System and method for communicating information between implantable devices

The invention claimed is: 1. A system for communicating information between at least two medical devices adapted to be implanted within the body of a subject using volume conduction of electric signals as a means or channel of communication, the system comprising: a first implant device having (i) at least three transmit electrodes that comprise a first transmit electrode configured to transmit stimulation pulses, and a second electrode and a third electrode configured as return electrodes and (ii) an encoder-controller-pulse generator configured to employ a channel as a transmission or communication medium for the stimulation pulses and to encode the information into the stimulation pulses or between the stimulation pulses, wherein the at least three transmit electrodes and the encoder-controller-pulse generator comprise a same circuitry (a) for transmitting the stimulation pulses for therapeutic use and (b) reused for transmitting the information; and a second implant device (i) having at least two receive electrodes configured to receive the transmitted information encoded into the stimulation pulses or between the stimulation pulses and (ii) a decoder configured to decode the information encoded into or between the stimulation pulses, wherein the encoder-controller-pulse generator of the first implant device further comprises a switch for switching a return current path of the at least three transmit electrodes to run via (i) the second electrode alone, (ii) the third electrode alone, and (iii) both the second electrode and the third electrode together to produce different electric field distributions that encode the information, and wherein the at least two receive electrodes of the second implant device are further configured to detect the different electric field distributions encoded with the information. 2. The system as claimed in claim 1 , wherein the encoder-controller-pulse generator is further configured to use at least one of (i) a timing of the simulation pulses, (ii) a shape of the simulation pulses, and (iii) both a timing and a shape of the stimulation pulses as a means to encode the information. 3. The system as claimed in claim 1 , wherein the encoder-controller-pulse generator is further configured to interlace data signals in between the stimulation pulses as a means to encode the information and wherein the interlaced data signals are smaller in amplitude than the stimulation pulses. 4. The system as claimed in claim 1 , wherein the first implant device and the second implant device each comprise an electro stimulator device and each of the encoder-controller-pulse generator and the decoder is configured to use a pulse time coding scheme. 5. The system as claimed in claim 1 , wherein the first implant device and the second implant device each comprise an electro stimulator device adapted to be implanted in a skull and the encoder-controller-pulse generator is configured to employ the channel for stimulation pulses and encode the information into the stimulation pulses. 6. The system as claimed in claim 1 , wherein the first implant device is further configured to communicate with an external device using volume conduction or electrical signals as a means of communication. 7. A method for communicating information between at least two medical devices adapted to be implanted within the body of a subject using volume conduction of electrical signals as a means or channel of communication, the method comprising: employing, via a first implant device, a channel as a transmission or communicating medium for stimulation pulses and encoding the information into or between the stimulation pulses, wherein the first implant device includes (i) at least three transmit electrodes that comprise a first transmit electrode configured to transmit stimulation pulses, and a second electrode and a third electrode configured as return electrodes, and (ii) an encoder-controller-pulse generator, wherein the at least three transmit electrodes and the encoder-controller-pulse generator comprise a same circuitry (a) for transmitting the stimulation pulses for therapeutic use and (b) reused for transmitting the information; transmitting (i) the stimulation pulses and (ii) the information using the at least three transmit electrodes provided in the first implant device; receiving, via a second implant device, the transmitted information encoded into or between the stimulation pulses using at least two receive electrodes provided in the second implant device; and decoding the information encoded into or between the stimulation pulses, wherein the encoder-controller-pulse generator of the first implant device further comprises a switch for switching a return current path of the at least three transmit electrodes to run via (i) the second electrode alone, (ii) the third electrode alone, and (iii) both the second electrode and the third electrode together to produce different electric field distributions that encode the information, and wherein the at least two receive electrodes of the second implant device are further configured to detect the different electric field distributions encoded with the information.