Abstract: A system and method for the present invention requires use of a generator, in combination with a radiation unit, to radiate electromagnetic waveform energy onto a target tissue (i.e. a cellular structure). During radiation of the target tissue in accordance with a predetermined titration-like protocol, the influence of the waveform energy on the cellular structure is periodically monitored. The protocol is stopped when the cellular structure has been transformed or morphed into a desired phenotype.

Abstract: A control system for delivering energy waveform radiation to influence in vivo tissue is described. For the system, the energy waveform radiation is generated by a radiation unit and is directed along a pathway to the tissue and a registration unit is provided to identify a start place relative to the in vivo tissue. Also, a monitor is provided to compare the start place with a base reference to measure an error signal between the start place and base reference. With this measured error signal, a controller operates the radiation unit using input from the monitor to effectively attain and maintain a zero error signal. More specifically, the controller can provide operational parameter inputs to the radiation unit for configuring the waveform radiation including a radiation frequency, f, and a volume intensity level, v, for the radiation and an exposure time interval, ti.

Abstract: A system and method for using a sonic wave to influence material in a target structure requires using a confined plasma antenna to generate an electromagnetic carrier wave, ?. The confined plasma antenna also pulses the carrier wave at a sonic frequency, f, to create a sonic wave. In detail, pulsing the carrier wave results in a sequential plurality of solitons which are separated from each other by a periodicity ?, wherein ?<<?. For the present invention, f is selected to resonate with a material (e.g. a cellular structure) in a target structure (e.g. a patient).

Abstract: A methodology in accordance with the present invention is directed toward optimizing the operational parameters of a radiation unit which will be used in a protocol to influence a target tissue (cellular structure), in a predetermined manner. Specifically, digital root techniques are used for this purpose. To do this, the digital root is determined for a number that is characteristic of a cellular structure attribute that is to be influenced by radiation. This digital root is then expanded into the range of a selected operational parameter for the radiation unit. Thus, a number in the operational range of the radiation unit is selected to establish an appropriate radiation parameter for influencing the cellular structure.

Abstract: A system and method for the present invention utilizes a generator, in combination with a radiation unit, to direct waveform energy towards a target tissue using a predetermined protocol directed by titration-like feedback. The effect of the waveform energy on cellular structures of the target tissue is periodically monitored, and the predetermined protocol is halted when the cellular structure has been transformed into a desired phenotype.

Abstract: A system and method for directing vibrational oscillating sonic waves toward a target tissue in the body of a person, to thereby influence a phenotypic differentiation of the target tissue at a cellular level, requires the use of an epidermal or implantable patch. Mounted on the patch is a sonic generator for generating sonic energy that entrains cellular functions of the target tissue for a desired phenotypic response. Also included is a unit for titrating the target tissue to monitor for changes in an expression level of the target tissue resulting from phenotypic differentiation.

Abstract: Systems and methods involving an intraocular implant with input and/or output electronics are described. In some embodiments, the system includes an intraocular lens having at least one optic operably coupled to a haptic, one or more input electronics on the haptic and/or the optic; and one or more output electronics on the haptic and/or the optic for receiving and/or transmitting data.

Abstract: In accordance with the present invention, a system and method are provided for using a computer-controlled, laser system to perform a partial vitrectomy of the vitreous humor in an eye. Operationally, an optical channel is first defined through the vitreous humor. Vitreous and suspended deposits (floaters) in the optical channel are then ablated and in some cases removed (e.g. aspirated) from the optical channel. In some instances, a clear liquid can be introduced into the optical channel to replace the ablated matter, and to thereby establish unhindered transparency in the optical channel.