Hermetic filter feedthrough including MLCC-type capacitors for use with an active implantable medical device

What is claimed is: 1. A filter feedthrough for an active implantable medical device, the filter feedthrough comprising: a) a hermetic feedthrough, comprising: i) a conductive ferrule comprising a ferrule sidewall having a ferrule inner surface defining a ferrule opening, wherein the ferrule sidewall extends from a ferrule first end surface spaced from a ferrule second end surface; ii) an insulator disposed at least partially within the ferrule inner surface, wherein the insulator comprises an insulator outer surface extending to an insulator first end surface adjacent to the ferrule first end surface and an opposed insulator second end surface adjacent to the ferrule second end surface; iii) at least one via hole extending through the insulator from the insulator first end surface to the insulator second end surface; and iv) a conductive fill disposed within the at least one via hole in a hermetically sealed relationship therewith to thereby provide an electrically conductive path extending from a conductive fill first end at or adjacent to the insulator first end surface to a conductive fill second end at or adjacent to the insulator second end surface; and v) a first metallization contacting at least a portion of the outer surface of the insulator; and b) at least one capacitor, comprising: i) a capacitor dielectric body; ii) at least one active electrode plate and at least one ground electrode plate supported by the capacitor dielectric body in spaced relation with each other; iii) a second metallization contacting and electrically coupled to the at least one active electrode plate at a first outer surface of the capacitor dielectric body; and iv) a third metallization contacting and electrically coupled to the at least one ground electrode plate at a second outer surface of the capacitor dielectric body; c) a first electrical connection physically contacting and electrically coupling the second metallization to the conductive fill in the at least one via hole to thereby electrically connect the at least one active electrode plate of the capacitor to the conductive fill; d) a second electrical connection physically contacting and electrically coupling the third metallization contacting the at least one ground electrode plate of the capacitor to the first metallization contacting the outer surface of the insulator; and e) an electrically conductive material that provides a hermetic seal electrically coupling the first metallization contacting the outer surface of the insulator to the ferrule to thereby electrically couple the capacitor to the ferrule. 2. The filter feedthrough of claim 1 , wherein the at least one capacitor is received in a castellation in the insulator first end surface. 3. The filter feedthrough of claim 1 , wherein the at least one capacitor is a multilayer ceramic capacitor (MLCC). 4. The filter feedthrough of claim 1 , wherein the electrically conductive material electrically coupling the first metallization contacting the outer surface of the insulator to the ferrule comprises an adhesion layer and a gold braze wetting layer. 5. The filter feedthrough of claim 1 , wherein the first electrical connection physically contacts and electrically couples to the conductive fill disposed in the at least one via hole at a position intermediate the conductive fill first and second ends. 6. The filter feedthrough of claim 1 , wherein the at least one via hole is substantially centered in the insulator and wherein there are at least two capacitors, each capacitor being disposed between the at least one via hole and the outer surface of the insulator. 7. The filter feedthrough of claim 6 , wherein the at least two capacitors are diametrically opposite each other. 8. The filter feedthrough of claim 1 , wherein the insulator has a dielectric constant that is less than 10. 9. The filter feedthrough of claim 1 , wherein the insulator comprises at least 96% alumina. 10. The filter feedthrough of claim 1 , wherein the conductive fill comprises platinum. 11. The filter feedthrough of claim 1 , wherein the hermetically sealed relationship between the conductive fill and the insulator comprises a tortuous and mutually conformal knitline. 12. The filter feedthrough of claim 11 , wherein the knitline comprises a glass that is at least about 60% silica. 13. The filter feedthrough of claim 1 , wherein at least one of the first and second electrical connections comprises a circuit trace. 14. A filter feedthrough for an active implantable medical device, the filter feedthrough comprising: a) a hermetic feedthrough, comprising: i) a conductive ferrule comprising a ferrule sidewall having a ferrule inner surface defining a ferrule opening, wherein the ferrule sidewall extends from a ferrule first end surface spaced from a ferrule second end surface; ii) an insulator disposed at least partially within the ferrule inner surface, wherein the insulator comprises an insulator outer surface extending to an insulator first end surface adjacent to the ferrule first end surface and an opposed insulator second end surface adjacent to the ferrule second end surface; iii) at least one via hole extending through the insulator from the insulator first end surface to the insulator second end surface; lv) a conductive fill disposed within the at least one via hole in a hermetically sealed relationship therewith to thereby provide an electrically conductive path extending from a conductive fill first end at or adjacent to the insulator first end surface to a conductive fill second end at or adjacent to the insulator second end surface; and v) a first metallization contacting at least a portion of the outer surface of the insulator; and b) at least two capacitors, each capacitor comprising: i) a capacitor dielectric body; ii) at least one active electrode plate and at least one ground electrode plate supported by the capacitor dielectric body in spaced relation with each other; iii) a second metallization contacting and electrically coupled to the at least one active electrode plate at a first outer surface of the capacitor dielectric body; and iv) a third metallization contacting and electrically coupled to the at least one ground electrode plate at a second outer surface of the capacitor dielectric body, v) wherein each of the two capacitors is supported by the insulator at or adjacent to the insulator first end surface and is disposed between the at least one via hole and the outer surface of the insulator; c) a first electrical connection physically contacting and electrically coupling the second metallization to the conductive fill in the at least one via hole to thereby electrically connect the at least one active electrode plate of each of the at least two capacitors to the conductive fill; d) a second electrical connection physically contacting and electrically coupling the third metallization contacting the at least one ground electrode plate of each of the at least two capacitors to the first metallization contacting the outer surface of the insulator; and e) an electrically conductive material that provides a hermetic seal electrically coupling the first metallization contacting the outer surface of the insulator to the ferrule to thereby electrically couple the capacitor to the ferrule. 15. The filter feedthrough of claim 14 , wherein the at least one via hole is substantially centered in the insulator and the at least two capacitors disposed between the at least one via hole and the outer surface of the insulator are spaced from each other. 16. The filter feedthrough of cla