Subject(s)
Delayed-Action Preparations , Drug Delivery Systems , Growth Hormone/administration & dosage , Amino Acid Sequence , Animals , Capsules/administration & dosage , Cattle , Dairying/methods , Drug Compounding , Drug Delivery Systems/instrumentation , Emulsions/administration & dosage , Human Growth Hormone/administration & dosage , Liposomes/administration & dosage , Molecular Sequence Data , Osmosis , RatsABSTRACT
The goal of this program was the development of biocompatible sustained-release systems that would release naltrexone at a rate of 20 to 25 microgram/hr for 30 days, and that would biodegrade within 90 days. The focus was on the use of macrocapsules prepared from synthetic polypeptides, specifically copolymers of glutamic acid and ethyl glutamate (i.e., Glu/EGlu copolymers). Tubular capsules prepared from 18/82 Glu/EGlu were the most promising systems developed. Capsules 1 cm in length, 0.19 cm in outside diameter, and 0.005 cm in wall thickness released naltrexone in mice at rates in the range of 20 to 40 microgram/hr for 18 days. The rates then decreased during the next 12 days as the capsules became exhausted of drug. These capsules were biocompatible and they appeared to biodegrade within 90 days. In general, the Glu/EGlu copolymers exhibit permeation and degradation rates that increase as the glutamic acid content is increased. Radiotracing studies revealed that the ultimate degradation product was carbon dioxide, which appeared in the expired air. This result is consistent with a polypeptide degradation process that involves hydrolysis of the ethyl esters followed by hydrolysis of the peptide bonds to produce glutamic acid, which enters the metabolic pool.
Subject(s)
Drug Implants , Narcotic Antagonists/administration & dosage , Peptides/administration & dosage , Polymers/chemical synthesis , Animals , Autoradiography , Biodegradation, Environmental , Capsules , Membranes, Artificial , Mice , Naltrexone/administration & dosage , Peptides/chemical synthesis , PermeabilityABSTRACT
Synthetic polypeptides consisting of copolymers of glutamic acid and leucine have been shown to be useful materials for the fabrication of practical, biodegradable delivery vehicles for narcotic antagonists. Model delivery vehicles in film form were prepared from copolymers containing 10 mole percent to 40 mole percent glutamic acid, and loaded with 10% to 40% naltrexone by weight. The naltrexone was found to be released by diffusion, exhibiting diffusion coefficients that varied as a function of the glutamic acid content and the initial naltrexone loading. A wide range in diffusion coefficients were achieved (0.31 x 10-7 cm2/hr to 120 x 10-7 cm2/hr), leading to release rates within practical ranges of interest for meeting the program goals. We have demonstrated that the polypeptides can be fabricated into dosage forms that are amenable to administration by trochar. For example, rods 0.4 mm to 0.8 mm in diameter containing as much as 40% naltrexone by weight were extruded using a simple compression mold and die arrangement. An in vitro evaluation of the rods showed that antagonist is released by diffusion at a continuously decreasing rate, a behavior similar to that observed with the film devices that were, nonetheless, capable of blocking an AD80 challenge of morphene sulfate in mice for more than 30 days. One of the most promising delivery vehicles that we have developed to date consists of a polypeptide tube filled with a naltrexone/polypeptide core. Preliminary experiments have shown that these devices may be capable of administering high, constant rates of release for prolonged periods of time. Additional work, however, is required to develop techniques for the preparation of reproducible delivery vehicles.
Subject(s)
Narcotic Antagonists/administration & dosage , Peptides , Animals , Biodegradation, Environmental , Drug Implants , Mice , Morphine/antagonists & inhibitors , Morphine/pharmacology , Naltrexone/administration & dosage , Naltrexone/pharmacology , Reaction Time/drug effects , Time FactorsABSTRACT
Synthetic polypeptides consisting of copolymers of glutamic acid and leucine have been shown to be useful materials for the fabrication of practical, biodegradable delivery vehicles for narcotic antagonists. Model delivery vehicles in film form were prepared from copolymers containing 10 mole percent to 40 mole percent glutamic acid, and loaded with 10% to 40% naltrexone by weight. The naltrexone was found to be released by diffusion, exhibiting diffusion coefficients that varied as a function of the glutamic acid content and the initial naltrexone loading. A wide range in diffusion coefficients were achieved (0.31 x 10(-7) cm2/hr to 120 x 10(-7) cm2/hr), leading to release rates within practical ranges of interest for meeting the program goals. We have demonstrated that the polypeptides can be fabricated into dosage forms that are amenable to administration by trochar. For example, rods 0.4 mm to 0.8 mm in diameter containing as much as 40% naltrexone by weight were extruded using a simple compression mold and die arrangement. An in vitro evaluation of the rods showed that antagonist is released by diffusion at a continuously decreasing rate, a behavior similar to that observed with the film devices that were, nonetheless, capable of blocking an AD80 challenge of morphine sulfate in mice for more than 30 days. One of the most promising delivery vehicles that we have developed to date consists of a polypeptide tube filled with a naltrexone/polypeptide core. Preliminary experiments have shown that these devices may be capable of administering high, constant rates of release for prolonged periods of time. Additional work, however, is required to develop techniques for the preparation of reproducible delivery vehicles.
