Variable stiffness devices that use the principles of granular jamming and methods of use

What is claimed is: 1. A system comprising: a first cell having an air impermeable outer bladder, the outer bladder defining a first internal pocket containing a plurality of first granular particulates, wherein the first cell is configured to maintain a first negative internal pressure relative to an area external to the outer bladder; a first valve in fluid communication with the first cell and the area external to the outer bladder, wherein the first valve extends from the first cell and through the outer bladder, and wherein the first valve is configured to provide fluid flow into and from the first cell to adjust the first negative internal pressure; a second cell adjacent to and at least partially coplanar with the first cell and having an air impermeable outer bladder, the outer bladder defining a second internal pocket containing a plurality of second granular particulates, wherein the second cell is configured to maintain a second negative internal pressure relative to an area external to the outer bladder; and a second valve in fluid communication with the second cell and the area external to the outer bladder, wherein the second valve extends from the second cell and through the outer bladder, and wherein the second valve is configured to provide fluid flow into and from the second cell to adjust the second negative internal pressure; wherein the plurality of first granular particulates are a different material than the plurality of second granular particulates. 2. The system of claim 1 , wherein the first internal pocket comprises a plurality of third granular particulates, wherein the plurality of first granular particulates are a different material than the plurality of second granular particulates. 3. The system of claim 1 , wherein the plurality of first granular particulates comprise a different geometry than the plurality of second granular particulates. 4. The system of claim 1 , wherein the first negative internal pressure is a different pressure than the second negative internal pressure. 5. The system of claim 1 , wherein the system forms part of an orthosis. 6. The system of claim 1 , further comprising: a fluid pump coupleable to the first valve; and a controller configured to operate the fluid pump to adjust the first negative internal pressure to alter a stiffness of the first cell. 7. The system of claim 1 , further comprising: a fluid pump coupleable to the first and second valves; and a controller configured to operate the fluid pump to adjust the first negative internal pressure to alter a stiffness of the first cell, the controller further configured to operate the fluid pump to adjust the second negative internal pressure to alter a stiffness of the second cell. 8. A method comprising: providing a user-orthosis interface, the interface comprising: a first cell having an air impermeable outer bladder; the first cell containing a plurality of first granular particulates; a first valve in fluid communication with the first cell and an area external to the outer bladder, the first valve extending from the first cell and through the outer bladder, and wherein the first valve is configured to provide fluid flow into and from the first cell; a second cell adjacent to and at least partially coplanar with the first cell and having an air impermeable outer bladder, the second cell containing a plurality of second granular particulates of a different material than the plurality of first granular particulates; and a second valve in fluid communication with the second cell and an area external to the outer bladder, the second valve extending from the second cell and through the outer bladder, and wherein the second valve is configured to provide fluid flow into and from the second cell; providing a pressure controller configured to attach to the first valve and the second valve and provide fluid into and remove fluid from the first cell and the second cell to adjust a first internal pressure of the first cell and a second internal pressure of the second cell; removing fluid, via the pressure controller, from the first cell to decrease the first internal pressure; removing fluid, via the pressure controller, from the second cell to decrease the second internal pressure; causing the plurality of first granular particulates to compact with each other to increase a stiffness of the first cell; and causing the plurality of second granular particulates to compact with each other to increase a stiffness of the second cell such that the second cell has different material properties than the first cell based at least in part on the plurality of second granular particulates being a different material than the plurality of first granular particulates. 9. The method of claim 8 , wherein the stiffness of the first cell is greater than the stiffness of the second cell. 10. The method of claim 8 , wherein the plurality of first granular particulates comprise a different geometry than the plurality of second granular particulates. 11. The method of claim 8 , wherein the interface is part of an orthotic insole, and wherein the orthotic insole is disposed within a shoe. 12. The method of claim 8 , wherein the interface is part of an orthotic insole, wherein the orthotic insole is disposed within a shoe, wherein the shoe comprises a first end and a second end, wherein the first cell is proximate the first end of the shoe, and wherein the second cell is proximate the second end of the shoe. 13. A method comprising: providing an orthotic insole, the orthotic insole comprising: a first cell having an air impermeable outer bladder, the outer bladder defining a first internal pocket containing a plurality of first granular particulates; and a first valve providing fluid communication between the first internal pocket and an area external to the first cell; a second cell adjacent to and at least partially coplanar with the first cell and having an air impermeable outer bladder, the outer bladder defining a second internal pocket containing a plurality of second granular particulates; and a second valve providing fluid communication between the first internal pocket and an area external to the second cell; providing a pressure controller coupleable to the first valve and the second valve; removing fluid, via the pressure controller, from the first cell to decrease a first internal pressure in the first cell relative to the area external to the first cell, wherein decreasing the first internal pressure causes the plurality of first granular particulates to compact and increases a stiffness of the first cell; and removing fluid, via the pressure controller, from the second cell to decrease a second internal pressure in the second cell relative to the area external to the second cell, wherein decreasing the second internal pressure causes the plurality of second granular particulates to compact and increases a stiffness of the second cell, wherein the plurality of second granular particulates comprise a different material than the plurality of second granular particulates. 14. The method of claim 13 , wherein the stiffness of the first cell is greater than the stiffness of the second cell. 15. The method of claim 13 , wherein the plurality of first granular particulates have a different geometry than the plurality of second granular particulates. 16. The method of claim 13 , wherein the orthotic insole and the pressure controller are disposed within a shoe.