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Abstract

Background

The objectives of this pilot study were to (1) determine whether bipolar radiofrequency plasma-mediated ablation (PMA) can efficiently remove nasal septal cartilage and (2) calculate the ablation rate as a function of device power, probe force, and translation velocity using ex vivo porcine tissue.

Methods

Specimens were secured to a linear translation stage and were subjected to varying translation velocities (4, 7, and 12 cm/s), probe forces (140, 200, and 225 g), and bipolar radiofrequency generator (Coblator ENTec power settings, 38–58, 77–115, and 129–193 Watts root mean squared. Specimen mass loss and depth of ablation were measured using an analytic balance and dissection microscope, respectively.

Results

Visual and microscopic inspection revealed little char. Mass loss increased with decreasing translation velocity and increasing generator setting. Increasing probe force also influenced mass loss and increased crater depth. Depth of ablation did not correlate with translation velocity or generator setting.

Conclusion

PMA effectively ablates nasal septal cartilage and may be able to reduce or contour cartilaginous deformities and framework structures in the head and neck.

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Bipolar Radiofrequency Plasma-Mediated Ablation of Porcine Nasal Septal Cartilage: A Pilot Investigation

Abstract

Background

Methods

Results

Conclusion

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References