Provided herein are methods of making and using storage-stable protein-coated articles that retain activity after drying. Also provided herein are kits comprising storage-stable protein-coated articles that retain activity after drying.

A leadless pacing device may include a housing having a proximal end and a distal end, and one or more electrodes supported by the housing. The housing may include a body portion and a header. A distal extension may extend distally from the header of the housing, the distal extension including one or more electrodes. The header may include a guide wire port and a guide wire lumen may extend from the guide wire port through the header of the housing and through the distal extension. A fixation member may extend from the header of the housing. The header may be formed from an over mold process.

A medical device system has a medical device interface configured to download data from an implanted medical device. Memory stores electrode location identification rules and display definitions. Each of the display definitions correspond to possible electrode placement locations of the implanted medical device. Processing circuitry is configured to compare the downloaded data from the implanted medical device to the electrode location identification rules to identify one or more actual electrode placement locations of the possible electrode placement locations of the implanted medical device. A user output interface is in communication with the processing circuitry. The processing circuitry is configured to cause the output to display the one or more actual electrode placement locations.

The disclosure relates to a multipolar, detection/stimulation endovascular lead intended to be implanted in the coronary venous network. The lead comprises a lead body with in proximal portion a connector to a cardiac pacemaker/defibrillator generator, and in a distal portion a first branch and a second branch extending beyond a bifurcation. The distal ends of the branches are free ends carrying an array of electrodes connected to the connector. Each of the branches comprises at its free end an outlet in the distal direction, able to receive an implantation guide wire inserted therein and to guide the implantation guide wire in an axial direction parallel to the main axis of the lead body.

The adoption of His Bundle Pacing (HBP) has been hindered by the procedural difficulty of achieving good lead position without causing cardiac damage or perforation. The procedural success rates are much lower when compared to traditional right ventricle (RV) pacing procedures due to the difficulty in mapping the His potential with the exposed helix and maintaining position while the pacing helix is fixated. The use of multidirectional balloon tipped catheter system that includes a catheter body with curls and flexion points and anchor balloon mounted to a distal end of the catheter body increases positional precision and an improved procedural success rate when compared to the conventional system.

In one embodiment, a medical procedure system includes a probe for insertion into a chamber of a heart of a living subject, and including a first electrode to apply a sequence of pacing pulses at a position in the chamber, a second electrode to sense an electrical activation signal responsively to electrical activations induced by capture of the pacing pulses in a myocardium of the chamber, a display, and processing circuitry to evaluate a successful acquisition by the second electrode of the induced electrical activations responsively to the electrical activation signal, the successful acquisition being indicative of a successful capture of the pacing pulses by the myocardium, compute a capture grade responsively to the evaluation of the successful acquisition of the induced electrical activations, the capture grade being indicative of a count of the induced electrical activations evaluated as being successfully acquired, and render the capture grade to the display.

A system for ablating target tissue includes an elongate anchor shaft, a radially expandable member coupled to the elongate anchor shaft, and an elongate ablation shaft. The radially expandable member has an expanded configuration for engagement with the target tissue to facilitate anchoring. The elongate ablation shaft may be slidably disposed in the elongate anchor shaft, and the distal portion of the elongate ablation shaft is steerable. An energy source is coupled to the elongate ablation shaft and is configured to deliver energy to the target tissue and ablate the target tissue. Actuation of the elongate ablation shaft directs the energy to the target tissue to form a desired ablation path in the target tissue.

Methods of treating acute heart failure in a patient in need thereof. Methods include inserting a therapy delivery device into a pulmonary artery of the patient and applying a therapy signal to autonomic cardiopulmonary fibers surrounding the pulmonary artery. The therapy signal affects heart contractility more than heart rate. Specifically, the application of the therapy signal increases heart contractility and treats the acute heart failure in the patient. The therapy signal can include electrical or chemical modulation.

A method of pacing a His bundle of a patient heart using a stimulation system including a memory, a pulse generator, a stimulating electrode and at least one sensing electrode includes applying a plurality of impulses through the stimulating electrode to induce a plurality of responses from the patient heart. Each impulse of the plurality of impulses is delivered at a different impulse energy corresponding to a respective output setting of the stimulation system. The response characteristics for each of the plurality of responses are measured and each impulse is assigned a classification based on whether the respective response characteristics indicate capture of one or both of the His bundle and a ventricle of the patient heart. The output setting and classification for each impulse is then stored in the memory.

The embodiments described herein relate to a self-positioning, quick-deployment low profile transvenous electrode system for sequentially pacing both the atrium and ventricle of the heart in the dual chamber mode, and methods for deploying the same.