Abstract: A coating material and a medical device. The medical device having an end effector and a coating to cover the end effector. The coating having one or more of: a plurality of hollow particles; and projections and depressions.

Abstract: In a width dimension decrease portion forming a distal end of an ultrasonic probe, a width dimension decreases from a proximal direction toward a distal direction, so that a sectional area perpendicular to a longitudinal axis decreases from the proximal direction toward the distal direction. An intermediary portion continuous between a probe body portion and the width dimension decrease portion includes a width dimension increase portion in which the width dimension increases and a thickness dimension decreases from the proximal direction toward the distal direction at the same time. In the intermediary portion, the sectional area perpendicular to the longitudinal axis does not increase and does not decrease at a higher decrease rate than in the width dimension decrease portion toward the distal direction.

Abstract: An energy treatment device includes a probe in which a suction path is defined inside along a longitudinal axis to a distal surface portion. The probe includes a first protrusion protruding an outer peripheral distal end of an outer peripheral portion toward a first perpendicular direction perpendicular to the longitudinal axis and perpendicular to open/close directions of the jaw. The distal surface portion includes an inclined plane in which it goes toward a distal direction side as it goes from the first perpendicular direction toward a second perpendicular direction that is opposite to the first perpendicular direction, the inclined plane extending from a first end position, located to the first perpendicular direction side of a first root position of a first protrusion, to a second end position, located to the second perpendicular direction side of the suction path.

Abstract: An inspection probe includes a vibration transmission portion transmitting an ultrasonic vibration along a longitudinal axis, and a vibration damping portion continuous with a distal direction side of the vibration transmission portion. the vibration damping portion damps the ultrasonic vibration by causing vibration energy of the ultrasonic vibration to be lost and converting the lost vibration energy to heat energy in a state that the vibration damping portion vibrates in a manner to follow the vibration transmission portion. An index section of the inspection probe serves as an index indicating a conversion amount to the heat energy in the vibration damping portion.

Abstract: A treatment device includes a support section having conductivity, for which a separate position separated from the probe is switched to a support position at which the support section abuts the probe to support the probe when bent in a direction off of the central axis in accordance with a load which is applied to the probe, and subserviently moved with the vibration of the probe. The support section absorbs the vibration transmitted in the probe when the support section is at the support position.

Abstract: An ultrasonic probe includes a probe bend portion bending relative to a probe main body portion in a first bend direction and a second bend direction with a center of gravity being located on a first bend direction side with respect to a longitudinal axis. In the probe bend portion, a cross-sectional shape in a cross section perpendicular to a first perpendicular direction and a second perpendicular direction varies continuously along the first perpendicular direction and the second perpendicular direction with a cross-sectional center of gravity in the cross section perpendicular to the first perpendicular direction and the second perpendicular direction lying toward the second bend direction, as it is from the first perpendicular direction toward the second perpendicular direction.

Abstract: An ultrasonic treatment system includes a calculator calculating a relation between an amplitude of a vibrating body unit when an ultrasonic vibration is generated and an electric current to be supplied to an ultrasonic generator based on both an elapse of time and a number of thermal processes. The ultrasonic treatment system includes a current value setting section setting the electric current to an adaptive current value that brings the amplitude of the vibrating body unit to a target amplitude based on the relation between the amplitude of the vibrating body unit and the electric current calculated by the calculation section.

Abstract: An ultrasonic probe includes a probe body which includes an outer peripheral portion provided along a longitudinal axis, and a void defining surface defining a void, which is open to an outside along the longitudinal axis in at least one part of the outer peripheral portion, along the longitudinal axis. The void defining surface defines the void in the probe body from a first anti-node position of the ultrasonic vibrations to a second anti-node position of the ultrasonic vibrations different from the first anti-node position.

Abstract: In an ultrasonic probe, a curved portion gravity center of a probe curved portion located on a first perpendicular direction side with respect to a longitudinal axis. A boundary position between a probe relay portion and a probe main body portion is located on a distal side with respect to a reference antinode position which is located most distally among antinode positions of a longitudinal vibration located on a proximal direction side with respect to the probe curved portion. By a cross-section changing portion located at the boundary position, a cross section gravity center in a cross section of the probe relay portion perpendicular to the longitudinal axis is away from the longitudinal axis toward a second perpendicular direction opposite to the first perpendicular direction.

Abstract: A treatment device includes a probe having a treatment portion to treat a biological tissue by using the ultrasonic vibration generated in an ultrasonic transducer; an action portion being able to be close to and away from the treatment portion and including a pressing portion that presses the biological tissue to the treatment portion; and a vibration damping portion disposed in a part of the pressing portion in a state of facing the treatment portion, moving following the treatment portion to which the ultrasonic vibration is transmitted when abutting on the treatment portion in a state where the ultrasonic vibration is transmitted to the treatment portion, and prevented from being grinded by the treatment portion to which the ultrasonic vibration is transmitted.

Abstract: A surgical system has an ultrasound treatment instrument having an ultrasound transducer, a power supply apparatus to which the ultrasound treatment instrument is detachably connected, an energy supply section that supplies drive energy to the ultrasound transducer, a clock that measures a present time, a time updating section that outputs the present time, a storage section that stores a final updated time that is updated finally in the present time, and a number of times of use, a time period calculation section that calculates a non-connection time period of the ultrasound treatment instrument to the power supply apparatus, and a processing section that performs processing of generating an update signal that causes the number of times of use to be updated in accordance with a determination result with respect to the non-connection time period and a result of determination with respect to a parameter.

Abstract: A vibration generating unit includes a proximal side vibration transmitting section extended from a proximal end of the ultrasonic transducer toward a proximal direction. A proximal end of the proximal side vibration transmitting section is placed at a position apart from a reference antinode position toward the proximal direction by an extending dimension equal to an integral multiple of a half wavelength, when the reference antinode position is the closest to the ultrasonic transducer among antinode positions placed on the proximal direction side with respect to the ultrasonic transducer. The vibration generating unit includes an amplitude increasing section increasing an amplitude of the ultrasonic vibration transmitted toward the proximal direction in the proximal side vibration transmitting section.

Abstract: An inspection probe includes a vibration transmission portion transmitting an ultrasonic vibration along a longitudinal axis, and a vibration damping portion continuous with a distal direction side of the vibration transmission portion. the vibration damping portion damps the ultrasonic vibration by causing vibration energy of the ultrasonic vibration to be lost and converting the lost vibration energy to heat energy in a state that the vibration damping portion vibrates in a manner to follow the vibration transmission portion. An index section of the inspection probe serves as an index indicating a conversion amount to the heat energy in the vibration damping portion.

Abstract: In an ultrasonic probe, an insulation layer portion is formed on an outer surface of a probe main body portion. A first electrode portion provided on an outer surface of the insulation layer portion so that at least part of the first electrode portion is exposed to an outside in a treatment section, and at least part of a second electrode portion is exposed to the outside in the treatment section. The second electrode portion is electrically insulated from the first electrode portion by the insulation layer portion. The probe main body portion vibrates integrally with the insulation layer portion, the first electrode portion and the second electrode portion.

Abstract: An ultrasonic actuated unit includes an intermediary portion continuous with an ultrasonic transmitting portion or connected to the ultrasonic transmitting portion at a node position of a longitudinal vibration, and a noncontact vibrating portion extending in directions parallel to a longitudinal axis without contacting the ultrasonic transmitting portion, an imprecise vibration being transmitted to the noncontact vibrating portion from the ultrasonic transmitting portion via the intermediary portion. The ultrasonic actuated unit includes a vibration absorbing portion absorbing the imprecise vibration transmitted to the noncontact vibrating portion.

Abstract: An ultrasonic treatment apparatus includes a probe main body performing a vibration including a longitudinal vibration in a vibrating direction parallel to a longitudinal axis, and a distal treatment section positioned on a distal direction side with respect to a most distal node position positioned most distally among node positions of the longitudinal vibration in the probe main body. A probe side facing surface is provided in a position facing a jaw in a surface of the distal treatment section. A coating portion is made of a material having a higher heat resistance than the probe main body, and coats a surface facing a side opposite to the probe side facing surface in the probe main body.

Abstract: An ultrasonic transmitting unit includes a first vibrating section and second vibrating section vibrating at the same predetermined frequency with respect to each other. The ultrasonic transmitting unit includes a relay portion transmitting the ultrasonic vibration toward a first transmitting direction from the first vibrating section to the second vibrating section and positioned at a position corresponding to one of an antinode position of the vibration in the first vibrating section and different from an antinode position and a node position of the vibration in the second vibrating section, and a non-contact vibrating portion extending in a second vibrating section from the relay portion toward a second transmitting direction without contact with the first vibrating section.

Abstract: An ultrasonic probe transmits vibration along longitudinal axis from the proximal toward the distal end, including: first area including proximal and distal end portions, a center axis parallel to the longitudinal axis, the first area having a vibration antinode position at the distal end, wherein maximum distance from the center axis to an outer peripheral surface in radial direction orthogonal to the center axis is a first distance; a treatment section located on a distal end side's barycenter position displaced from the center axis; a second area located between the first area and treatment section continuous with the distal end of the first area and gravity center axis parallel to the center axis to pass through the barycenter, wherein maximum distance from the center axis to the outer surface in the radial direction orthogonal to the center axis is a second distance equal to or shorter than the first distance.

Abstract: An ultrasonic probe includes a probe bend portion bending relative to a probe main body portion in a first bend direction and a second bend direction with a center of gravity being located on a first bend direction side with respect to a longitudinal axis. In the probe bend portion, a cross-sectional shape in a cross section perpendicular to a first perpendicular direction and a second perpendicular direction varies continuously along the first perpendicular direction and the second perpendicular direction with a cross-sectional center of gravity in the cross section perpendicular to the first perpendicular direction and the second perpendicular direction lying toward the second bend direction, as it is from the first perpendicular direction toward the second perpendicular direction.

Abstract: An ultrasonic probe that transmits an ultrasonic vibration, generated in an ultrasonic vibrator, from a proximal end to a distal end so that the ultrasonic probe performs a longitudinal vibration in a vibrating direction. The ultrasonic probe including a probe body, a distal asymmetric portion, and a proximal side probe component. The distal asymmetric portion is asymmetric about an X-axis so that a center of gravity of the distal asymmetric portion is deviated from the X-axis and a first lateral vibration of the distal asymmetric portion is superposed on the longitudinal vibration of the ultrasonic probe. The proximal side probe component is bent relative to the probe body at a bending position so that a center of gravity of the proximal side component is deviated from the X-axis and a second lateral vibration of the proximal side component is superposed on the longitudinal vibration of the ultrasonic probe.