Abstract: One embodiment is directed to a method for treating the nervous system of a patient, comprising: determining a desired nervous system functional modulation to be facilitated by sonogenetic intervention; selecting targeted neuroanatomy for achieving the desired functional outcome with sonogenetic intervention; and delivering an effective amount of polynucleotide comprising a sound-responsive opsin protein which is expressed in neurons of the targeted neuroanatomy, wherein delivering comprises systemically injecting the effective amount of polynucleotide and facilitating diffusive access to the targeted neuroanatomy using focused ultrasound energy.

Abstract: One embodiment is directed to a method for treating the nervous system of a patient, comprising: determining a desired nervous system functional modulation to be facilitated by optogenetic intervention; selecting targeted neuroanatomy for achieving the desired functional outcome with optogenetic intervention; and delivering an effective amount of polynucleotide comprising a light-responsive opsin protein which is expressed in neurons of the targeted neuroanatomy, and delivering an effective amount of immunosuppressant.

Abstract: One embodiment is directed to a method for acoustically modulating activity of cells comprising a targeted tissue portion of a patient. An implantable probe system may be utilized for delivering acoustical energy to a targeted tissue portion of a patient, comprising a plurality of substrate portions, each substrate portion comprising at least one acoustical emitter; a probe body portion having proximal and distal ends and being movably coupled to the plurality of substrates and configured to at least partially encapsulate the plurality of substrates; and a distal end portion coupled to the distal end of the probe body portion, the distal end portion comprising at least one guiding feature configured to redirect a path of at least one of the substrate portions as such substrate portion is extended through and past the distal end portion by moving the plurality of substrates relative to the probe body portion.

Abstract: One embodiment is directed to an implantable probe system for delivering acoustical energy to a targeted tissue portion of a patient, comprising: a plurality of substrate portions, each substrate portion comprising at least one acoustical emitter; a probe body portion having proximal and distal ends and being movably coupled to the plurality of substrates and configured to at least partially encapsulate the plurality of substrates; and a distal end portion coupled to the distal end of the probe body portion, the distal end portion comprising at least one guiding feature configured to redirect a path of at least one of the substrate portions as such substrate portion is extended through and past the distal end portion by moving the plurality of substrates relative to the probe body portion

Abstract: One embodiment is directed to a system for altering the function of a sensory unit that innervates a targeted tissue region in an animal, the sensory unit being configured to express a light-responsive protein, comprising a light delivery element configured to direct radiation to at least a portion of a targeted tissue structure; and a light source configured to provide light to the light delivery element; wherein the targeted tissue structure is illuminated transcutaneously with radiation such that a membrane potential of cells comprising the targeted tissue structure is modulated at least in part due to exposure of the light-responsive protein to the radiation.

Abstract: One embodiment is directed to a system for altering the function of a sensory unit that innervates a targeted tissue region in an animal, the sensory unit being configured to express a light-responsive protein, comprising a light delivery element configured to direct radiation to at least a portion of a targeted tissue structure; and a light source configured to provide light to the light delivery element; wherein the targeted tissue structure is illuminated transcutaneously with radiation such that a membrane potential of cells comprising the targeted tissue structure is modulated at least in part due to exposure of the light-responsive protein to the radiation.

Abstract: One embodiment is directed to a method for altering the function of the sensory unit that innervates a targeted tissue region in a mammal comprising the steps of identifying the targeted tissue region; cutaneously administering into the targeted tissue region an adeno-associated virus wherein the viral genome encodes at least one exogenous protein; expressing the exogenous protein in the targeted sensory unit; and altering the function of the targeted sensory unit to treat or restore the sensory response because of the exogenous protein expression while not impacting the function of nearby sensory units.

Abstract: One embodiment is directed to a method for controllably managing pain in the afferent nervous system of a patient having a targeted tissue structure that has been genetically modified to have light sensitive protein, comprising: providing a light delivery element configured to direct radiation to at least a portion of a targeted tissue structure, a light source configured to provide light to the light delivery element, and a controller operatively coupled to light source, wherein the targeted tissue structure comprises a sensory neuron of the patient; and automatically operating the controller to illuminate the targeted tissue structure with radiation such that a membrane potential of cells comprising the targeted tissue structure is modulated at least in part due to exposure of the light sensitive protein to the radiation.

Abstract: One embodiment is directed to a system for controllably managing pain in the afferent nervous system of a patient having a targeted tissue structure that has been genetically modified to have light sensitive protein, comprising a light delivery element configured to direct radiation to at least a portion of a targeted tissue structure; a light source configured to provide light to the light delivery element; and a controller operatively coupled to light source; wherein the targeted tissue structure comprises a sensory neuron of the patient; and wherein the controller is configured to be automatically operated to illuminate the targeted tissue structure with radiation such that a membrane potential of cells comprising the targeted tissue structure is modulated at least in part due to exposure of the light sensitive protein to the radiation.