Shape memory actuators for adjustable shunting systems, and associated systems and methods

We claim: 1. An adjustable shunting system, comprising: a shunting element; and a shape memory actuator having— a first plurality of petals each having a corresponding first curved segment, wherein the first plurality of petals are coupled to the shunting element, a second plurality of petals each having a corresponding second curved segment, wherein the second plurality of petals at least partially define a lumen through the system, and a plurality of curved regions coupling the first plurality of petals and the second plurality of petals, wherein individual curved regions of the plurality of curved regions are positioned between individual first curved segments and individual second curved segments; wherein the shape memory actuator is configured to adjust a geometry of the lumen by changing a curvature of the plurality of curved regions to move the second plurality of petals relative to the first plurality of petals, and wherein the system is configured such that strain in the shape memory actuator is concentrated in the plurality of curved regions when the shape memory actuator is deformed relative to its preferred geometry. 2. The adjustable shunting system of claim 1 wherein the shape memory actuator is configured such that, when an electrical current is applied to the shape memory actuator, the plurality of curved regions experiences higher resistive heating than the first plurality of petals and the second plurality of petals. 3. The adjustable shunting system of claim 1 wherein the plurality of curved regions have an axial cross-sectional area smaller than an axial cross-sectional area of the second plurality of petals. 4. The adjustable shunting system of claim 1 wherein, when electrical current flows through the shape memory actuator, the plurality of curved regions have a higher electrical current density than the second plurality of petals. 5. The adjustable shunting system of claim 1 wherein the plurality of curved regions form an annular structure, and wherein the second plurality of petals extend from the annular structure to form a conical structure. 6. The adjustable shunting system of claim 1 wherein the second plurality of petals are substantially unstrained when the actuator is deformed relative to its preferred geometry. 7. The adjustable shunting system of claim 1 wherein the first plurality of petals, the second plurality of petals, and the plurality of curved regions, comprise a unitary structure. 8. The adjustable shunting system of claim 1 wherein the system is configured such that, when the system is implanted in a patient: the shunting element engages patient tissue and extends between a first body region and a second body region; the shape memory actuator extends into the first body region or the second body region. 9. The adjustable shunting system of claim 1 wherein the shape memory actuator is configured such that respective curvatures of the first curved segments and the second curved segments remain generally unchanged when the curvature of the plurality of curved regions changes. 10. The adjustable shunting system of claim 1 wherein the shape memory actuator is composed of a contiguous structure that alternates between individual first petals and individual second petals, with individual curved regions between each individual first petal and individual second petal. 11. An adjustable shunting system, comprising: a shunting element; and a shape memory actuator, the shape memory actuator comprising a plurality of actuation members arranged in a conical shape, wherein each individual actuation member of the plurality of actuation members includes— a curved portion; and a projection portion extending from the curved portion, wherein individual projection portions of different actuation members are not directly in series electrically with each other; and a lumen extending through the shunting element and the shape memory actuator between a first orifice and a second orifice, wherein the shape memory actuator is configured to adjust a geometry of the lumen, the first orifice, and/or the second orifice, and wherein the system is configured such that any strain in the shape memory actuator is concentrated in the curved portions of the actuation members. 12. The adjustable shunting system of claim 11 wherein the individual actuation members have a “Y” shape. 13. The adjustable shunting system of claim 11 wherein the individual actuation members are arranged side-by-side to form the conical shape. 14. The adjustable shunting system of claim 11 wherein, when actuated, the shape memory actuator is configured to bend at the curved portions. 15. The adjustable shunting system of claim 11 wherein the individual actuation members are integral with one another such that the shape memory actuator is a unitary structure. 16. An adjustable shunting system, comprising: a shunting element; and a shape memory actuator having a first plurality of petals coupled to the shunting element, a second plurality of petals at least partially defining a lumen through the system, and a plurality of curved regions coupling the first plurality of petals and the second plurality of petals; wherein the shape memory actuator is configured to adjust a geometry of the lumen, and wherein the system is configured such that (a) strain in the shape memory actuator is concentrated in the plurality of curved regions when the shape memory actuator is deformed relative to its preferred geometry, and (b) individual curved regions of the plurality of curved regions are in electrical series. 17. The adjustable shunting system of claim 16 wherein the shape memory actuator is configured such that, when an electrical current is applied to the shape memory actuator, the plurality of curved regions experiences higher resistive heating than the first plurality of petals and the second plurality of petals. 18. The adjustable shunting system of claim 16 wherein the shape memory actuator further comprises a plurality of electrical bridges extending between and electrically coupling the plurality of curved regions.