Glass-metal feedthrough

What is claimed is: 1. A glass-metal feedthrough, comprising: an external conductor comprising steel, having a coefficient of expansion α external , and having an opening formed therein; an internal conductor disposed in the opening, the internal conductor comprising steel and having a coefficient of expansion α internal , the external conductor and the internal conductor being configured to not release nickel when in contact with a human or animal body or biological cells of a cell culture; and a glass material surrounding the internal conductor within the opening and having a coefficient of expansion α glass , the coefficient of expansion α external of the external conductor and the coefficient of expansion α internal of the internal conductor both being greater than the coefficient of expansion α glass of the glass material, wherein the coefficient of expansion of the internal conductor α internal is 1.7 times to 4 times greater than the coefficient of expansion of the glass material α glass , wherein the coefficient of expansion of the internal conductor α internal and the coefficient of expansion of the external conductor α external are such that a joint pressure of at least 30 MPa is generated on a portion of the internal conductor in contact with the glass material in a temperature range of 20° C. to a glass transformation temperature of the glass material, wherein a difference between the coefficient of expansion of the external conductor α external and the coefficient of expansion of the glass material α glass is at least 2 ppm/K in the temperature range of 20° C. to the glass transformation temperature of the glass material, wherein the external conductor and the internal conductor both comprise AISI 316L steel. 2. The glass-metal feedthrough of claim 1 , wherein the coefficient of expansion of the external conductor α external is 1.1 times to 4 times greater than the coefficient of expansion of the glass material α glass . 3. The glass-metal feedthrough of claim 1 , wherein the glass material seals the internal conductor in the opening of the external conductor. 4. A glass-metal feedthrough, comprising: an external conductor having a coefficient of expansion α external , and having an opening formed therein; an internal conductor disposed in the opening, the internal conductor comprising AISI 316L steel and having a coefficient of expansion α internal , the external conductor and the internal conductor being configured to not release nickel when in contact with a human or animal body or biological cells of a cell culture; and a glass material surrounding the internal conductor within the opening and having a coefficient of expansion α glass , the coefficient of expansion α external of the external conductor and the coefficient of expansion α internal of the internal conductor both being greater than the coefficient of expansion α glass of the glass material, wherein the coefficient of expansion of the internal conductor α internal is 1.7 times to 4 times greater than the coefficient of expansion of the glass material α glass , wherein the coefficient of expansion of the internal conductor α internal and the coefficient of expansion of the external conductor α external are such that a joint pressure of at least 30 MPa is generated on a portion of the internal conductor in contact with the glass material in a temperature range of 20° C. to a glass transformation temperature of the glass material, wherein a difference between the coefficient of expansion of the external conductor α external and the coefficient of expansion of the glass material α glass is at least 2 ppm/K in the temperature range of 20° C. to the glass transformation temperature of the glass material, wherein the external conductor and the internal conductor both consist of AISI 316L steel. 5. The glass-metal feedthrough of claim 4 , wherein the coefficient of expansion of the external conductor α external is 1.1 times to 4 times greater than the coefficient of expansion of the glass material α glass . 6. The glass-metal feedthrough of claim 4 , wherein the glass material seals the internal conductor in the opening of the external conductor. 7. An element for insertion into or attachment to a human or animal body or biological cells of a cell culture, the element comprising: a glass-metal feedthrough comprising: an external conductor comprising steel, having a coefficient of expansion α external , and having an opening formed therein; an internal conductor disposed in the opening, the internal conductor comprising AISI 316L steel and having a coefficient of expansion α internal , the external conductor and the internal conductor being configured to not release nickel when in contact with the human or animal body or the biological cells of the cell culture; and a glass material surrounding the internal conductor within the opening and having a coefficient of expansion α glass , the coefficient of expansion α external of the external conductor and the coefficient of expansion α internal of the internal conductor both being greater than the coefficient of expansion α glass of the glass material, wherein the coefficient of expansion of the internal conductor α internal is 1.7 times to 4 times greater than the coefficient of expansion of the glass material α glass , wherein the coefficient of expansion of the internal conductor α internal and the coefficient of expansion of the external conductor α external are such that a joint pressure of at least 30 MPa is generated on a portion of the internal conductor in contact with the glass material in a temperature range of 20° C. to a glass transformation temperature of the glass material, wherein a difference between the coefficient of expansion of the external conductor α external and the coefficient of expansion of the glass material α glass is at least 2 ppm/K in the temperature range of 20° C. to the glass transformation temperature of the glass material, wherein the external conductor and the internal conductor both comprise AISI 316L steel. 8. The element of claim 7 , wherein at least one of the external conductor or the internal conductor consists of AISI 316L steel. 9. The element of claim 7 , wherein the coefficient of expansion of the external conductor α external is 1.1 times to 4 times greater than the coefficient of expansion of the glass material α glass .