An electrically conductive plastic (ECP) material can be used to heat water in a reservoir of a respiratory humidifier to encourage heating and/or humidification of gases passing through the respiratory humidifier. The electrically conductive plastic material can at least in part overmould the base and/or walls of the chamber and/or the reservoir of the respiratory humidifier. The reservoir can also partially or fully be formed from the electrically conductive plastic material. Furthermore, the humidification system can be configured to create substantially equal or differential heating of water in the reservoir.

Guidewires useful for cooperating with catheters may be actively steered and/or provide adjustable stiffness. Angle or curvature of a guidewire, and/or flexural modulus of a guidewire, may be adjusted at one or more locations between ends thereof. Variable stiffness segments may include electrically operated compressible and/or extensible materials. Multiple tensile elements may terminate at different body elements to adjust angle or curvature at multiple locations. Multiple circumferentially and/or radially contractible fiber regions may be provided and distributed over a length of a guidewire. Adjustable flexure elements arranged in or along a guidewire may be electrically operated. A flexible core member may be centrally arranged in a tubular body. A flexible guide wire or track may cooperate with electrically operable motor units.

The invention comprises an apparatus and a method for operating a cardiac assist pump, comprising the steps of: (1) providing a cardiac monitor comprising: a cardiac output sensor including an activity sensor and at least two of: a pulse oximeter; an electrocardiogram meter; and a blood pressure monitor; (2) receiving time-varying cardiovascular input data, from the cardiac output sensor, related to a transient hemodynamic state of a cardiovascular system; (3) receiving and operating on time-varying activity input data, from the activity sensor, to generate cardiovascular state information; (4) sensing activity with the activity sensor to generate a target cardiovascular state; (5) repeating both the steps of receiving and operating to update the transient cardiovascular state information and the step of sensing to update the target cardiovascular state; and (6) directing the cardiac assist pump to adjust assisted blood flow, yielding the updated transient cardiovascular state, toward the target cardiovascular state.

Guidewires useful for cooperating with catheters may be actively steered and/or provide adjustable stiffness. Angle or curvature of a guidewire, and/or flexural modulus of a guidewire, may be adjusted at one or more locations between ends thereof. Variable stiffness segments may include electrically operated compressible and/or extensible materials. Multiple tensile elements may terminate at different body elements to adjust angle or curvature at multiple locations. Multiple circumferentially and/or radially contractible fiber regions may be provided and distributed over a length of a guidewire. Adjustable flexure elements arranged in or along a guidewire may be electrically operated. A flexible core member may be centrally arranged in a tubular body. A flexible guide wire or track may cooperate with electrically operable motor units.

An implantable blood pump includes a housing defining an inlet and an outlet and a flow path therethrough. A rotor is disposed within the housing. A stator is disposed within the housing, the stator being configured to rotate the rotor when a current is applied to the stator. A volute is disposed distal to the rotor proximate the outlet, the volute including a tongue composed of a piezoelectric material.

A patient interface assembly is configured to deliver pressurized gas to the patient's airways. The patient interface assembly includes a patient interface structure that is configured to sealingly engage the patient's face. The patient interface includes a receptacle. The patient interface assembly further includes headgear configured to support the patient interface structure on the patient's head. The headgear includes a clip that is receivable by the receptacle. The receptacle and the clip together form a multiple stage connection arrangement in which each of the multiple stages corresponds to an interlocked position of the clip in the receptacle. Each stage is associated with a corresponding range of headgear tension.

An implantable blood flow control system has an open passageway defined inside a radially inner wall, behind which is a closed passageway. The radially inner wall includes electroactive polymer actuator members for providing a variable flow restriction. The flow restriction has an undulating shape so that the volume of the closed passageway may remain constant during actuation of the electroactive polymer actuator members. In this way, the chamber behind the actuator members does not impede free movement of the actuator members. The undulating pattern presents no sharp edges, where blood coagulation could otherwise occur.

An implantable device includes an EAP actuator and a sensor. The sensor is configured to monitor a force external to the implantable device acting in a direction either with or counter to a direction of actuation of the actuator, and a controller is adapted to control the actuator to actuate at a moment when force counter to the direction of actuation is sensed to be at its lowest within a given time window or force with the direction of actuation is sensed to be at its highest within a given time window. In this way, actuation is effected at a moment of least resistance force, reducing the power needed for deployment of the actuator, and permitting actuation to occur even in conditions experiencing large variable forces.

A catheter comprises a hollow sheath, a guidewire extendable through the hollow sheath, where the guidewire comprises a controllably bendable tip portion, a hollow tubular intermediate portion connected to the tip portion, an electrical connection portion connected to the hollow tubular portion, at least a first wire extending through the hollow tubular portion and connected at a first end thereof to a first circumferential conductor and at a second end thereof to a surface of the tip end, and a power supply connector, therein the electrical connection portion is received in the power supply connector and a first terminal in the power supply connector contacts the first circumferential conductor.

A usage recording smart label and inhaler, and methods for detecting, verifying and recording actuation events of the inhaler, are disclosed. The usage recording smart label comprises a capacitive touch sensing plate to detect the presence of an activating body organ such as a hand or finger. The smart label, which may be in the form of a sticker or sticker-like, is attached to a grasping or actuation surface of the inhaler. The smart label may comprise text printed thereon, used as a replacement for an existing printed label. A usage recording method comprises (a) the usage recording smart label detecting an event of proximity of a finger for a given minimal time duration; (b) recording a timestamp of the event in memory of the smart label; (c) communicating stored timestamp data from the memory to an external device; the external device can be configured to display the actuation history.