Abstract: An injection syringe device includes a tubular barrel, a plunger, and a piezo-chromic pressure indicator. The plunger has a distal tip and is designed to fit tightly and to reciprocate within the tubular barrel. Pulling the plunger out of the tubular barrel draws a liquid or a gas inside the tubular barrel in a space between the distal tip and a distal end of the tubular barrel and pushing the plunger into the tubular barrel expels the liquid or gas from the space. The piezo-chromic pressure indicator changes color to indicate pressure applied on the liquid or gas being expelled and/or target tissue being injected with the liquid or gas.

Abstract: A positionable, direct-injection catheter that can access a specific region of the heart or other organ. The catheter is provided with one or two needle shafts, which may be located within respective sheaths that extend axially along the interior of the lumen of a main catheter shaft. Each needle shaft carries, at a distal end thereof a penetrable element that is normally retracted, but is subsequently deployed by a trigger. Each extended needle is curved to enter the organ wall in a flattened trajectory that both reduces the chance of puncture through the wall and anchors the needles into the wall during injection. A plurality of apertures which provide for more complete agent delivery rapidly, while maintaining a low delivery velocity to avoid the problems caused by high velocity delivery. The needles are typically arranged to exit the tip at contralateral orientations relative to each other.

Abstract: A positionable, direct-injection catheter that can access a specific region of the heart or other organ. The catheter is provided with one or two needle shafts, which may be located within respective sheaths that extend axially along the interior of the lumen of a main catheter shaft. Each needle shaft carries, at a distal end thereof a penetrable element or “needle” that is normally retracted within the distal tip of the main shaft during travel to the target organ, but is subsequently deployed by action of a handle-mounted trigger mechanism to extend the needles into the organ's wall. Each extended needle is curved to relative to the shaft's axis to enter the organ wall in a flattened trajectory that both reduces the chance of puncture through the wall and anchors the needles into the wall during injection (for reduced chance of pullout under pressure).

Abstract: An improved rappelling system for raising or lowering a person or an object to or from a stationary or moving elevated point includes at least one cable for supporting a person or an object, a motor attached to the elevated point and coupled to the cable so that the motor propels the cable up or down and thereby raises or lower the person or object, respectively, a controller/processor for controlling the motion of the motor and at least one sensor attached to the elevated point and coupled to the controller/processor. The sensor measures the distance of the elevated point from a target area located at a lower point than the elevated point and continuously sends a feedback signal to the controller/processor. The feedback signal is used to calculate and adjust in real-time motor control parameters that determine speed and landing location of the person or object relative to the target area.

Abstract: A positionable, direct-injection catheter that can access a specific region of the heart or other organ. The catheter is provided with one or two needle shafts, which may be located within respective sheaths that extend axially along the interior of the lumen of a main catheter shaft. Each needle shaft carries, at a distal end thereof a penetrable element or “needle” that is normally retracted within the distal tip of the main shaft during travel to the target organ, but is subsequently deployed by action of a handle-mounted trigger mechanism to extend the needles into the organ's wall. Each extended needle is curved to relative to the shaft's axis to enter the organ wall in a flattened trajectory that both reduces the chance of puncture through the wall and anchors the needles into the wall during injection (for reduced chance of pullout under pressure).

Abstract: A pacemaker system 100 includes a pacemaker device 160, cardiac leads 120 and 150, guide catheter 110, an ultrasound transmitter 133 and an ultrasound receiver 130. Cardiac lead 150 is implanted in the right atrium (RA) 82 and includes an electrode 152 at its distal end that is actively fixed into location 102 of the right atrium 82. Electrode 152 is used for pacing of the RA. Cardiac lead 120 is implanted in the right ventricle (RV) 84 and includes two separate electrodes. A first electrode 140 is actively fixed into location 101 close to the apex 98 of the right ventricle 84 and is used for pacing, sensing and/or defibrillating of the RV. A second electrode 130 perforates the apex 98 of the right ventricle 84 and is actively fixed into the apex 99 of the left ventricle (LV) 86. Electrode 130 is used for pacing, sensing and/or defibrillating of the LV.

Abstract: This invention overcomes the disadvantages of the prior art by providing a positionable, direct-injection catheters that can access a specific region of the heart or other organ. The catheter is provided with one or two needle shafts, which may be located within respective sheaths that extend axially along the interior of the lumen of a main catheter shaft. Each needle shaft carries, at a distal end thereof a penetrable element or “needle” that is normally retracted within the distal tip of the main shaft during travel to the target organ, but is subsequently deployed by action of a handle-mounted trigger mechanism to extend the needles into the organ's wall. Each extended needle is curved to relative to the shaft's axis to enter the organ wall in a flattened trajectory that both reduces the chance of puncture through the wall and anchors the needles into the wall during injection (for reduced chance of pullout under pressure).

Abstract: An improved rappelling system for raising or lowering a person or an object to or from a stationary or moving elevated point includes at least one cable for supporting a person or an object, a motor attached to the elevated point and coupled to the cable so that the motor propels the cable up or down and thereby raises or lower the person or object, respectively, a controller/processor for controlling the motion of the motor and at least one sensor attached to the elevated point and coupled to the controller/processor. The sensor measures the distance of the elevated point from a target area located at a lower point than the elevated point and continuously sends a feedback signal to the controller/processor. The feedback signal is used to calculate and adjust in real-time motor control parameters that determine speed and landing location of the person or object relative to the target area.