Multilayer balloon for a catheter

The invention claimed is: 1. A multilayer balloon for a catheter comprising: a first layer made of a first polymer material having a first Shore durometer hardness; a second layer made of a second polymer material having a second Shore durometer hardness greater than the first Shore durometer hardness, wherein the second layer is an inner layer relative to the first layer; a third layer made of a third polymer material having a third Shore durometer hardness less the first Shore durometer hardness, wherein the third layer is an inner layer relative to the second layer. 2. The multilayer balloon of claim 1 , wherein the multilayer balloon, as blown, has a nominal working diameter. 3. The multilayer balloon of claim 2 , wherein the balloon has a noncompliant limited radial expansion beyond the nominal working diameter at pressures above a nominal pressure. 4. The multilayer balloon of claim 1 , wherein the multilayer balloon, as blown, has a compliance less than about 0.035 mm/atm between a nominal pressure and a rated burst pressure. 5. The multilayer balloon of claim 2 , wherein the balloon has a semicomplaint radial expansion beyond the nominal working diameter at pressures above a nominal pressure. 6. The multilayer balloon of claim 1 , wherein the multilayer balloon, as blown, has a balloon wall thickness less than 0.003 inch. 7. The multilayer balloon of claim 1 , wherein the multilayer balloon, as blown, has a balloon wall thickness less than 0.002 inch. 8. The multilayer balloon of claim 1 , wherein the multilayer balloon, as blown, has a balloon wall thickness less than 0.001 inch. 9. The multilayer balloon of claim 1 , wherein the multilayer balloon, as blown, has a rated burst pressure is about 15 to about 30 atm. 10. The multilayer balloon of claim 2 , wherein at least the third layer is substantially at a third layer maximum blow-up-ratio when the multilayer balloon is substantially at the nominal working diameter. 11. The multilayer balloon of claim 2 , wherein at least the third layer is at a blow up ratio of at least about 90% of a third layer maximum blow-up-ratio when the multilayer balloon is substantially at the nominal working diameter. 12. The multilayer balloon of claim 2 , wherein at least the third layer is at a blow up ratio of at least about 80% of a third layer maximum blow-up-ratio when the multilayer balloon is substantially at the nominal working diameter. 13. The multilayer balloon of claim 1 , wherein the third layer has a blow-up-ratio between about 7.0 and about 8.0. 14. The multilayer balloon of claim 1 , wherein the third layer has a blow-up-ratio between about 7.2 and about 7.8. 15. The multilayer balloon of claim 2 , wherein the second layer is at a blow up ratio of at least 80% of a second layer maximum blow-up-ratio when the multilayer balloon is substantially at the nominal working diameter. 16. The multilayer balloon of claim 2 , wherein the second layer is at a blow up ratio of at least 70% of a second layer maximum blow-up-ratio when the multilayer balloon is substantially at the nominal working diameter. 17. The multilayer balloon of claim 2 , wherein the first layer is at a blow up ratio at least 60% of a first layer maximum blow-up-ratio when the multilayer balloon is substantially at the nominal working diameter. 18. The multilayer balloon of claim 1 , further comprising an expandable stent mounted on an outer surface of the multilayer balloon. 19. The multilayer balloon of claim 1 , wherein the first Shore durometer hardness is about 70D. 20. The multilayer balloon of claim 1 , wherein the second Shore durometer hardness is about 72D or greater. 21. The multilayer balloon of claim 1 , wherein the third Shore durometer hardness is less than about 70D. 22. The multilayer balloon of claim 2 , wherein the first Shore durometer hardness is about 70D, the second Shore durometer hardness is about 72D, and the third Shore durometer hardness is about 63D. 23. The multilayer balloon of claim 22 , wherein the first polymer material is a polyether block amide, the second polymer material is a polyether block amide, and the third polymer material is a polyether block amide. 24. The multilayer balloon of claim 23 , wherein the balloon has a semicomplaint radial expansion beyond the nominal working diameter at pressures above a nominal pressure. 25. The multilayer balloon of claim 2 , wherein the first Shore durometer hardness is about 70D, the second Shore durometer hardness is about 74D or greater, and the third Shore durometer hardness is about 63D. 26. The multilayer balloon of claim 25 , wherein the first polymer material is a polyether block amide, the second polymer material is a nylon, and the third polymer material is a polyether block amide. 27. The multilayer balloon of claim 26 , wherein the balloon has a noncompliant limited radial expansion beyond the nominal working diameter at pressures above a nominal pressure. 28. The multilayer balloon of claim 1 , wherein the first Shore durometer hardness is between about 70D and about 72D, the second Shore durometer hardness is about 74D or greater, and the third Shore durometer hardness is between about 63D and about 70D. 29. The multilayer balloon of claim 1 , wherein the third layer defines an inner surface of the balloon. 30. The multilayer balloon of claim 29 , wherein the first layer defines an outer surface of the balloon. 31. The multilayer balloon of claim 1 , wherein the first layer, the second layer, and the third layer are coextruded. 32. A method of making a multilayer balloon for a catheter comprising: providing a tube having at least a first layer, a second layer, and a third layer, wherein the first layer is made of a first polymer material having a first Shore durometer hardness; the second layer is made of a second polymer material having a second Shore durometer hardness greater than the first Shore durometer hardness, wherein the second layer is an inner layer relative to the first layer; and the third layer is made of a third polymer material having a third Shore durometer hardness less the first Shore hardness, wherein the third layer is an inner layer relative to the second layer; and radially expanding the tube in a mold to form a balloon having a nominal working diameter. 33. The method of claim 32 , wherein the tube is formed by coextruding the first layer, the second layer, and the third layer. 34. The method of claim 32 , wherein the tube is radially expanded in the mold via a single blow process. 35. The method of claim 32 , wherein the tube is radially expanded in the mold via a double blow process. 36. A balloon catheter, comprising: an elongate catheter shaft having a proximal section, a distal section, and an inflation lumen defined therein; and a multilayer balloon on the distal section of the shaft comprising: a first layer made of a first polymer material having a first Shore durometer hardness; a second layer made of a second polymer material having a second Shore durometer hardness greater than the first Shore durometer hardness, wherein the second layer is an inner layer relative to the first layer; a third layer made of a third polymer material having a third Sh