A serrated stethoscope tube is disclosed herein. The serrated stethoscope tube includes a tubular body portion, the tubular body portion having an exterior surface and an interior surface, the interior surface being oppositely disposed relative to the exterior surface, and the interior surface of the tubular body portion having a plurality of channels formed therein for reducing sound wave refraction and/or reverberation.

A serrated stethoscope tube is disclosed herein. The serrated stethoscope tube includes a tubular body portion, the tubular body portion having an exterior surface and an interior surface, the interior surface being oppositely disposed relative to the exterior surface, and the interior surface of the tubular body portion having a plurality of channels formed therein for reducing sound wave refraction and/or reverberation.

The present disclosure provides an apparatus comprising a housing with a left side panel, right side panel, and top panel, each of which may comprise a slot. The apparatus may comprise a front panel that is insertable into the slots of the left and right-side panels. The front panel may comprise a recessed region configured to receive a portion of a medical instrument. A source of a barrier material may be supported by the left and right-side panels. The apparatus may comprise a lid cover comprising a roller portion that is insertable into a slot of the top panel. The lid cover may pivot relative to the housing when the roller portion is inserted into the slot of the top panel. The lid cover and the front panel may form a gap through which a portion of the barrier material may extend when the barrier material is dispensed.

Medical diagnostic devices or components thereof are described that comprise a microstructured surface that comprises peak structures and adjacent valleys wherein the valleys have a maximum width ranging from 1 to 1000 microns and the peak structures. In some embodiments (e.g.

for improved cleanability) the peak structures of the microstructured surface have a side wall angle of greater than 10 degrees. The peak structures may comprise two or more facets such as in the case of a linear array of prisms or an array of cube-comers elements. The microstructured surface of the medical diagnostic device typically comes in contact with multiple patients during normal use of the device, such as a stethoscope diaphragm. The microstructured surface exhibits better microorganism (e.g. bacteria) removal when cleaned and/or provides a reduction in microbial touch transfer. Also described are methods of making and methods of use.

Medical diagnostic devices or components thereof are described that comprise a microstructured surface that comprises peak structures and adjacent valleys wherein the valleys have a maximum width ranging from 1 to 1000 microns and the peak structures. In some embodiments (e.g.

for improved cleanability) the peak structures of the microstructured surface have a side wall angle of greater than 10 degrees. The peak structures may comprise two or more facets such as in the case of a linear array of prisms or an array of cube-comers elements. The microstructured surface of the medical diagnostic device typically comes in contact with multiple patients during normal use of the device, such as a stethoscope diaphragm. The microstructured surface exhibits better microorganism (e.g. bacteria) removal when cleaned and/or provides a reduction in microbial touch transfer. Also described are methods of making and methods of use.

A device and method for verifying the proper position of catheters in the body by means of acoustic reflectometry, the device including a sound source, one or more sound receivers, a tube with compliant walls and open distal end to be introduced through an entrance to a body cavity, the sound source and receiver(s) coupled to the proximal end of the tube, a processor for causing the sound source to generate an acoustic excitation signal, the processor processing the acoustic signals sensed by the sound receiver(s) and generating an approximation of the acoustic impulse response of the tube, and the processor analyzing the acoustic impulse response to determine the position of the tube in the body cavity.

A quick release structure of a diaphragm assembly of a stethoscope is disclosed, including a stethoscope having two collecting surfaces each being connectable with a diaphragm assembly. The collecting surface has a portion adjacent to an outer periphery thereof and formed with an annular fitting groove that has a height lower than the collecting surface. The collecting surface is formed with a trough. The annular fitting groove has an inclined internal wall. The diaphragm assembly includes an elastic piece combined with a diaphragm assembly. The elastic piece includes a raised rib, a projection portion, and an inclined inside surface. Through pressing the raised rib into the annular fitting groove, the inside surface is set in tight engagement with the internal wall, and this, in combination with the projection portion fit in the trough, forms a secure and stable fitting engagement and allowing easy release performed in an opposite way.

A quick release structure of a diaphragm assembly of a stethoscope is disclosed, including a stethoscope having two collecting surfaces each being connectable with a diaphragm assembly. The collecting surface has a portion adjacent to an outer periphery thereof and formed with an annular fitting groove that has a height lower than the collecting surface. The collecting surface is formed with a trough. The annular fitting groove has an inclined internal wall. The diaphragm assembly includes an elastic piece combined with a diaphragm assembly. The elastic piece includes a raised rib, a projection portion, and an inclined inside surface. Through pressing the raised rib into the annular fitting groove, the inside surface is set in tight engagement with the internal wall, and this, in combination with the projection portion fit in the trough, forms a secure and stable fitting engagement and allowing easy release performed in an opposite way.

The present invention relates to a method and system for determining a central pulse wave velocity in a pregnant woman. The method comprises receiving an indication of a measurement of a length of a human aortic path outside the body to provide an aortic length, arranging a sound transducer at the position of the anatomical projection of the uterine artery, identifying the opening of the maternal aortic valve with measurement from the sound transducer as a first time, and the pulse wave arrival time at the uterine artery with measurements from the sound transducer as a second time, determining the central transit time based on the difference between the second time and the first time, and calculating the central pulse wave velocity based on the aortic length and the central transit time.

Exemplary embodiments of the present disclosure are directed towards a medical device for assessing, and predicting and operating the user's health by capturing the user's vital signs in real time. The medical device comprises a plurality of electrodes and a plurality of sensors positioned on various finger sheaths, wrist portions, and hand portions. The various finger sheaths, the wrist portions, and the hand portions are configured to allow the plurality of electrodes to detect a plurality of electrical potentials on different surfaces of a user's body parts and the plurality of sensors to collect vital signs on different surfaces of a user's body parts. at least one processing device configured to contact with the plurality of electrodes and the plurality of sensors, the plurality of electrodes and the plurality of sensors configured to transmit the detected plurality of electrical potentials and the plurality of vital signs from the different surfaces of the user's body parts to the processing device. The processing device configured to store the plurality of electrical potentials and the plurality of vital signs and process the detected plurality of electrical potentials and the plurality of vital signs to assess a user's health and an end user device configured to receive the plurality of processed electrical potentials and the plurality of vital signs form the processing device through a network.