A wireless medical imaging system comprising a head unit is provided. The head unit comprises a head unit case, an integrated light source, an image sensor, a wireless transceiver, a central processing unit, and a user-input component. The head unit case has an external surface defining an external cavity, an internal surface defining an internal cavity, a first aperture, and a second aperture. The integrated light source, the image sensor, the wireless transceiver, and the central processing unit are disposed within the internal cavity. The integrated light source extends from within the internal cavity into the first aperture and is configured to transmit light from the head unit through the first aperture. The image sensor is configured to detect an image transmitted into the head unit through the second aperture. The external cavity is configured to receive an external battery. The user-input component is disposed on the external surface.

A point-of-care system with a diagnostic tool and a base station with a display and in communication with the diagnostic tool is described. Used in diagnosing health conditions for a tissue under analysis, the diagnostic tool includes a handle and a head portion. The head portion includes a speculum and optical spectroscopy (OS) data acquisition components positioned within the head portion. The OS data acquisition components are configure to (i) emit light toward the tissue under analysis, (ii) receive light reflected at least in part from the tissue under analysis based on the emitted light, and (iii) determine reflectance spectra associated with the received light. Either the diagnostic tool or a base station includes analytic components configured to (i) generate diagnostic metrics including characteristics of the reflectance spectra and (ii) compare these characteristics to data associated with characteristics of known reflectance spectra associated healthy and/or unhealthy tissue of patients.

Medical borescopes and related methods. In some embodiments, a medical borescope may comprise a handle and a tube extending from the handle. The tube may be partially, or wholly, defined by an at least substantially non-conductive material, such as a suitable plastic, ceramic, or other non-metallic material. The borescope may further comprise a tip assembly positioned at a distal end of the tube, which may comprise an image sensor configured to take images through the distal end of the tube.

A portable endoscopic inspection system comprises an endoscope having a proximal end with a flanged eyepiece for observation and a distal end with a lens assembly for insertion into a region of interest. A light port transports incident light to the region of interest along an lighting pathway, and reflected light is transported along an imaging pathway from the lens assembly to the eyepiece. A wireless imaging unit comprises a light source which detachably couples to the light port for generating the incident light, and an imaging sensor for recording images of the reflected light from the eyepiece. The wireless imaging unit comprises a variable coupling system which mechanically couples the imaging sensor to the flanged eyepiece independent of the shape and/or size of the flange of the eyepiece.

The present invention discloses a system for wireless capsule endoscope with adaptive frame rate, comprising: a recorder data processor to filter the first posture information of a capsule endoscope and the second posture information of a portable recorder to obtain a quaternion p.sub.0 of the first posture information and a quaternion p.sub.1 of the second posture information, and to calculate an interpolated median s.sub.0 between p.sub.0 and p.sub.1 at time t.sub.0, and an interpolated median s.sub.1 between p′.sub.0 and p′.sub.1 at time t.sub.1; the recorder data processor also calculates a difference diff.sub.0 between the interpolated median s.sub.0 and s.sub.1, and works out the dot product of the difference diff.sub.0 and unit quaternion [1, 0, 0, 0].

A laryngoscope enhancement system (LES) and an intubation system including an LES are provided. The LES includes a holder and a video stylet. The holder includes an adjustable mount to releasably secure an electronic device with a display, and an end cap configured to removably attach the holder to an upper end of a laryngoscope handle. The video stylet includes a connecter removably attachable to the electronic device, a flexible segment, a malleable segment and a video camera.

A method of manufacturing a laryngoscope may include forming a blade being straight and having a handle side and a non-handle side, the blade including a structure that extends from a proximal end to a distal end, and configured to connect to a handle at the proximal end. A first channel may be formed through the structure. The first channel may be configured to enable optical signals to pass therethrough. The first channel may include (i) a first aperture disposed at the proximal end of the first channel and (ii) a second aperture disposed at the distal end of the first channel. The second aperture may be oriented at an offset angle toward the handle side such that images captured via the second aperture are at the offset angle.

An instrument head is provided for attachment to a plurality of instrument handles having different power profiles. The instrument head contains an illumination assembly including at least one LED as well as a drive circuit for detecting a power profile of an attached instrument handle and converting variable voltages received from the attached instrument handle to a constant current for powering the at least one LED based on the power profile. Accordingly, the instrument head enables use with a plurality of instrument handles, including those originally configured for use only with incandescent light sources.

According to an embodiment, an autonomous endoscopic system capable of controlling movement of an endoscope inserted into a protective sheath installed in the body of a patient may comprise: an endoscope operating device capable of operating a relative position of the endoscope with respect to the protective sheath, a rolling angle of the endoscope, and a bending angle of a bending portion which is located at the end of the endoscope and is bendable; and a control unit for controlling the endoscope operating device, wherein the control unit controls the endoscope operating device on the basis of a driving record of the endoscope.

The invention relates to a device for acquiring personal health information and a method therefor, the device: easily and periodically acquiring, anytime and anywhere or without regard to place and time, information on ambient temperature/humidity and health information of an individual, such as the state of skin (including hair), a nose, ears, and a mouth associated with an ENT clinic, the teeth associated with a dental clinic, skin moisture, and body temperature, through image information having multiple functions and a multifunctional health care sensor; enabling the acquired health information to be accumulated over in a personal terminal or computer by analyzing, storing, and making the same into data, and continuously managing the periodically accumulated personal health information such that the personal health information can be used as critical information by which a disease cause and the like can be fundamentally understood during an incidence of disease in the future.