Acute and Chronic Performance Evaluation of a Novel Epicardial Pacing Lead Placed by Percutaneous Subxiphoid Approach in a Canine Model

John, Roy M.; Morgan, Kevin; Brennecke, Lucas H.; Benser, Michael E.; Jaı̈s, Pierre

doi:10.1161/circep.114.002076

Cited by 10 publications

(4 citation statements)

References 22 publications

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“…18 John et al developed and implanted an intrapericardial pacing leads in 12 dogs using a novel passive fixation lead system. 19 Similarly, Clark et al demonstrated feasibility of implanting a defibrillator lead with a “side biting” tine through a pericardial sheath. 20,21 An additional approach towards extravascular pacing demonstrated successful ventricular capture using a substernal electrode.…”

Section: Discussionmentioning

confidence: 99%

Minimally Invasive Implantation of a Micropacemaker Into the Pericardial Space

Bar‐Cohen

Silka

Hill

et al. 2018

Circ: Arrhythmia and Electrophysiology

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Background Permanent cardiac pacemakers require invasive procedures with complications often related to long pacemaker leads. We are developing a percutaneous pacemaker for implantation of an entire pacing system into the pericardial space. Methods Percutaneous micropacemaker implantations were performed in six pigs (27.4 – 34.1 kg) using subxyphoid access to the pericardial space. Modifications in the implantation methods and hardware were made after each experiment as the insertion method was optimized. In the first 5 animals, non-functional pacemaker devices were studied. In the final animal, a functional pacemaker was implanted. Results Successful placement of the entire non-functional pacing system into the pericardial space was demonstrated in 2 of the first 5 animals, and successful implantation and capture was achieved using a functional system in the last animal. A sheath was developed that allows retractable features to secure positioning within the pericardial space. In addition, a miniaturized camera with fiberoptic illumination allowed visualization of the implantation site prior to electrode insertion into myocardium. All animals studied during follow-up survived without symptoms after the initial post-operative period. Conclusions A novel micropacemaker system allows cardiac pacing without entering the vascular space nor surgical exposure of the heart. This pericardial pacemaker system may be an option for a large number of patients currently requiring transvenous pacemakers but is particularly relevant for patients with restricted vascular access, young children or those with congenital heart disease who require epicardial access.

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Section: Discussionmentioning

confidence: 99%

Minimally Invasive Implantation of a Micropacemaker Into the Pericardial Space

Bar‐Cohen

Silka

Hill

et al. 2018

Circ: Arrhythmia and Electrophysiology

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“…This innovative pacemaker concept was feasible, yet 1 out of 6 piglets developed a pneumothorax during implantation [53]. Thirdly, John et al described an effective percutaneous placement of an intrapericardial pacemaker lead by using a subxiphoid approach in a pre-clinical setting [54]. Fourthly, the SPACE study established the feasibility of delivering epicardial pacing therapy within the substernal anterior mediastinum in 18 out of 26 patients [55].…”

Section: Expert Opinionmentioning

confidence: 99%

Leadless cardiac pacing systems: current status and future prospects

Beurskens

Breeman

Dasselaar

et al. 2019

Expert Review of Medical Devices

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Introduction: Permanent transvenous pacemaker therapy is an essential management option in patients with symptomatic bradyarrhythmias, but harbors a concomitant risk of serious complications. As most complications are lead-or pocket-related, intracardiac leadless pacemaker therapy has the potential to positively impact patient outcome. Since the first leadless pacemaker implant in 2012, many studies have been conducted to evaluate the effectiveness, safety, and applicability of this novel pacing approach.Areas covered: This review will cover the current status of leadless pacemaker technology. Available safety and efficacy outcomes, current area of indication, and end-of-life management will be evaluated. Furthermore, future perspectives for clinical practice and new pacing modalities are discussed. Expert opinion: The first-generation leadless pacemakers are a promising innovation that provide safe and efficient single-chamber pacing therapy without the use of transvenous pacemaker leads. Yet, broad implementation of this technology is hampered by limitations of the current leadless devices, such as end-of-life management and its single-chamber pacing indication. Further innovations such as leadless dual-chamber pacing therapy, leadless cardiac synchronization therapy, energy-harvesting leadless pacemakers, communicating leadless pacemakers with subcutaneous implantable cardiac defibrillators, and minimally invasive completely extracardiac pacemakers are currently being developed that have the potential to become major game changers in pacing therapy.

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“…Introduction and discussions regarding some existing medical device animal models include: the biocompatibility testing of novel materials (e.g., polymers) in the subcutaneous, bone, or muscle tissues of the rat or rabbit (ISO 10993-6); cardiovascular and other devices in the swine and/or sheep (Swindle et al 2012; Sartoretto et al 2016); skin wound healing in swine (Seaton, Hocking, and Gibran 2015); critical defect bone healing in sheep, rabbits, and rats (Cooper et al 2010; Wancket 2015); and electrophysiology devices in canine (John et al 2015).…”

Section: Animal Model Developmentmentioning

confidence: 99%

An Overview on the Considerations for the Planning of Nonclinical Necropsies for Medical Device Studies

Stanley¹,

Keating²,

Souci³

2019

Toxicol Pathol

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The terminal collection and histological processing of medical devices is an expensive, labor-, and material-intensive endeavor, which requires adequate experience, innovation, and preparation for success. It is also an exciting endeavor that continually challenges, intellectually engages, and improves the skills and knowledge of the pathologist. Awareness of the importance of the medical device pathologist's involvement, communication, and oversight throughout the development, implementation, and execution of a nonclinical assessment of a medical device is in the best interest of the test facility, the histopathology laboratory, the pathologist, the sponsor, and, ultimately, the patients. This article serves to present as a primer of key considerations for the approach and conduct of "nontoxicological" studies, defined as studies involving animal models of deployment or implantation of medical devices as well as surgical animal models.

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Acute and Chronic Performance Evaluation of a Novel Epicardial Pacing Lead Placed by Percutaneous Subxiphoid Approach in a Canine Model

Cited by 10 publications

References 22 publications

Minimally Invasive Implantation of a Micropacemaker Into the Pericardial Space

Minimally Invasive Implantation of a Micropacemaker Into the Pericardial Space

Leadless cardiac pacing systems: current status and future prospects

An Overview on the Considerations for the Planning of Nonclinical Necropsies for Medical Device Studies

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