@article{sathyam96b, author = {U. S. Sathyam and A. Shearin and E. A. Chasteney and S. A. Prahl}, title = {Threshold and Ablation Efficiency Studies of Microsecond Ablation of Gelatin Under Water}, journal = {Lasers Surg. Med.}, volume = {19}, pages = {397--406}, year = {1996}, abstract = {\textbf{Background and Objective}: Laser Thrombolysis is the selective ablation of thrombus occluding vessels by microsecond pulsed laser irradiation. To achieve efficient ablation of thrombus, the optimal wavelength, spot size, and pulse energy need to be determined. \vskip2mm \textbf{Study Design/Materials and Methods}: A gelatin-based thrombus model confined in 3\,mm inner diameter tubes was ablated under water using a 1\,$\mu$s pulsed dye laser. Wavelength studies were conducted by varying the absorption of the gelatin between 10--2000\,cm$^{-1}$ corresponding to the waveband between 400--600\,nm on the absorption spectrum of thrombus. A unique spectrophotometric method was developed to measure the ablated mass. An acoustic method was used to measure ablation thresholds under water as a function of absorption. \vskip2mm \textbf{Results}: The mass removed per pulse per unit energy was nearly equal over an absorption range of 100--1000\,cm$^{-1}$ at pulse energies above threshold. Mass removal increased linearly with pulse energy but did not have a direct relationship with radiant exposure. Ablation thresholds indicate that the gelatin needed to be heated only to 100$^\circ$C for ablation to commence. Ablation masses measured were an order of magnitude higher than those predicted by thermal ablation models. \vskip2mm \textbf{Conclusions}: The results suggest that any wavelength between 410--590\,nm can be used for effective thrombolysis. The ablation efficiency depends on the total energy delivered rather than the radiant exposure. The high ablation efficiencies suggest a dominance of the mechanical action of vapor bubbles over thermal ablation in the ablation process.}, }