Assembly process of wireless powered pacemaker.

<p>(a) Platinum wire is attached to the circuit board, wound together, and coiled with a 0.5 cc syringe. (b) A bead of Silastic is placed on a piece of parafilm(1). The device is placed on the bead(2), coated with an additional layer of Silastic(3), and topped with a piece of gas permeable film(4). (c) Final product. (d) Artistic rendering of external transmitter interacting with abdominally implanted receiver in mouse.</p

Bench top and <i>in vivo</i> testing of battery powered pacemaker.

<p>(a) Current (blue) and voltage (gray) traces from the pacing catheter. (b) Frequency Response Analysis of distal and proximal pacing catheter electrodes (c) Lead II ECG recording in a mouse heart during sinus rhythm and right ventricular pacing by the battery-powered pacemaker over 5 days.</p

<i>In vivo</i> testing of wireless pacemaker.

<p>(a) Lead II ECG during normal sinus rhythm (top) and during LV apical pacing (bottom). (b) Pacing pulse width threshold of wireless device over 30 days for all mice with stable capture. Solid red line shows linear regression on mean pulse width thresholds. Dashed black lines show 95% confidence interval bounds for the regression.</p

Comparison of battery-powered and wireless-powered pacemakers.

<p>Comparison of battery-powered and wireless-powered pacemakers.</p

Layout of the wireless-powered pacemaker.

<p>(a) Circuit layout of transmitter (top) and receiver (bottom). (b) Pulsed input into transmitter from pulse generator. (c) Output from transmitter. (d) Uncapped output from receiver. (e) Capped output from receiver. (f) Receiver output decreases minimally up to 5 cm from the transmitter coil. See text for further details.</p

Parts list for wireless transmitter and receiver circuits.

<p>Parts list for wireless transmitter and receiver circuits.</p