Synthetic resins or natural rubbers -- part of the class 520 ser – Synthetic resins – Treating polymer containing material or treating a solid...
Patent
1994-06-15
1996-08-27
Seidleck, James J.
Synthetic resins or natural rubbers -- part of the class 520 ser
Synthetic resins
Treating polymer containing material or treating a solid...
528502R, 528503, C08F 628
Patent
active
055502113
DESCRIPTION:
BRIEF SUMMARY
BACKGROUND
Certain elastomedc articles, i.e., gaskets, valves and seats used in aerosol containers, are designed as part of the container for the efficacious delivery of pharmaceutically active compounds, i.e. medicaments. As a matter of cost and convenience, such articles are derived using elastomedc materials such as elastomeric rubber and the like, specifically formulated with ingredients that enable the article to meet numerous demanding toxicological, chemical, and physical requirements. For example, gaskets and valves made of rubber are typically formulated with about six to twelve ingredients, including monomers, polymers, organic solvents, organic plasticizers, antioxidants, antiozonants, curing agents, accelerators, pigments, tackifiers, reinforcing materials and inorganic fillers such as carbon black. Nearly all cured or finished articles will inherently contain small amounts of residual components derived from these ingredients. These inherent residual components or impurities are not neccessary for performance of the article but can potentially interact with the medicament or other excipients in the formulation, leaciing to reduced pharmaceutical dosing. Such impurities could also interact with the container, causing it to malfunction, such as by blocking a nozzle orifice.
A paper by A. Figazette et al., Analysis for Extractables From Nitrile Rubber Components in Metered Dose Inhalers, Pharmaceutical Analysis Department, SmithKline Beecham Pharmaceuticals, King of Prussia, Pa., was presented at the Symposium, "Regulatory Issues in Aerosol Drug Development", June 12-14, 1991 in Arlington Va., by the University of Kentucky College of Pharmacy. Figazette et al stated that contamination of pharmaceutical aerosols by substances leached from elastomedc valve assemblies in metered dose inhalers is a potentially serious problem. The authors present evidence that numerous extractables could be detected in valves from various suppliers, demonstrating a need for cleaner valve rubbers with fewer leachable extractants. One class of impurities is known as the polynuclear aromatic hydrocarbons (PNAs or PAHs). Another class of impurities is known as non-PAHs, including phthalates derived from plasticizers employed during processing. Presently, conventional methods for removing PAHs and non-PAHs from rubber articles involves liquid-solid extraction and refluxing using either conventional solvents or fluorocarbon type solvents (eg. freons). However, these conventional method are deemed unsatisfactory for preparing pudfied elastomedc articles using the newer, environmentally safer fluorohydrocarbons propellants such as HFC-134A, HFC-226a and HFC-227, for the following reasons. First, these conventional methods have the disadvantage of incurring high expenses for special handling and safety precautions, and for special buildings, rooms and equipment due to the explosive nature of the newer propellants, necessitating the need to use explosion-proof equipment. Second, these conventional methods have the further disadvantage of supedicially cleaning primarily the outer surface of the article, leaving impurities in the intedor of the article.
Clearly, it would be desirable to provide an improved method for cleaning elastomedc articles by removal of the impurities contained therein, particularly for highly demanding pharmaceutical and medicinal uses. It would also be desirable to provide a method for preparing such articles which would meet govenmental regulatory requirements (ie. Food and Drug Administration). Furthermore, it would also be desirable to provide a method for cleaning elastomeric articles that is occupationally and environmentally safer, simpler, more rapid and less expensive than known conventional methods.
SUMMARY OF THE INVENTION
The present invention is directed towards a method for cleaning elastomeric articles comprising contacting the elastomeric article with at least one supercritical fluid under conditions and for a time sufficient to remove the phthalates and/or polynuclear aromatic hydroca
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DeCrosta Michelle A.
Jagnandan Indradat
Jones Richard
Maitner John T.
Majka Joseph T.
Schering Corporation
Seidleck James J.
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