Effect of magnitude and direction of force on laryngeal abduction: implications for the nerve-muscle pedicle graft technique.

REASONS FOR PERFORMING STUDY: The nerve-muscle pedicle graft technique is a treatment for recurrent laryngeal neuropathy (RLN), but the optimal placement of the pedicles within the cricoarytenoideus dorsalis (CAD) muscle is unknown. HYPOTHESIS: The magnitude and direction of force placed on the muscular process of the left arytenoid cartilage affects the magnitude of laryngeal abduction. METHODS: Five larynges were harvested from cadavers. Using increments of 0.98 N, a dead-weight force generator applied a force of 0-14.7 N for 1 min each to the left muscular process at 0, 10, 20, 30, 40, 50, 60 and 70 degrees angles. The rima glottis was photographed digitally 1 min after each force had been applied. Distances between biomarkers (Lines 1-4) and right to left angle quotient (RLQ) were used to assess the degree of left arytenoid abduction. RESULTS: Increasing force from 0-14.7 N progressively and significantly increased the length of all lines and RLQ, indicating abduction. Furthermore, there was a significant interaction between force and angles. Applying forces of 7.84 N or greater (Lines 2-4 and RLQ) or 11.76 N or greater (Line 1) at angles 0, 10, 20 and 30 degrees resulted in significantly greater abduction than applying the same forces at 40, 50, 60 and 70 degrees. Angles of 0-30 degrees correspond with the direction of pull exerted by the lateral compartment of the CAD muscle. CONCLUSION: In RLN, nerve-muscle pedicle grafts should be placed preferentially in the lateral rather than in the medial compartment of the CAD muscle. POTENTIAL RELEVANCE: The information presented can be used to assist surgeons in the planning and application of the nerve-muscle pedicle graft procedure.

A piezo-powered floating-gate sensor array for long-term fatigue monitoring in biomechanical implants.

Measurement of the cumulative loading statistics experienced by an implant is essential for prediction of long-term fatigue failure. However, the total power that can be harvested using typical in-vivo strain levels is less than 1 muW. In this paper, we present a novel method for long-term, battery-less fatigue monitoring by integrating piezoelectric transduction with hot-electron injection on a floating-gate transistor array. Measured results from a fabricated prototype in a 0.5-mum CMOS process demonstrate that the array can sense, compute, and store loading statistics for over 70000 stress-strain cycles which can be extended to beyond 107 cycles. The measured response also shows excellent agreement with a theoretical model and the nominal power dissipation of the array has been measured to be less than 800 nW.