Handheld steering devices for use with intravascular devices and associated systems and methods are disclosed. In some instances, the handheld steering device includes a housing sized and shaped for grasping by a hand of a user, the housing including a proximal portion and a distal portion, wherein the distal portion includes an opening sized and shaped to receive an intravascular device; an adaptor positioned within the opening of the housing, the adaptor including a bore sized and shaped to allow a proximal end of the intravascular device to pass therethrough; a steering controller coupled to the housing; and an actuator positioned within the housing and in communication with the steering controller, the actuator interfacing with the proximal end of the intravascular device based on inputs to the steering controller to steer a distal end of the intravascular device. Associated systems and methods are also disclosed.

A flexible, passive pressure sensor includes three LC tank circuits. The first LC tank circuit is a pressure sensing LC tank circuit, having a capacitance that varies in response to changes in environmental pressure. The second and third LC tank circuits are reference LC tank circuits, having capacitances that are relatively constant over changes in environmental pressure. A measurement tool measures the resonant frequencies of the three LC tank circuits and then computes a pressure measurement that accounts for changes in resonant frequencies in the LC tank circuits due to environmental effects and deforming.

A flexible, passive pressure sensor includes three LC tank circuits. The first LC tank circuit is a pressure sensing LC tank circuit, having a capacitance that varies in response to changes in environmental pressure. The second and third LC tank circuits are reference LC tank circuits, having capacitances that are relatively constant over changes in environmental pressure. A measurement tool measures the resonant frequencies of the three LC tank circuits and then computes a pressure measurement that accounts for changes in resonant frequencies in the LC tank circuits due to environmental effects and deforming.

Guidewires having conductive elements are described where in one variation, the guidewire may be formed by disposing an insulative layer upon a surface of the guidewire core, and printing one or more conductive traces directly upon a surface of the insulative layer.

Guidewires having conductive elements are described where in one variation, the guidewire may be formed by disposing an insulative layer upon a surface of the guidewire core, and printing one or more conductive traces directly upon a surface of the insulative layer.

Handheld steering devices for use with intravascular devices and associated systems and methods are disclosed. In some instances, the handheld steering device includes a housing sized and shaped for grasping by a hand of a user, the housing including a proximal portion and a distal portion, wherein the distal portion includes an opening sized and shaped to receive an intravascular device; an adaptor positioned within the opening of the housing, the adaptor including a bore sized and shaped to allow a proximal end of the intravascular device to pass therethrough; a steering controller coupled to the housing; and an actuator positioned within the housing and in communication with the steering controller, the actuator interfacing with the proximal end of the intravascular device based on inputs to the steering controller to steer a distal end of the intravascular device. Associated systems and methods are also disclosed.

Handheld steering devices for use with intravascular devices and associated systems and methods are disclosed. In some instances, the handheld steering device includes a housing sized and shaped for grasping by a hand of a user, the housing including a proximal portion and a distal portion, wherein the distal portion includes an opening sized and shaped to receive an intravascular device; an adaptor positioned within the opening of the housing, the adaptor including a bore sized and shaped to allow a proximal end of the intravascular device to pass therethrough; a steering controller coupled to the housing; and an actuator positioned within the housing and in communication with the steering controller, the actuator interfacing with the proximal end of the intravascular device based on inputs to the steering controller to steer a distal end of the intravascular device. Associated systems and methods are also disclosed.

This disclosure provides systems and methods for measuring fluid flow in a vasculature system of a patient. Some systems may include an injection system configured to inject a bolus of fluid into a vessel of a patient. Some systems may include a measurement engine configured to monitor the bolus of fluid in the vessel using measurement data generated by an intravascular measuring device. The measurement engine may determine a travel distance of the bolus of fluid and an elapsed time during which the bolus of fluid traversed the travel distance based on the measurement data. A fluid flow rate (e.g., velocity, volumetric flow) of the vessel may be calculated using the travel distance and the elapsed time.

This disclosure provides systems and methods for measuring fluid flow in a vasculature system of a patient. Some systems may include an injection system configured to inject a bolus of fluid into a vessel of a patient. Some systems may include a measurement engine configured to monitor the bolus of fluid in the vessel using measurement data generated by an intravascular measuring device. The measurement engine may determine a travel distance of the bolus of fluid and an elapsed time during which the bolus of fluid traversed the travel distance based on the measurement data. A fluid flow rate (e.g., velocity, volumetric flow) of the vessel may be calculated using the travel distance and the elapsed time.

A coronary artery load detection method includes: (S1) obtaining the cross-sectional area of a reference cavity, and separately obtaining voltage values of a primary device at a location corresponding to the cross-sectional area of the reference cavity in a low frequency state and a high frequency state; (S2) separately obtaining voltage values of the primary device at the location of a bottom end or a top end of a to-be-detected object in the low frequency state and the high frequency state under the same current; (S3) driving the primary device to move at a constant speed, and obtaining a voltage value of the primary device during the movement in the low frequency state under the same current; and (S4) obtaining the cross-sectional area of each location of the to-be-detected object according to a preset fixed current value, the cross-sectional area of the cavity, and the obtained voltage values.