Reverse atrial electrical remodeling induced by cardiac resynchronization therapy.

PURPOSE: Cardiac resynchronization therapy (CRT) has been shown to improve left atrial function; however the effect on reverse electrical remodeling has been poorly evaluated. We hypothesized that CRT might induce reverse atrial electrical remodeling manifesting in the surface ECG as a shortening in P-wave duration. METHODS: Patients with CRT and more than 92% biventricular pacing at minimum follow-up of 1 year were included in the analysis. Those with prior history of atrial fibrillation (AF) were excluded. Data were recorded for clinical, echocardiographic and ECG variables prior to implant and at least 12 months post implantation. Semiautomatic calipers and scanned ECGs at 300 DPI maximized × 8 were used to measure P-wave duration and diagnose advanced interatrial block (aIAB) during sinus rhythm. The occurrence of AF was assessed through analyses of intracardiac electrograms and clinical presentations. RESULTS: 41 patients were included in the study with mean age of 67.4 ±9.6 years, 71% were male, left atrial diameter 41.1 ± 8.5 mm and LV EF 28.5 ± 6.5%. Over a mean follow up of 55 months, a significant reduction in P-wave duration (142.7 ms vs. 133.1 ms; p < 0.001) was noted. The presence of aIAB was significantly reduced (36% vs. 17%; p = 0.03). The incidence of new onset AF was 36%. Time to AF onset after CRT implantation was not influenced by a reduction in P-wave duration. CONCLUSION: CRT induces atrial reverse electrical remodeling manifested as a reduction in P-wave duration. Larger studies are needed to determine the impact on AF incidence after CRT implantation.

Low profile halo head fixation in non-human primates.

BACKGROUND: We present a new halo technique for head fixation of non-human primates during electrophysiological recording experiments. Our aim was to build on previous halo designs in order to create a simple low profile system that provided long-term stability. NEW METHOD: Our design incorporates sharp skull pins that are directly threaded through a low set halo frame and are seated into implanted titanium foot plates on the skull. The inwardly directed skull pins provide an easily calibrated force against the skull. RESULTS: This device allowed for head fixation within 1 week after implantation surgery. The low-profile design maximized the area of the skull available and potential implant orientations for electrophysiological experiments. It was easily maintained and was stable in 2 animals for the 6-8 months of testing. The quality of single unit neural recordings collected while using this device to head fix was indistinguishable from traditional head-post fixation. The foot plates used in this system did not result in significant MRI distortion in the location of deep brain targets (∼0.5mm) of a 3D printed phantom skull. COMPARISON WITH EXISTING METHOD(S): The low profile design of this halo design allows greater access to the majority of the frontal, parietal, and occipital skull. It has fewer parts and can hold larger animals than previous halo designs. CONCLUSIONS: Given the stability, simplicity, immediate usability, and low profile of our head fixation device, we propose that it is a practical and useful means for performing electrophysiological recording experiments on non-human primates.