Abstract: Providing neuroprotective therapy for glaucoma includes generating a micropulsed laser light beam having parameters and characteristics, including pulse length, power, and duty cycle, selected to create a therapeutic effect with no visible laser lesions or tissue damage to the retina. The laser light beam is applied to retinal and/or foveal tissue of an eye having glaucoma or a risk of glaucoma to create a therapeutic effect to the retinal and/or foveal tissue exposed to the laser light beam without destroying or permanently damaging the retinal and/or foveal tissue and improve function or condition of an optic nerve and/or retinal ganglion cells of the eye.

Abstract: A process for using a retinal photostimulation device involves limiting multiple or repeated uses of the device during a particular treatment cycle. Ordinarily a physician would not want to repeat multiple photostimulation treatments on a patient in a short period time. The process would prevent such retreatment during a single treatment cycle where the retina for any subsequent treatment biometrically matches the retina for an earlier treatment. Such subsequent treatments would be permitted within a predefined period of time after the earlier treatment. Such subsequent treatment may also be permitted where the retinas do not biometrically match.

Abstract: Providing neuroprotective therapy for glaucoma includes generating a micropulsed laser light beam having parameters and characteristics, including pulse length, power, and duty cycle, selected to create a therapeutic effect with no visible laser lesions or tissue damage to the retina. The laser light beam is applied to retinal and/or foveal tissue of an eye having glaucoma or a risk of glaucoma to create a therapeutic effect to the retinal and/or foveal tissue exposed to the laser light beam without destroying or permanently damaging the retinal and/or foveal tissue and improve function or condition of an optic nerve and/or retinal ganglion cells of the eye.

Abstract: A process for heat treating biological tissue includes repeatedly applying a pulsed energy to a target tissue over a period of time so as to controllably raise a temperature of the target tissue to create a therapeutic effect to the target tissue without destroying or permanently damaging the target tissue. After the first treatment is concluded the application of the pulsed energy to the target tissue is halted for an interval of time. Within a single treatment session a second treatment is performed on the target tissue after the interval of time by repeatedly reapplying the pulsed energy to the target tissue so as to controllably raise the temperature of the target tissue to therapeutically treat the target tissue without destroying or permanently damaging the target tissue.

Abstract: Providing neuroprotective therapy for glaucoma includes generating a micropulsed laser light beam having parameters and characteristics, including pulse length, power, and duty cycle, selected to create a therapeutic effect with no visible laser lesions or tissue damage to the retina. The laser light beam is applied to retinal and/or foveal tissue of an eye having glaucoma or a risk of glaucoma to create a therapeutic effect to the retinal and/or foveal tissue exposed to the laser light beam without destroying or permanently damaging the retinal and/or foveal tissue and improve function or condition of an optic nerve and/or retinal ganglion cells of the eye.

Abstract: A process for preventing or treating myopia includes applying a pulsed energy, such as a pulsed laser beam, to tissue of an eye having myopia or a risk of having myopia. The source of pulsed energy has energy parameters including wavelength or frequency, duty cycle and pulse train duration, which are selected so as to raise an eye tissue temperature up to eleven degrees Celsius to achieve therapeutic or prophylactic effect, such as stimulating heat shock protein activation in the eye tissue. The average temperature rise of the eye tissue over several minutes is maintained at or below a predetermined level so as not to permanently damage the eye tissue.

Abstract: A process that provides protective therapy for biological tissues or fluids includes applying a pulsed energy source to a target tissue or a target fluid having a chronic progressive disease or a risk of having a chronic progressive disease to therapeutically or prophylactically treat the target tissue or target fluid. The pulsed energy source has energy parameters selected so as to raise the target tissue or bodily target fluid temperature up to a predetermined temperature for a short period of time to achieve a therapeutic or prophylactic effect, while the average temperature rise of the target tissue or target fluid over a longer period of time is maintained at or below a predetermined level so as not to permanently damage the target tissue or target fluid.

Abstract: A process for heat treating biological tissue includes applying a pulsed energy to a first treatment area of a target tissue to create a therapeutic effect to the target tissue without destroying or permanently damaging the target tissue. After a predetermined interval of time, within a single treatment session, the pulsed energy is reapplied to the first treatment area. During the interval of time between pulsed energy applications to the first treatment area, the pulsed energy is applied to a second treatment area of the target tissue that is spaced apart from the first treatment area. The pulsed energy is repeatedly applied to each of the areas to be treated until a predetermined number of applications to each area to be treated has been achieved.

Abstract: Providing neuroprotective therapy for glaucoma includes generating a micropulsed laser light beam having parameters and characteristics, including pulse length, power, and duty cycle, selected to create a therapeutic effect with no visible laser lesions or tissue damage to the retina. The laser light beam is applied to retinal and/or foveal tissue of an eye having glaucoma or a risk of glaucoma to create a therapeutic effect to the retinal and/or foveal tissue exposed to the laser light beam without destroying or permanently damaging the retinal and/or foveal tissue and improve function or condition of an optic nerve and/or retinal ganglion cells of the eye.

Abstract: A process for performing retinal phototherapy or photostimulation includes generating a laser light that creates a therapeutic effect to retinal and/or foveal tissues exposed to the laser light without destroying or permanently damaging the retinal or foveal tissue. The laser light is applied to a first treatment area of the retina. After a predetermined interval of time, within a single treatment session, the laser light is reapplied to the first treatment area of the retina. During the interval of time between the laser light applications to the first treatment area, the laser light is applied to one or more additional areas of the retina that is spaced apart from the first treatment area and one another. The laser light is repeatedly applied to each of the areas to be treated until a predetermined number of laser light applications to each area to be treated has been achieved.

Abstract: A method for heat treating biological tissues includes providing a pulsed energy source having energy parameters selected so as to raise a target temperature to a level to achieve a therapeutic effect, while the average temperature rise of the tissue over a prolonged period of time is maintained at or below a predetermined level so as not to permanently damage the target tissue. Application of the pulsed energy source to the target tissue induces a heat shock response and stimulates heat shock protein activation in the target tissue so as to therapeutically treat the target tissue.

Abstract: A process for performing retinal phototherapy or photostimulation includes generating a laser light that creates a therapeutic effect to retinal and/or foveal tissues exposed to the laser light without destroying or permanently damaging the retinal or foveal tissue. The laser light is applied to a first treatment area of the retina. After a predetermined interval of time, within a single treatment session, the laser light is reapplied to the first treatment area of the retina. During the interval of time between the laser light applications to the first treatment area, the laser light is applied to one or more additional areas of the retina that is spaced apart from the first treatment area and one another. The laser light is repeatedly applied to each of the areas to be treated until a predetermined number of laser light applications to each area to be treated has been achieved.

Abstract: A system and method are disclosed for stimulating activation of heat shock proteins and facilitating protein repair in cells and tissues in order to take advantage of the remediative and restorative nature of the increased heat shock protein activation or production and the facilitation of protein repair, while not damaging the cells and tissues. This is accomplished by treating a specified target area with an ultrasound or electromagnetic radiation source which is pulsed and applied or focused to one or more small areas in order to achieve the necessary temperature rise or sufficiently stress the cells and tissue to stimulate heat shock protein production or activation and facilitate protein repair, while allowing the temperature to decay sufficiently quickly so as not to damage or destroy the treated tissue.

Abstract: A system and process for treating retinal diseases includes passing a plurality of radiant beams, i.e., laser light beams, through an optical lens or mask to optically shape the beams. The shaped beams are applied to at least a portion of the retina. Due to the selected parameters of the beams—pulse length, power and duty cycle—the beams can be applied to substantially the entire retina, including the fovea, without damaging retinal or foveal tissue, while still attaining the benefits of retinal phototherapy or photostimulation.

Abstract: A system and process for treating retinal diseases includes passing a laser light beam through an optical lens or mask to optically shape the light beam. The light beam is applied to at least a portion of the retina. Due to the selected parameters of the laser light beam pulse length, power and duty cycle, the laser light beam can be applied to substantially the entire retina, including the fovea, without damaging retinal or foveal tissue, while still attaining the benefits of retinal photocoagulation.

Abstract: A process for treating an eye to stop or delay the onset or symptoms of retinal diseases includes determining that the eye has a risk for a retinal disease before detectable retinal imaging abnormalities. A laser light beam is generated that provides preventative and protective treatment of the retinal tissue of the eye. At least a portion of the retinal tissue is exposed to the laser light beam without damaging the tissue. The retina may be retreated according to a set schedule or periodically according to the determination that the retina of the patient is to be retreated by monitored visual and/or retinal function or condition.

Abstract: A system and method are disclosed for stimulating activation of heat shock proteins and facilitating protein repair in cells and tissues in order to take advantage of the remediative and restorative nature of the increased heat shock protein activation or production and the facilitation of protein repair, while not damaging the cells and tissues. This is accomplished by treating a specified target area with an ultrasound or electromagnetic radiation source which is pulsed and applied or focused to one or more small areas in order to achieve the necessary temperature rise or sufficiently stress the cells and tissue to stimulate heat shock protein production or activation and facilitate protein repair, while allowing the temperature to decay sufficiently quickly so as not to damage or destroy the treated tissue.

Abstract: A process for restoring responsiveness to medication in eye tissue, namely retinal tissue, that is unresponsive to medication. The process utilizes a laser source for generating a confluent, contiguous laser light beam. The laser light beam is preferably a subthreshold diode micropulse laser beam which is optically shaped through an optical lens or mask. The tissue is then exposed to the confluent, contiguous laser light beam and allowed to recover for thirty days before administering medication to which the tissue was unresponsive.

Abstract: A process for restoring responsiveness to medication in eye tissue, namely retinal tissue, that is unresponsive to medication. The process utilizes a laser source for generating a confluent, contiguous laser light beam. The laser light beam is preferably a subthreshold diode micropulse laser beam which is optically shaped through an optical lens or mask. The tissue is then exposed to the confluent, contiguous laser light beam and allowed to recover for thirty days before administering medication to which the tissue was unresponsive.