Depletion block to block nerve communication

What is claimed is: 1. A system, comprising: a depletion block neural stimulator configured to deliver a depletion block stimulation to a nerve; and a depletion block controller configured to communicate with the depletion block neural stimulator and control the depletion block stimulation to provide a series of pulses at a pulse frequency within a range between 100 Hz to 700 Hz, the series of pulses including an amplitude and a pulse width to depolarize the nerve such that the depletion block stimulation induces action potentials in the nerve and depletes neurotransmitters to prevent action potentials from being communicated across a synaptic cleft, the depletion block controller configured to receive a start depletion block signal and respond to the received start depletion block signal by initiating the delivery of the depletion block stimulation to the nerve, and the depletion block controller configured to receive a stop depletion block signal and respond to the received stop depletion block signal by terminating the delivery of the depletion block stimulation to the nerve, wherein the depletion block controller is configured to change the pulse frequency of the depletion block stimulation, and is further configured to initiate the depletion block stimulation with a first pulse frequency and maintain the depletion block stimulation with a second pulse frequency less than the first pulse frequency. 2. The system of claim 1 , further comprising: an electrical therapy stimulator configured to generate and apply electrical stimulation to a patient; and a therapy controller configured to communicate with the electrical therapy stimulator and control the electrical stimulation, the therapy controller configured to send the start depletion block signal and the stop depletion block signal, and further configured to control the electrical therapy stimulator to generate and apply the electrical stimulation during a time period between sending the start and stop depletion block signals. 3. The system of claim 2 , wherein the electrical therapy stimulator includes an ablation system configured to ablate tissue using the electrical stimulation during an ablation procedure, and the depletion block neural stimulator is configured to reduce pain during the ablation procedure. 4. The system of claim 2 , wherein the electrical therapy stimulator includes a kilohertz high frequency alternating current (KHFAC) nerve block stimulator configured to deliver an KHFAC nerve block stimulation to the nerve, the nerve block stimulation including a series of pulses at a pulse frequency over 1 kHz to arrest action potentials in the axon; and the therapy controller is configured to send the start and stop depletion block signals near the beginning of the KHFAC nerve block stimulation to alleviate an onset response for the KHFAC nerve block stimulation. 5. The system of claim 1 , wherein the depletion block stimulator is configured to deliver the depletion block stimulation to the nerve selected to relieve spasmodic peripheral nerve pain, the system further comprising a patient input configured to receive a patient-initiatedsignal, the depletion block controller configured to send the start depletion block signal in response to receiving the patient-initiated signal. 6. The system of claim 1 , wherein the depletion block stimulator is configured to deliver the depletion block stimulation to the nerve selected to relieve spasmodic peripheral nerve pain, the system further comprising a muscle spasm detector configured to detect a spasmodic episode, the depletion block controller configured to send the start depletion block signal in response to detecting a spasmodic episode. 7. The system of claim 1 , wherein the depletion block stimulator is configured to deliver the depletion block stimulation to the nerve selected to relieve spasmodic peripheral nerve pain, the depletion block controller configured to adjust at least one of the amplitude or the pulse width of the depletion block stimulation to control a graded depletion block to allow some neurotransmitters to be released from the presynaptic terminal into the extracellular space. 8. The system of claim 1 , wherein the depletion block controller is configured to implement a process to automatically transition through at least two frequency stages, wherein a first pulse frequency stage includes the first pulse frequency and a second pulse frequency stage includes the second pulse frequency, and the first pulse frequency stage has a duration corresponding to a time period such that the depletion block controller transitions from the first pulse frequency stage to the second pulse frequency stage after the time period.