One embodiment is directed to a system comprising a head-mounted member removably coupleable to the user's head; one or more electromagnetic radiation emitters coupled to the head-mounted member and configured to emit light with at least two different wavelengths toward at least one of the eyes of the user; one or more electromagnetic radiation detectors coupled to the head-mounted member and configured to receive light reflected after encountering at least one blood vessel of the eye; and a controller operatively coupled to the one or more electromagnetic radiation emitters and detectors and configured to cause the one or more electromagnetic radiation emitters to emit pulses of light while also causing the one or more electromagnetic radiation detectors to detect levels of light absorption related to the emitted pulses of light, and to produce an output that is proportional to an oxygen saturation level in the blood vessel.

Systems and methods for monitoring properties of the cornea and controlling the crosslinking treatment. The thickness of the cornea during crosslinking may be measured by using ultrasonic reflections to determine an anterior distance (D.sub.1′) between a reference location (37) on a device resting on the eye and an anterior surface (66) of the cornea and to determine a posterior distance (D.sub.3′) between a posterior surface (63) of the cornea and an element of the eye such as an anterior surface (72) of the lens of the eye. These distances are subtracted from a reference distance (D.sub.0) between the reference location and the element of the eye. The reference distance (D.sub.0) may be determined using ultrasonic reflections to determine the corresponding anterior and posterior distances and the thickness (D.sub.2) of the cornea prior to crosslinking. The speed of sound in the cornea during crosslinking may be derived using the thickness (D2′) and time of flight of ultrasound through the cornea. The position of the cornea relative to a reference location may be determined. In still other embodiments, location of a surface of demarcation (86) within the cornea formed as a result of crosslinking may be determined. Still other embodiments provide for determination of one or more resonant frequencies of the cornea, and for measurement of responses of the cornea to applied forces, such as displacement and rebound velocity. The properties of the cornea may be used as proxies for the extent of crosslinking, and a light source (48, 348) used to induce crosslinking may be controlled in response to such proxies.

Systems and methods for monitoring properties of the cornea and controlling the crosslinking treatment. The thickness of the cornea during crosslinking may be measured by using ultrasonic reflections to determine an anterior distance (D.sub.1′) between a reference location (37) on a device resting on the eye and an anterior surface (66) of the cornea and to determine a posterior distance (D.sub.3′) between a posterior surface (63) of the cornea and an element of the eye such as an anterior surface (72) of the lens of the eye. These distances are subtracted from a reference distance (D.sub.0) between the reference location and the element of the eye. The reference distance (D.sub.0) may be determined using ultrasonic reflections to determine the corresponding anterior and posterior distances and the thickness (D.sub.2) of the cornea prior to crosslinking. The speed of sound in the cornea during crosslinking may be derived using the thickness (D2′) and time of flight of ultrasound through the cornea. The position of the cornea relative to a reference location may be determined. In still other embodiments, location of a surface of demarcation (86) within the cornea formed as a result of crosslinking may be determined. Still other embodiments provide for determination of one or more resonant frequencies of the cornea, and for measurement of responses of the cornea to applied forces, such as displacement and rebound velocity. The properties of the cornea may be used as proxies for the extent of crosslinking, and a light source (48, 348) used to induce crosslinking may be controlled in response to such proxies.

An ultrasound transducer may include: a plurality of capacitive ultrasound transducer elements; and a base having a largest dimension sized and shaped to be disposed with an external ear canal, wherein the plurality of capacitive ultrasound transducers is mounted on the base. Each capacitive ultrasound transducer element and the ultrasound transducer are specifically constructed to achieve select desired performance characteristics. The ultrasound transducer may have an angular beam spread through a gaseous medium of greater than 15 degrees and an attenuation loss through the gaseous medium of greater than 10 dB measured at a distance 12.5 mm to 25 mm along a primary transmission axis of the ultrasound transducer. The ultrasound transducer may be particularly useful for characterizing fluid behind an ear drum to diagnose otitis media.

It has been discovered that even mild changes in cerebrospinal fluid (CSF) pressure or intracranial pressure (ICP) can be detected immediately as evidenced by distortions in the ONS surface structure. Further, the changes in the ONS persist after the CSF pressure has returned to normal. The stability of ONS distortions provides a method of detecting transient changes in brain pressure even when the use of the diagnostic ultrasound is delayed. One embodiment provides systems and methods for detecting or diagnosing brain injury by detecting distortions or deformations of the ONS, preferably using ultrasound.

It has been discovered that even mild changes in cerebrospinal fluid (CSF) pressure or intracranial pressure (ICP) can be detected immediately as evidenced by distortions in the ONS surface structure. Further, the changes in the ONS persist after the CSF pressure has returned to normal. The stability of ONS distortions provides a method of detecting transient changes in brain pressure even when the use of the diagnostic ultrasound is delayed. One embodiment provides systems and methods for detecting or diagnosing brain injury by detecting distortions or deformations of the ONS, preferably using ultrasound.

A method and system assist a physician in performing an ophthalmic surgery. The method includes receiving a quasi-real time image of at least a first portion of the eye. The at least the first portion of the eye includes an operating field for the ophthalmic surgery. A recommended next region and a recommended next procedure are determined based on the quasi-real time image and a computational model of the eye. An expected next result for the recommended next procedure is calculated using the quasi-real time image and the computational model. The recommended next region, the recommended next procedure and the expected result are provided to the physician.

A method and system assist a physician in performing an ophthalmic surgery. The method includes receiving a quasi-real time image of at least a first portion of the eye. The at least the first portion of the eye includes an operating field for the ophthalmic surgery. A recommended next region and a recommended next procedure are determined based on the quasi-real time image and a computational model of the eye. An expected next result for the recommended next procedure is calculated using the quasi-real time image and the computational model. The recommended next region, the recommended next procedure and the expected result are provided to the physician.

Configurations are disclosed for a health system to be used in various healthcare applications, e.g., for patient diagnostics, monitoring, and/or therapy. The health system may comprise a light generation module to transmit light or an image to a user, one or more sensors to detect a physiological parameter of the user's body, including their eyes, and processing circuitry to analyze an input received in response to the presented images to determine one or more health conditions or defects.

Configurations are disclosed for a health system to be used in various healthcare applications, e.g., for patient diagnostics, monitoring, and/or therapy. The health system may comprise a light generation module to transmit light or an image to a user, one or more sensors to detect a physiological parameter of the user's body, including their eyes, and processing circuitry to analyze an input received in response to the presented images to determine one or more health conditions or defects.