BACKGROUND AND OBJECTIVE: The purpose of this study was to compare the ablation of cortical bone at wavelengths across the near and midinfrared region. STUDY DESIGN/ MATERIALS AND METHODS: An free electron laser generating 4-micros macropulses at specific wavelengths between 2.9 and 9.2 microm was used to ablate cortical bone. The same pulse intensity, repetition rate, radiant exposure, number of pulses, and delivery was used for each wavelength. Tissue removal, collateral thermal injury, and morphologic characteristics of the ablation sites were measured by light and scanning electron microscopy, and compared with the infrared absorption characteristics of cortical bone. RESULTS: Within the parameters used, bone ablation was found to be wavelength dependent. Incisions were deepest where protein has strong absorption, and were most shallow where mineral is a strong absorber. No char was observed on ablation surfaces where 3.0, and 5.9-6.45 microm wavelengths were used. CONCLUSIONS: The use of wavelengths in the 6.1-microm amide I to 6.45-microm amide II region, with the pulse characteristics described, were the most efficient for cutting cortical bone and produced less collateral thermal injury than cutting with a surgical bone saw. This study confirms previous observations that the ablation mechanism below plasma threshold is consistent with an explosive process driven by internal vaporization of water in a confined space and demonstrates that ablation is enhanced by using wavelengths that target the protein matrix of cortical bone. Copyright 1999 Wiley-Liss, Inc.
BACKGROUND AND OBJECTIVE: The purpose of this study was to compare the ablation of cortical bone at wavelengths across the near and midinfrared region. STUDY DESIGN/ MATERIALS AND METHODS: An free electron laser generating 4-micros macropulses at specific wavelengths between 2.9 and 9.2 microm was used to ablate cortical bone. The same pulse intensity, repetition rate, radiant exposure, number of pulses, and delivery was used for each wavelength. Tissue removal, collateral thermal injury, and morphologic characteristics of the ablation sites were measured by light and scanning electron microscopy, and compared with the infrared absorption characteristics of cortical bone. RESULTS: Within the parameters used, bone ablation was found to be wavelength dependent. Incisions were deepest where protein has strong absorption, and were most shallow where mineral is a strong absorber. No char was observed on ablation surfaces where 3.0, and 5.9-6.45 microm wavelengths were used. CONCLUSIONS: The use of wavelengths in the 6.1-microm amide I to 6.45-microm amide II region, with the pulse characteristics described, were the most efficient for cutting cortical bone and produced less collateral thermal injury than cutting with a surgical bone saw. This study confirms previous observations that the ablation mechanism below plasma threshold is consistent with an explosive process driven by internal vaporization of water in a confined space and demonstrates that ablation is enhanced by using wavelengths that target the protein matrix of cortical bone. Copyright 1999 Wiley-Liss, Inc.
Authors: Philipp Leucht; Kentson Lam; Jae-Beom Kim; Mark A Mackanos; Dmitrii M Simanovskii; Michael T Longaker; Christopher H Contag; H Alan Schwettman; Jill A Helms Journal: Ann Surg Date: 2007-07 Impact factor: 12.969
Authors: David D Lo; Mark A Mackanos; Michael T Chung; Jeong S Hyun; Daniel T Montoro; Monica Grova; Chunjun Liu; Jenny Wang; Daniel Palanker; Andrew J Connolly; Michael T Longaker; Christopher H Contag; Derrick C Wan Journal: Lasers Surg Med Date: 2012-11-26 Impact factor: 4.025