Abstract
The optical properties of tissue change during thermal ablation. Multi-modal methods such as acousto-optic (AO) and photo-acoustic (PA) imaging may provide a real-time, direct measure of lesion formation. Baseline changes in optical properties have been previously measured over limited ranges of thermal dose for tissues exposed to a temperature-controlled water bath, however, there is scant data for optical properties of lesions created by HIFU. In this work, the optical scattering and absorption coefficients from 400–1300 nm of excised chicken breast exposed to HIFU were measured using an integrating sphere spectrophotometric technique. HIFU-induced spatiotemporal temperature elevations were measured using an infrared camera and used to calculate the thermal dose delivered to a localized region of tissue. Results obtained over a range of thermal dose spanning 9 orders of magnitude show that the reduced scattering coefficient increases for HIFU exposures exceeding a threshold thermal dose of CEM43 = 600 ± 81 cumulative equivalent minutes. HIFU-induced thermal damage results in changes in scattering over all optical wavelengths, with a 2.5-fold increase for thermal lesions exceeding 70 °C. The tissue absorption coefficient was also found to increase for thermally lesioned tissue, however, the magnitude was strongly dependent on the optical wavelength and there was substantial sample-to-sample variability, such that the existence of a threshold thermal dose could not be determined. Therapeutic windows, where the optical penetration depth is expected to be greatest, were identified in the near infrared regime centered near 900 nm and 1100 nm. These data motivate further research to improve the real-time AO and PA sensing of lesion formation during HIFU therapy as an alternative to thermometry.
Highlights
Tissue heating and thermal ablation using high intensity focused ultrasound (HIFU) is being adopted in the clinic as a non-invasive surgical technique for treatment of solid tumors in cancer (Hsiao et al 2016) and nonmalignant ablative therapies (Chen et al 2017, Lang et al 2017)
Baseline changes in optical properties have been previously measured over limited ranges of thermal dose for tissues exposed to a temperature-controlled water bath, there is scant data for optical properties of lesions created by HIFU
The data obtained here comprise the first study of optical properties in chicken breast tissue over a wide range of optical wavelengths under the effect of HIFU-induced thermal coagulation
Summary
Tissue heating and thermal ablation using high intensity focused ultrasound (HIFU) is being adopted in the clinic as a non-invasive surgical technique for treatment of solid tumors in cancer (Hsiao et al 2016) and nonmalignant ablative therapies (Chen et al 2017, Lang et al 2017). In HIFU, high amplitude ultrasound waves are focused to a target location and the absorption of acoustic energy elevates the tissue temperature, resulting in thermal ablation of a cigar-shape region of tissue typically 1–3 mm in diameter and 1–2 cm in length. Magnetic resonance (MR) imaging is considered the ‘gold standard’ for guiding and monitoring HIFU by thermometry (Kim 2015, Zhu et al 2017) and is able to accurately estimate the temperature changes in tissue, it does not directly measure absolute temperature or lesion formation and a thermal dose model is needed to infer tissue ablation based on spatial maps of relative temperature increase due to HIFU (McDannold 2005, Rivens et al 2007). MR-based elastography methods such as acoustic radiation force imaging (MR-ARFI) may be useful for monitoring irreversible changes in tissue elasticity due to HIFU treatment but have so far only been implemented off-line (Vappou et al 2018). Drawbacks of MRI techniques include the limited temporal and spatial resolution, the requirement that the ultrasound equipment be MR-compatible, and the high cost of MRI systems
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