The present disclosure relates to a laser probe assembly coupled to a laser system through an optical fiber cable. In one example, the laser probe assembly comprises a probe tip coupled to the probe body, the probe tip housing multiple fibers. Each of the multiple fibers comprises a proximal end that couples to the laser system and a distal end that terminates in the probe tip, a single core for transporting a laser beam provided by the laser system, and a cladding surrounding the core. The laser probe assembly also comprises a lens for projecting multiple laser beams provided by the multiple fibers on to a surgical site. Within the probe tip, parts of outer surfaces of portions of any two adjacent fibers of the multiple fibers touch. Also, the multiple fibers are at least substantially centered with respect to the lens.

The invention provides an excimer laser system including a means for authenticating laser probes to be used with the excimer laser system via radio-frequency identification techniques.

The present disclosure generally relates to microsurgical instruments for ophthalmic surgical procedures, and more particularly, microsurgical instruments having combined illumination and laser vitrectomy functions. In some embodiments, a surgical instrument includes a base and a probe having a main lumen and a port at a distal end thereof. In some embodiments, the probe may further include one or more optical fibers within the main lumen and configured to project laser light and illumination light. According to some embodiments, as soon as vitreous material is drawn into the probe, e.g., through the port, the vitreous material passes through a volume irradiated by the laser light emitted by the optical fibers, thus severing the vitreous material. Simultaneously, the illumination light provides enhanced visualization of the intraocular space during severance and removal of the vitreous material.

Systems and methods for creating multi-spot laser light beams, multiplexing an illumination light and the multi-spot laser light beams, and delivering the multiplexed light to a surgical handpiece via a multi-core optical fiber cable.

A method for a minimally invasive, cell-selective laser therapy on the eye. The method, based on a short-pulse laser system, allows for different selective types of therapy on the eye. The method is based on a frequency-doubled, continuously working solid-state laser including a pump source and a control unit. The control unit regulates the pump source such that the solid-state laser emits individual pulses with pulse lengths ranging from 50 ns to continuous, wherein pulse lengths ranging from 50 ns to 50 μs are provided for selective therapies and pulse lengths ranging from 50 μs to continuous are provided for coagulative or stimulating therapies, in particular in the range from 1 ms to 500 ms. The proposed method enables a selective treatment of melanin-containing cells in the different areas of the eye via the targeted control of the pump source.

Certain embodiments of the present disclosure provide a thermally robust laser probe assembly. The probe assembly comprises a cannula through which one or more optical fibers extend at least partially for transmitting laser light from a laser source to a target location. The probe assembly also comprises a lens housed in the cannula and a protective component at a distal end of the cannula, wherein the lens is positioned between the one or more optical fibers and the protective component, and wherein the distal end of the cannula is sealed at a sealing location of the probe assembly.

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.

Technologies are described for monitoring efficacy of laser treatment through cell lysis determination. Current methods for removing diseased tissue may include directing laser treatment toward cells in a treatment area. The laser treatment may induce lysis of the cells without any visual indication of the lysis occurring. According to some examples, a treatment system may direct a pair of laser pulses to cells in a treatment area. The treatment system may derive a first signal and a second signal based on a detected response to the first and second laser pulse within the pair. A signal processor, according to some examples, may determine a difference between the first signal and the second signal and may modify the laser treatment based on the difference.

A photocoagulation apparatus of some embodiment examples is configured to apply both treatment light for subthreshold coagulation and an OCT scan to a retina via a probe inserted in an eye. Upon receiving a user's instruction, the apparatus applies the treatment light to the retina, and applies an OCT scan to the retina at least after the treatment light application. The apparatus compares the first OCT image constructed from OCT data of the retina acquired prior to the treatment light application and the second OCT image constructed from OCT data of the retina acquired after the treatment light application, thereby acquiring change information that represents a tissue change in the retina caused by the treatment light. The apparatus displays a change image based on the change information together with a retinal image.

An auxiliary surgical field visualization system is described, which includes an auxiliary surgical field camera, configured for acquiring an image of a field of view of a secondary surgical field, wherein the secondary surgical field includes the exterior of a patient's eye undergoing vitreoretinal surgery. The auxiliary surgical field visualization system also includes a display in electronic communication with the auxiliary surgical field camera, wherein the display is configured for receiving, from the auxiliary surgical field camera, a signal that includes the image of the field of view of the secondary surgical field, and upon receiving the signal, displaying the image of the field of view of the secondary surgical field.