Abstract: A method and system of treating connective tissue to increase flexibility of the connective tissue or decrease tension in the connective tissue includes forming perforations in the connective tissue to at least 90% of the depth or thickness of the connective tissue and maintaining the perforations in the connective tissue. The method alters the tissue to enhance the fundamental mechanisms involved the immunology, biochemistry, and molecular genetics of the metabolism of the connective tissue.

Abstract: Disclosed are systems, devices and methods for performing simulations using a multi-component Finite Element Model (FEM) of ocular structures involved in ocular accommodation.

Abstract: Hardware and software system solutions provide real-time, interactive predictive simulations of the eye (e.g., human eye or animal eye). The predictive simulations of an individual's eye can be created using a Finite Element Model (FEM) of ocular structures involved in optical biomechanics, including ocular accommodation.

Abstract: A method for ocular simulated camera assisted robot training is provided. In some implementations, the method includes initializing, by a processor, a robotics assembly. The method further includes connecting, by the processor, to one or more computing devices. The method further includes operating, by the processor, the robotics assembly. The method further includes simulating, by the processor, an eye movement of a human or animal. The method further includes operating, by the processor, a laser to perform a determined exercise on an eye of the robotics assembly. Related systems, methods, and articles of manufacture are also described.

Abstract: A system for a virtual integrated remote assistant is provided. In some implementations, the system performs operations comprising receiving an input for a surgical procedure. The operations further include determining first feedback for the surgical procedure. The operations further include receiving, in response to the first feedback, a user input. The operations further include receiving second feedback from a laser apparatus. The operations further include performing eye tracking verification for a user. The operations further include displaying a graphical display of a virtual assistant. Related systems, methods, and articles of manufacture are also described.

Abstract: Disclosed are systems, devices and methods for a modeling of ocular structures involved in ocular accommodation and use of a multi-component Finite Element Model (FEM).

Abstract: Disclosed are systems, devices and methods for laser microporation for rejuvenation of tissue of the eye, for example, regarding aging of connective tissue and rejuvenation of connective tissue by scleral rejuvenation. The systems, devices and methods disclosed herein restore physiological functions of the eye including restoring physiological accommodation or physiological pseudo-accommodation through natural physiological and biomechanical phenomena associated with natural accommodation of the eye. In some embodiments, the laser system may be configured to treat ocular tissue off axis or in a region of the eye which is distinct from the visual axis or directed away from the pupil of the eye where the gaze of the eye is.

Abstract: Disclosed are systems, devices and methods for performing simulations using a multi-component Finite Element Model (FEM) of ocular structures involved in ocular accommodation.

Abstract: A method and system of treating connective tissue to increase flexibility of the connective tissue or decrease tension in the connective tissue includes forming perforations in the connective tissue to at least 90% of the depth or thickness of the connective tissue and maintaining the perforations in the connective tissue. The method alters the tissue to enhance the fundamental mechanisms involved the immunology, biochemistry, and molecular genetics of the metabolism of the connective tissue.

Abstract: Systems, devices and methods are provided to deliver microporation medical treatments to improve biomechanics, wherein the system includes a laser for generating a beam of laser radiation on a treatment-axis not aligned with a patient's visual-axis, operable for use in subsurface ablative medical treatments to create an array pattern of micropores that improves biomechanics. The array pattern of micropores is at least one of a radial pattern, a spiral pattern, a phyllotactic pattern, or an asymmetric pattern.

Abstract: Disclosed are systems, devices and methods for performing simulations using a multi-component Finite Element Model (FEM) of ocular structures involved in ocular accommodation.

Abstract: Systems, devices and methods are provided to deliver microporation medical treatments to improve biomechanics, wherein the system includes a laser for generating a beam of laser radiation on a treatment-axis not aligned with a patient's visual-axis, operable for use in subsurface ablative medical treatments to create an array pattern of micropores that improves biomechanics. The array pattern of micropores is at least one of a radial pattern, a spiral pattern, a phyllotactic pattern, or an asymmetric pattern.

Abstract: Disclosed are systems, devices and methods for a modeling of ocular structures involved in ocular accommodation and use of a multi-component Finite Element Model (FEM).

Abstract: A method and system of treating connective tissue to increase flexibility of the connective tissue or decrease tension in the connective tissue includes forming perforations in the connective tissue to at least 90% of the depth or thickness of the connective tissue and maintaining the perforations in the connective tissue. The method alters the tissue to enhance the fundamental mechanisms involved the immunology, biochemistry, and molecular genetics of the metabolism of the connective tissue.

Abstract: A device for delivering ablative medical treatments to improve biomechanics comprising a laser for generating a beam of laser radiation used in ablative medical treatments to improve biomechanics, a housing, a controller within the housing, in communication with the laser and operable to control dosimetry of the beam of laser radiation in application to a target material, a lens operable to focus the beam of laser radiation onto a target material, and a power source operable to provide power to the laser and controller.

Abstract: Systems, devices and methods are provided to deliver microporation medical treatments to improve biomechanics, wherein the system includes a laser for generating a beam of laser radiation on a treatment-axis not aligned with a patient's visual-axis, operable for use in subsurface ablative medical treatments to create an array pattern of micropores that improves biomechanics. The array pattern of micropores is at least one of a radial pattern, a spiral pattern, a phyllotactic pattern, or an asymmetric pattern.

Abstract: Disclosed are systems, devices and methods for a modeling of ocular structures involved in ocular accommodation and use of a multi-component Finite Element Model (FEM).

Abstract: Disclosed are systems, devices and methods for performing simulations using a multi-component Finite Element Model (FEM) of ocular structures involved in ocular accommodation.

Abstract: A method and system of treating connective tissue to increase flexibility of the connective tissue or decrease tension in the connective tissue includes forming perforations in the connective tissue to at least 90% of the depth or thickness of the connective tissue and maintaining the perforations in the connective tissue. The method alters the tissue to enhance the fundamental mechanisms involved the immunology, biochemistry, and molecular genetics of the metabolism of the connective tissue.

Abstract: A method and system of treating connective tissue to increase flexibility of the connective tissue or decrease tension in the connective tissue includes forming perforations in the connective tissue to at least 90% of the depth or thickness of the connective tissue and maintaining the perforations in the connective tissue. The method alters the tissue to enhance the fundamental mechanisms involved the immunology, biochemistry, and molecular genetics of the metabolism of the connective tissue.