Abstract
Toward developing a new method for restoring tissue viscoelasticity in scarred vocal folds, we previously proposed a method to localize biomaterials within subepithelial voids ablated using ultrafast laser pulses. The clinical implementation of this method necessitates the quantification of the laser parameters for ablating scarred tissue. Here, we present a comprehensive study of these parameters including ablation threshold and bubble lifetime in healthy and scarred tissues. We also present a new method for extracting tissue-specific ablation threshold and scattering lengths of different tissue layers. This method involves finding the ablation threshold at multiple depths and solving the equations based on Beer's law of light attenuation for each depth to estimate the unknown parameters. Measured threshold fluences were 1.75 J/cm2 for vocal folds and 0.5 J/cm2 for cheek pouches for 3-ps, 776-nm laser pulses. Scarred pouches exhibited 30% lower threshold than healthy pouches, possibly due to the degraded mechanical properties of scarred collagen during wound healing. The analysis of tissue architecture indicated a direct correlation between the ablation threshold and tissue tensile strength and that the bubble lifetime is inversely related to tissue stiffness. Overall, this study sheds light on the required laser parameters for successful implementation of ultrafast laser ablation for phonosurgery.
Original language | English |
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Article number | 118001 |
Journal | Journal of Biomedical Optics |
Volume | 18 |
Issue number | 11 |
DOIs | |
Publication status | Published - Nov 2013 |
Externally published | Yes |
Funding
Grants from the National Science Foundation (IDR: CBET-1014953 and Career Award: CBET-0846868) supported this work. We thank Raydiance, Inc. for use of their Discovery fiber laser, Dr. David Kleinfeld and his research group for the use of MPScan, as well as Dr. R. Rox Anderson, Dr. Christopher Hoy, Dr. Nicholas Durr, Dr. Richard Harrison, Dr. Aaron Friedman, Myoungkyu Lee, Navid Ghorashian, and Ki Hyun Kim for consultation.
Funders | Funder number |
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National Science Foundation | 1014953, CBET-0846868, CBET-1014953 |
Keywords
- ablation of tissue
- endoscopic imaging
- laser-induced damage
- mechanical properties of tissue
- multiphoton processes
- nonlinear microscopy
- scarring
- tensile strength of tissue
- ultrafast lasers
- vocal fold scarring