Methods and systems may quantify how much contrast fluid is injected into a patient by a powered fluid injector. A controller of the powered fluid injector can receive a command from a user to begin dispensing contrast fluid. The controller may determine whether a hemodynamic pressure signal is present from a pressure sensor in fluidic connection with the vasculature of the patient. The powered fluid injector may dispense a quantity of contrast fluid in response to the command. The controller may add the quantity of contrast fluid to an injection quantity if the hemodynamic pressure signal is present just prior to and/or just after the quantity of contrast fluid is dispensed. The controller may refrain from adding the quantity of contrast fluid to the injection quantity if the hemodynamic pressure signal is not present just prior to and/or just after the quantity of contrast fluid is dispensed.

A treatment system includes a guide sheath, and a catheter provided with a pressure-controlled element. The pressure-control element preferably includes an expanded configuration adapted to extend across a small feeder vessel branching from the splenic vein. The pressure-control element is positioned with the feeder vessel, and a therapeutic agent is delivered under pressure directly into the feeder vessel, where it is forced to penetrate deep into tissue. Pressure responsive elements for monitoring intravascular pressure are also provided to time delivery of the therapeutic agent for maximum uptake by the target organ. Methods for treating tissues and organs via vascular pathways are provided.

A vascular catheter includes a catheter shaft having a distal end, a proximal end, a handle, at least two occlusion elements adapted to isolate a volume of the blood vessel, and an expandable balloon, between the two occlusion elements. The catheter shaft includes a first hole that opens into the expandable balloon. The catheter handle includes a first pumping device associated with a first path and with a first tank containing a first fluid, a second pumping device associated with a second path and with a second tank containing a second fluid, and a synchronization device connectable both to the first and to the second pumping devices.

There is provided a catheter for assessing cardiac function, the catheter comprising an elongate shaft extending from a proximal end to a distal end, where the shaft comprises a lumen for a guidewire and/or a saline flush. The catheter further comprises at least one electrode disposed on the shaft for sensing electrical signals in a bipolar or unipolar fashion and applying pacing to a patient's heart, at least one sensor disposed on the shaft for detecting an event relating to the rapid increase in the rate of pressure increase within the left ventricle of a patient; and communication means configured to transmit data received from the electrode(s) and the sensor(s).

A method of embolizing a tumor includes advancing a distal end of a device having a catheter body and an occlusion structure to a target tumor site within a blood vessel of a body. The occlusion structure is activated within the blood vessel, and a real time pressure measurement in the vascular space distal to the activated occlusion structure is monitored. The method further includes waiting for a pressure drop in the vascular space distal to the activated occlusion structure and for the pressure drop to cause a blood flow reversal in branch vessels antegrade to the occlusion. An embolic substance is injected from the distal end of the delivery device to permit the reversed blood flow to carry the embolic substance into the vasculature of the target tumor and the device is withdrawn from the body. Other catheter assemblies and methods of use are also disclosed.

Disclosed is an inter- and intra-catheter flow device for the management of vascular bleeding disorders that provide a liquid flow-pass between proximal and distal balloons for bridging the circulation between the upper and lower segments of a hemorrhaging artery or blood vessel, while blocking the blood flow to the hemorrhaging middle segment(s) of the artery or blood vessel between the two or more balloons. When only one balloon is inflated, these devices can create a pressure gradient between proximal or distal and middle segments of the artery or blood vessel. These devices are useful for controlling proximal artery blood pressure, preventing distal ischemia-reperfusion injury, identifying the bleeding location, controlling the bleeding, repairing and remodeling vascular structures, extending resuscitative endovascular balloon occlusion of the aorta (REBOA) use duration, and performing fluid resuscitation.

A urodynamic investigation apparatus for receipt of urine from a bladder is provided. The apparatus is characterized by a tubular element, first and second fittings, and a sleeve element, for select passage of urine there through, within the tubular element. The tubular element is characterized by opposing first and second end portions, and a port. The fittings are adapted to be received by the opposing end portions of the tubular element so as to delimit an apparatus chamber. The sleeve element, suspended between the fittings within the chamber, has collapsed and open configurations. The collapsed configuration is indicative of a no urine flow condition, and the open configuration indicative of a urine flow condition, with the sleeve element urine flow condition being a function of pressure applied to the chamber via the port of the tubular element.

An apparatus and methods to form a tissue scaffolding are provided. The apparatus may include a catheter shaft extending from a proximal end to a distal tip, a distal balloon positioned on the catheter shaft proximal to the distal tip, and a proximal balloon positioned on the catheter shaft proximal to the distal balloon. The apparatus may further include an intermediate balloon positioned on a distal segment of the catheter shaft proximal to the distal balloon and distal to the proximal balloon. The intermediate balloon and the distal segment each include a translucent material. A light fiber may extend through the distal segment. A first lumen and a second lumen may be arranged in the catheter shaft, the first lumen comprising a first port located between the distal balloon and the intermediate balloon, and the second lumen comprising a second port located between the intermediate balloon and the proximal balloon.

A method of assessing bladder storage anomalies via utilization of an indwelling urinary drainage catheter is provided. A urodynamic assessment assembly is provided, the assembly characterized by a pressure sensor for vesical pressure measurement, a processor/controller for receiving, processing and/or displaying select urodynamic patient parameters comprising sensed/monitored pressure data, and a catheter balloon adaptor for operably uniting the pressure sensor of the urodynamic assessment assembly to a balloon inflation valve of the indwelling urinary drainage catheter, the indwelling urinary drainage catheter operably linked with the urodynamic assessment assembly. Vesical pressure is sensed via the vesical pressure sensor during a bladder emptying event, the bladder emptying event characterized by an application of variable resistance to fluid flow from the bladder via the indwelling urinary drainage catheter with vesical pressure/outlet resistance/flow rate relationships established based upon sensed vesical pressure values.

The present disclosure relates to an intravascular catheter with sensor systems that can measure intravascular pressure using MEMS sensors. Devices of the present disclosure can also be used to administer intravenous therapies, such as drug delivery or hemodialysis. Exemplary devices can be equipped with multiple MEMS sensors to measure pressure in multiple locations throughout the cardiovascular system. The intravascular catheter can communicate with a receiver and monitor to display sensor data.