CVD-coated glass container

Abstract
Glass containers specifically for the storage of pharmaceutical or diagnostic solutions whose surface which comes into contact with the solutions is coated with a layer of oxides and/or nitrides of the elements Si, Ti, Ta, Al or mixtures thereof applied by means of a plasma CVD process.
Description




BACKGROUND OF THE INVENTION




Glass containers for the storage of pharmaceutical or diagnostic solutions are intended to come into direct contact with such solutions. Different types of glass containers are used, such as ampuls, small bottles, injection bottles for prefabricated syringes, cylindrical ampuls and container for the taking of blood and blood samples.




It is known with respect to all glass container—seven glass containers made from borosilicate glass which are classified in the highest quality class in accordance with the pharmacopeias (such as the Deutsches Arzneibuch [German Pharmaceutical Book] DAB 10)—that interactions can be documented between the solutions and the glass surface. However, the interactions in the case of glass containers made from lime-natron glass are even substantially greater.




The interaction is based primarily on the leaching of alkalic substances from the glass surface through the aqueous solution. While the solution is being stored, this leaching can lead to an undesired increase in the pH-value (such as in the case of water for injection purposes) of several pH units (see B. Borchert et al., J. of Parenteral Science & Technology, Vol. 43, No. 2 March/April 1989).




With some medications, it is also possible for a portion of the active ingredient to be inactivated by ions dissolved from the glass, which is particularly disruptive in low dosed medications.




SUMMARY OF THE INVENTION




The task of the invention therefore consists of finding a glass container for the storage of pharmaceutical or diagnostic solutions which behaves in a largely inert manner vis a vis these solutions, i.e., a glass container in which the quantity of ions leached from the glass through the solutions is minimized.




This problem is solved by the glass container, specifically for the storage of pharmaceutical or diagnostic solutions, characterized by the fact, that the surface which comes into contact with the solutions is coated with a layer of oxides and/or nitrides of the elements Si, Ti, Ta, Al or mixtures thereof applied by means of a plasma CVD process.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a sectional view of the container of the present invention.











DETAILED DESCRIPTION




The inner side of the glass container, i.e., the non-planar surface which is in contact with the solutions, is coated with a layer of oxides and/or nitrides of the elements Si, Ti, Ta, Al or mixtures thereof; said layer is created by means of a plasma CVD process (PCVD process). Specifically, the layer was manufactured by means of the plasma impulse CVD process (PICVD process).




In this process, a layer deposition from the gas phase (chemical vapor deposition=CVD) takes place, and the energy necessary for the cleavage of the precursor gases is brought into the system by means of an electric high frequency plasma. This process is well-known, in and of itself.




Surprisingly, it has been shown that a glass container with layers manufactured according to the PCVD or PICVD process possesses a very extraordinary resistance to leaching and thus behaves in a highly inert manner vis a vis the solutions stored therein.




Oxidic layers are particularly well suited, particularly those made from SiO


2


and TiO


2


—with SiO


2


being preferred. The thickness of the layers should be about 10 to 1000 mn. A thickness of between 20 and 1000 mn, particularly 20 to 500 mn, is preferred. It is also possible to deposit multiple layers of varying composition to form a layer package; in this connection, it is intended that the layer package has the aforementioned layer thickness.




The composition of the glass from which the container is made is not critical. In general, the usual clear and colored glass for pharmaceutical applications will be used. Preferred, however, is glass which already belongs to a low hydrolytic class, i.e., particularly so-called neutral glass (borosilicate glass) (DAB 10).




By way of example,

FIG. 1

shows a 10 ml injection glass bottle. The bottle consists of glass 1, whose inner side is provided with a SiO2 coat


2


. The thickness of the SiO


2


coat is not presented according to scale.




The outstanding properties of the container in accordance with the invention are illustrated by the following example:




A glass container made from borosilicate grass composed of 75% SiO


2


, 11% B


2


O


3


, 5% Al


2


O


3


, 7% Na


2


O, 2% CaO+BaO in the form of an injection bottle with 10 ml capacity, whose inner side has a 150 nm SiO


2


layer applied according to the PICVD process, is filled with 2 ml 0.4 mol HCI and then autoclaved for 1 hour at 121° C. Then the quantity of released sodium, calcium, aluminum, borosilicate and silicate cations is determined in μg/l. For comparison purposes, the test was repeated with an identical container which, however, was not provided with an inner coating. The results are summarized in the table.



















Comparison

















Borosilicate glass




Borosilicate glass







Cations




without




with 150 nm SiO


2









release




layer μg/l




layer (μg/l)



















Sodium (Na)




3.5




< detection limit of 0.01







Calcium (Ca)




1.1




< detection limit of 0.05







Boron (B)




3.5




< detection limit of 0.10







Aluminum (Al)




2.3




< detection limit of 0.05







Silicone (Si)




5.0




< detection limit of 0.30















Each of the indicated values are average values from 32 tested glass containers. In the glass containers according to the invention, the quantity of leached cations always remains below the detection limit. Particularly surprising is the fact that, in spite of an SiO


2


concentration of 100% in the layer, the leached quantity of Si ions is distinctly lower than with the comparison sample, despite the fact that, in the latter, the SiO2 concentration in the wall which is in contact with the solution is only 75 percent by weight.



Claims
  • 1. A glass container having a plasma impulse CVD deposited non-planar surface for the storage of pharmaceutical or diagnostic solutions, wherein the non-planar surface comes into contact with the solution and wherein said non-planar surface is coated with a layer consisting of SiO2 applied by means of a plasma impulse CVD process, wherein the layer is 20 to 1000 nm thick, and wherein the leachable quantity of Na-cation is less than 0.01 μg/l if a glass container having a 10 ml capacity is filled with 2 ml 0.4 molar HCl and then autoclaved for 1 hour at 121° C.
Priority Claims (1)
Number Date Country Kind
196 22 550 Jun 1996 DE
US Referenced Citations (9)
Number Name Date Kind
3182839 Hoag May 1965 A
3833406 White Sep 1974 A
4485146 Mizuhashi et al. Nov 1984 A
5017404 Paquet et al. May 1991 A
5030475 Askermann et al. Jul 1991 A
5236511 Etzkorn et al. Aug 1993 A
5431707 Recourt et al. Jul 1995 A
5531060 Fayet et al. Jul 1996 A
5578103 Araujo et al. Nov 1996 A
Foreign Referenced Citations (6)
Number Date Country
3801 111 A 1 Jul 1989 DE
43 27 513 A 1 Mar 1994 DE
195 02 103 Aug 1995 DE
0 446 596 Sep 1991 EP
0 665 304 Aug 1995 EP
2 697 014 Apr 1994 FR
Non-Patent Literature Citations (4)
Entry
German Office Action Mar. 12, 1997 (English Translation).
European Search Report Oct. 27, 1997 (German, Not Translated).
Patent Abstracts of Japan vol. 014, No. 446 (C-0763), Sep. 25, 1990 & JP 02 175630 A (Matsumoto Seiyaku Kogyo KK et al), Jul. 6, 1990, Zusammenfassung.
Borchert S.J. et al: “Accelerated Extractable Studies of Borosilicate Glass Containers” Journal of Parenteral Science and Technology, Bd. 43, Nr. 2, Mar. 1, 1989, Seiten 67-79, XP000197458.