Optical probes for port-based corridor surgery are provided, including a device comprising: a surgical tool mounting adaptor configured for mounting to a surgical tool; an optical probe attached to the surgical tool mounting adaptor, the optical probe comprising: an optical interface end; an optical output end, distal the optical interface end, the optical output end comprising illumination optics and collection optics, the illumination optics configured to illuminate tissue proximal the optical output end, the collection optics configured to collect an optical signal from the tissue; one or more illumination optical fibers configured to convey illumination light from the optical interface end to the illumination optics; and, one or more collection optical fibers configured to convey the optical signal collected by the collection optics to the optical interface end.

An anatomical manometry catheter system, comprising a plurality of balloons on the distal end and being configured to be inflatable and/or deflatable. The system includes a connector assembly coaxially aligned with the catheter assembly, the connector assembly being connectable to the proximal end of the catheter. The connector assembly may have a connector interface connected to the proximal end of the catheter. The connector assembly may include a manifold comprising a plurality of channels configured to deliver the pressure transmission medium therethrough toward a respective catheter lumen for inflating one or more balloons. The connector assembly may include a charging mechanism fluidly coupled to the catheter that facilitates inflating each balloon of the plurality of balloons by a common actuating mechanism so as to simultaneously charge each balloon of the plurality of balloons.

A temperature measurement probe for a patient is provided. The probe includes a sensor assembly and produces a temperature map comprising temperature information for multiple patient locations.

A diagnostic assistance method for a disease based on an endoscopic image of a digestive organ with use of a convolutional neural network (CNN). A diagnostic assistance method for a disease based on an endoscopic image of a digestive organ with a CNN trains the CNN using a first endoscopic image of the digestive organ and at least one final diagnosis result on positivity or negativity to the disease in the digestive organ, a past disease, a severity level, and information corresponding to a site where an image is captured, the final diagnosis result corresponding to the first endoscopic image, and the trained CNN outputs at least one of a probability of the positivity and/or the negativity to the disease, a probability of the past disease, a severity level of the disease, an invasion depth of the disease, and a probability corresponding to the site where the image is captured.

A method may include positioning a catheter, including at least one electrode, within an esophagus such that the electrode is proximate to at least one sympathetic ganglion. The methods may further include recruiting the sympathetic ganglion via an electrical signal, monitoring the recruitment of the sympathetic ganglion, and, based on the monitoring the recruitment of the sympathetic ganglion, adjusting the electrical signal from the at least one electrode.

A device and method for mapping, diagnosing and treating disorders or other diseases, disorders or conditions (e.g., bleeding, ischemic or necrotic tissue, and presence of certain chemicals or substances) of the intestinal tract is provided using a capsule passing through the intestinal tract and sensing optical characteristics as the capsule passes through. Further, a capsule tracking system is provided for tracking a capsule's location along the length of an intestinal tract as various treatment and/or sensing modalities are employed. In one variation, an acoustic signal is used to determine the location of the capsule. A map of optical characteristics may be derived from the pass of a capsule to diagnose the disorder or disease. The capsule or subsequently passed capsules may treat, further diagnose or mark the intestinal tract at a determined location along its length.

A gastrointestinal (GI) sensor deployment device is disclosed. In implementations, the sensor deployment device includes an orally-administrable capsule with a tissue capture device removably coupled to the orally-administrable capsule. The tissue capture device includes a plurality of fasteners for connecting the tissue capture device to GI tissue within a body. A biometric sensor is coupled to the tissue capture device for continuous or periodic monitoring of the GI tract of the body at the GI tissue attachment location. A chamber within the orally-administrable capsule is configured to draw gastrointestinal tissue towards the plurality of fasteners when a fluid pressure of the chamber is increased. An actuator can be configured to cause an increase of the fluid pressure of the chamber. Control circuitry coupled to the actuator can be configured to trigger the actuator to cause the increase of the fluid pressure of the chamber at a selected time.

Disclosed are an imaging method using fluoroquinolone antibiotics and an imaging device for the same, in which biological tissue is stained with Moxifloxacin as one of fluoroquinolone antibiotics, and the stained biological tissue is subjected to fluorescent image-capture through single-photon excitation with either near-ultraviolet or visible wavelength light instead of either a middle-ultraviolet light source or a femtosecond near-infrared laser device, thereby obtaining morphological information of cells in the biological tissue at a high speed without damage. To this end, an imaging method of using fluoroquinolone antibiotics includes: staining cells of the biological tissue with fluoroquinolone antibiotics; illuminating the excitation light from a light source to the biological tissue stained with the fluoroquinolone antibiotics; and capturing an image of the biological tissue through the fluoroquinolone antibiotics based fluorescence caused by the excitation light illuminated to the biological tissue, wherein the excitation light from the light source includes either near-violet or short visible wavelength light for single photon excitation of the fluoroquinolone antibiotics.

Devices and a system for detection of blood within in-vivo fluids are provided. A device comprises a housing that includes a gap. The gap has at least one opening through which in-vivo fluids may enter and/or exit the gap. The device further comprises an illumination source for illuminating the in-vivo fluids in the gap, a light detector for detecting light which passes through the in-vivo fluids in the gap, and flexible fins disposed on the housing in the vicinity of the gap's opening for covering the opening when the fins are folded and for pumping fluids into and out of the opening by repeated closure and opening of the opening by the fins, due to repeated peristaltic waves. This pumping effect may lead to continuous flow of fluids into and out of the opening and thus into and out of the gap of the device.

A method may include positioning a catheter, including at least one electrode, within an esophagus such that the electrode is proximate to at least one sympathetic ganglion. The methods may further include recruiting the sympathetic ganglion via an electrical signal, monitoring the recruitment of the sympathetic ganglion, and, based on the monitoring the recruitment of the sympathetic ganglion, adjusting the electrical signal from the at least one electrode.