A medical communication system including a first medical device with a memory storing first additional information to be added to first information related to a subject, a DICOM server, and a second medical device storing second additional information to be added to second information. The first medical device having a processor generating DICOM (Digital Imaging and Communication in Medicine)-format data of the first information, a first transmitter/receiver communicating the second information and at least a portion of the second additional information between the first medical device and the second medical device via a network defined by a prescribed protocol different from the DICOM protocol. The processor generates DICOM-format data of the second information based on at least the second additional information. The second transmitter/receiver communicates generated DICOM-format data of the first information and the second information with the DICOM server via the network defined by the DICOM protocol.

One or more devices, systems, methods, and storage mediums for imaging and more particularly to minimally invasive medical devices, such as, but not limited to, spectrally encoded endoscopy (SEE), endoscopy, and/or other catheter-related apparatuses and systems, methods, and storage mediums for use with same, are provided herein. One or more devices, systems, methods and storage mediums may be for characterizing, examining and/or diagnosing, and/or measuring viscosity of, a sample or object in application(s) using an apparatus or system that includes, in one or more embodiments, an in-situ optics observation window or lens cleaning apparatus or system that provides a technique(s) for cleaning the medical device optic(s) without removing the medical device during a surgical procedure.

A surgical visualization system may include tiered-access features. The surgical visualization system may be used to analyze at least a portion of a surgical field. Based on a control parameter, the system may assess the present state of moving particles that portion of the surgical field, assess an aggregated state of the moving particles, and/or assess moving particles at a selectable tissue depth. The control parameter may include system aspects such as processing capability or bandwidth for example and/or the identification of an appropriate service tier.

A disclosed medical device includes a first data transmission path that includes a first insulation device connecting a secondary circuit and a patient circuit such that serial data output from the secondary circuit is transmitted to the patient circuit while maintaining electrical insulation between the secondary circuit and the patient circuit; a second data transmission path that includes a second insulation device connecting the secondary circuit and the patient circuit such that the serial data transmitted from the secondary circuit to the patient circuit via the first data transmission path is fed back to the secondary circuit while maintaining electrical insulation between the secondary circuit and the patient circuit; and a comparison determination unit that is provided in the secondary circuit and compares the serial data output from the secondary circuit with the serial data fed back to the secondary circuit.

A surgical visualization system may be field programmable. The surgical visualization system may include a field programmable gate array (FPGA) and a processor. The FPGA may be configured to transform sensor information of backscattered laser light into real-time information of particle movement (e.g., blood cells) in a portion of a surgical field. The processor may be configured to receive an input and, based on that input, to reconfigure the logic elements of the FPGA, changing the operation of the FPGA from a first transform to a second transform. For example, the logic elements of the FPGA may be configured to assess particle movement at a selectable depth and then reconfigured, at the request of a surgeon, to assess aggregate particle movement over multiple depths.

Provided is and electrode selection device communicating with a capsule endoscope. The device includes an analog front end configured to recover first data based on first signals transmitted from the capsule endoscope to a first electrode and a second electrode, recover second data based on second signals transmitted from the capsule endoscope to the first electrode and a third electrode, and recover third data based on third signals transmitted from the capsule endoscope to the second electrode and the third electrode, and a digital receiver configured to calculate a first correlation value between the first and second electrodes, a second correlation value between the first and third electrodes, and a third correlation value between the second and third electrodes based on the first to third data. The digital receiver calculates first to third correlation sums, and selects a receiving electrode pair based on the first to third correlation sums.

A solid-state imaging device includes: a first semiconductor substrate including a light receiver that receives incident light; and a second semiconductor substrate including an image processing circuit that processes a signal from the light receiver and generates an image signal. The second semiconductor substrate includes: a nonvolatile memory including a region in which use history data is stored; and a control circuit (use history securing circuit) that restricts output of the image signal when the use history data is stored in the nonvolatile memory.

A medical assembly comprising a first imaging device comprising a first handle and a first shaft extending distally from the first handle, a second imaging device comprising a second handle and a second shaft extending distally from the second handle, and an imaging unit, wherein the first imaging device further comprises a first imager at a distal end of the first shaft, a first cable extending from the first handle for connection to the imaging unit, and a first connector, wherein the second imaging device further comprises a second imager at a distal end of the second shaft and a second connector, and wherein the first connector and the second connector are configured to connect, thereby transmitting imaging data from the second imager to the imaging unit via the first cable.

The present disclosure provides a wireless scanning device, including: a scanning housing, including: an image detector configured for acquiring 2D-images at a first 2D-frame-rate; and one or more processor(s) coupled to the image detector such that the 2D-images can be processed by the processor(s) to form processed data; a wireless module being coupled to the processor(s) such that the wireless module receives the processed data from the processor(s) and wirelessly transmits the processed data.

Various surgical hubs are disclosed. A surgical hub comprises a storage device; a processor coupled to the storage device; and a memory coupled to the processor. The memory stores instructions executable by the processor to: receive data from a surgical instrument coupled to the surgical hub; and determine a rate at which to transfer the data from the surgical hub to a remote cloud-based medical analytics network based on available storage capacity of the storage device.