Parenteral delivery routes insulin

Parenteral administration is not perceived as a problem in the context of drugs which are administered infrequently, or as a once-off dose to a patient. However, in the case of products administered frequently/daily (e.g. insulin to diabetics), non-parenteral delivery routes would be preferred. Such routes would be more convenient, less invasive, less painful and generally would achieve better patient compliance. Alternative potential delivery routes include oral, nasal, transmucosal, transdermal or pulmonary routes. Although such routes have proven possible in the context of many drugs, routine administration of biopharmaceuticals by such means has proven to be technically challenging. Obstacles encountered include their high molecular mass, their susceptibility to enzymatic inactivation and their potential to aggregate. 

The objectives of the present chapter are to provide a brief overview of the complexity and diversity of insulin formulation, to give a historical review of the efforts to improve parenteral delivery of insulin, and, with an emphasis on the last 25 years efforts, to survey the numerous studies performed in a search for acceptable insulin delivery through various noninvasive routes. 

Virtually all therapeutic proteins must enter the blood in order to promote a therapeutic effect. Such products must usually be administered parenterally. However, research continues on the development of non-parenteral routes which may prove more convenient, less costly and obtain improved patient compliance. Alternative potential delivery routes include transdermal, nasal, oral and bucal approaches, although most progress to date has been recorded with pulmonary-based delivery systems (Chapter 4). An inhaled insulin product ( Exubera , Chapters 4 and 11) was approved in 2006 for the treatment of type I and II diabetes. 

Pulmonary delivery currently represents the most promising alternative to parenteral delivery systems for biopharmaceuticals. Delivery via the pulmonary route moved from concept to reality in 2006 with the approval of Exubera, an inhalable insulin product (Chapter 11). Although the lung is not particularly permeable to solutes of low molecular mass (e.g. sucrose or urea), macromolecules can be absorbed into the blood via the lungs surprisingly well. In fact, pulmonary... 

Particle design applied to pharmaceutical processing has the potential to improve the efficacy of current medications as well as to open the way to the use of alternative delivery routes. An example is the administration of drugs, such as insulin, that are subject to extensive gastrointestinal breakdown and thus cannot be administered orally. The alternative is parenteral administration, which has major side effects, especially in long-term or chronic conditions. 

Protein-based drugs have been formulated mainly as stable liquids or in cases where liquid stability is limiting as lyophilized dosage forms to be reconstituted with a suitable diluent prior to injection. This is because their delivery has been limited primarily to the parenteral routes of intravenous (IV), subcutaneous (SC), or intramuscular (IM) administration. There are a few drugs that have been developed for pulmonary delivery, such as rhDNase (Pulmozyme ) and an inhalable formulation of insulin (e.g., Exubra ). However, even such drugs have been formulated as either liquid or lyophilized or spray-dried powders. This chapter will focus only on excipients that are applicable to liquid and lyophilized protein formulations. 

Polylactic acid has been studied extensively for controlled release applications ranging from the oral delivery of simple drugs such as indomethacin9 to the parental administration of complex proteins such as insulin.10 Polylactic acid of different molecular weights has been studied as matrix material for parenteral administration. Seki et al.11 used polylactic acid 6000 and Smith and Hunneyball8 used polylactic acid 100,000 for the controlled delivery of drugs by the parenteral route. Several polylactic acid systems have been studied for the controlled... 

Although routine oral delivery of proteins has not been realized, some protein formulations have been developed for pulmonary delivery. Pulmonary delivery can result in either parenteral or local administration of the drug and, like oral delivery, is considered non-invasive. As with other routes of delivery, the size of the protein may limit its ability to be delivered systemi-cally via the pulmonary route of administration. Pulmozyme , a DNase-based formulation approved for the treatment of cystic fibrosis (CF), is delivered to the lungs by a nebulizer to clear blockage of the airways in the CF patient.Formulations for insulin to be administered by inhalation for systemic delivery of... 

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