, including nasal, buccal, rectal, vaginal, transder-mal, ocular, or pulmonary drug delivery. Some of these delivery pathways will be discussed in the following sections in the order of the increasing biopharmaceutic challenges to obtain adequate systemic exposure. [Pg.18]

Shoyele, S. A., and Slowey, A. (2006), Prospects of formulating proteins/peptides as aerosols for pulmonary drug delivery, Int. J. Pharm., 314,1-8. [Pg.715]

The lack of activity after oral administration for most peptides and proteins resulted in the past besides parenteral application into the utilization of nonoral administration pathways, for example, nasal, buccal, rectal, vaginal, percutaneous, ocular, or pulmonary drug delivery [27]. Drug delivery via these administration routes, however, is also frequently accompanied by presystemic degradation processes. Bioavailability of numerous peptides and proteins is, for example, markedly reduced after subcutaneous or intramuscular administration compared to their intravenous administration. The pharma-cokinetically derived apparent absorption rate constant is thus the combination of absorption into the systemic circulation and presystemic degradation at the absorption... [Pg.151]

J. S. Patton and R. M. Platz, Routes of drug delivery case studies (2) pulmonary delivery of peptides and proteins for systemic action, Adv. Drug Deliv. Rev, 8, 179 (1992). [Pg.721]

While there are no currently approved therapeutic protein or peptide products for delivery via the pulmonary route into the systemic circulation, the data on the efficiency, reproducibility, and safety of molecules such as insulin are particularly encouraging. From a molecular perspective, there is a general trend in the reduction of the rate and extent of absorption with increasing molecular weight, but predictive theories are lacking due to our poor understanding of the complexity and multitude of channels of entry of drugs from the respiratory tract into the systemic circulation. [Pg.2738]

Mackay, M. Phillips, J. Steward, A. Hastewell, J. Pulmonary absorption of therapeutic peptides and proteins. In Respiratory Drug Delivery IV, Byron, P.R., Dalby, R.N., Farr, S.J., Eds. Interpharm Press, Inc. Buffalo Grove, IL, 1994 31-37. [Pg.2738]

Although aerosols of various forms for treatment of respiratory disorders have been in use since the middle of the twentieth century, the interest in the use of pulmonary route for systemic drug delivery is recent. Interest in this approach has been further stimulated by the demonstration of potential utility of lung as a portal for entry of peptides and the feasibility of gene therapy for cystic fibrosis. It is important to understand the mechanism of macromolecule absorption by the lungs for an effective use of this route. [Pg.12]

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See also in sourсe #XX -- [ Pg.297 , Pg.298 ]



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