Rate process model for arterial tissue thermal damage: Implications on vessel photocoagulation

Agah, Ramtin; Pearce, John A.; Welch, Ashley J.; Motamedi, Massoud

doi:10.1002/lsm.1900150205

Cited by 104 publications

(77 citation statements)

References 17 publications

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“…Damage integral value W=1 corresponds to 63% probability of cell death at a specific point, and value W=4.6 corresponds to 99% probability of cell death at a point in the model. The significance of W=1 has been reported as the point at which tissue coagulation first occurs (12).…”

Section: Mathematical Model Of Rf Ablationmentioning

confidence: 99%

Investigation of radiofrequency ablation process in liver tissue by finite element modeling and experiment

Barauskas

Gulbinas²,

Barauskas³

2007

Medicina

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Section: Mathematical Model Of Rf Ablationmentioning

confidence: 99%

Investigation of radiofrequency ablation process in liver tissue by finite element modeling and experiment

Barauskas

Gulbinas²,

Barauskas³

2007

Medicina

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“…At a temperature of ϳ67°C ͑ϳ30°C above body temperature͒, thermal damage of arterial tissue occurs within a few minutes, 15 a time scale similar to that of device deployment. Given the minutes time scale for thermal damage at 67°C, our design goal is a maximum deployment time of 60 s and desired deployment time under 30 s. To avoid causing thermal damage to the already compromised aneurysm wall under zero or low flow conditions, the optimal combination of foam T g , laser power, dye concentration, and flow will need to be determined.…”

Section: Discussionmentioning

confidence: 99%

Prototype laser-activated shape memory polymer foam device for embolic treatment of aneurysms

et al. 2007

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Abstract. Conventional embolization of cerebral aneurysms using detachable coils is time-consuming and often requires retreatment. These drawbacks have prompted the development of new methods of aneurysm occlusion. We present the fabrication and laser deployment of a shape memory ͑SMP͒ polymer expanding foam device. Data acquired in an in vitro basilar aneurysm model with and without flow showed successful treatment, with the flow rate affecting foam expansion and the temperature at the aneurysm wall. © 2007 Society of Photo-Optical Instrumentation Engineers.

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“…The damage analysis was performed for the arterial tissue with the initial temperature distribution taken from the temperature map (Fig. 6) at time t =0.1 ms, and the rate process coefficients for arterial tissue (A = 5.6·10 63 , E a = 430 KJ/mol) obtained from the literature (Agah et al 1994). The accumulated damage coefficient for the temperature distribution observed after approximately 5 thermal relaxation times (25 ms) is 6.4·10 -11 which suggest that the temperature increase and the exposure time are small and do not cause any significant thermal change in the artery tissue following IVPA imaging.…”

Section: Discussionmentioning

confidence: 99%

Remote Temperature Estimation in Intravascular Photoacoustic Imaging

Sethuraman

Aglyamov

Smalling

et al. 2008

Ultrasound in Medicine & Biology

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Intravascular photoacoustic (IVPA) imaging is based on the detection of laser-induced acoustic waves generated within the arterial tissue under pulsed laser irradiation. Generally, laser radiant energy levels are kept low (20 mJ/cm 2 ) during photoacoustic imaging to conform to general standards for safe use of lasers on biological tissues. However, safety standards in intravascular photoacoustic imaging are not yet fully established. Consequently, monitoring spatio-temporal temperature changes associated with laser-tissue interaction is important to address thermal safety of IVPA imaging. In this study we utilize the IVUS based strain measurements to estimate the laser induced temperature increase. Temporal changes in temperature were estimated in a phantom modeling a vessel with an inclusion. A cross-correlation based time delay estimator was used to assess temperature induced strains produced by different laser radiant energies. The IVUS based remote measurements revealed temperature increases of 0.7±0.3°C, 2.9±0.2 °C and 5.0±0.2 °C, for the laser radiant energies of 30 mJ/cm 2 , 60 mJ/cm 2 and 85 mJ/cm 2 respectively. The technique was then used in imaging of ex vivo samples of a normal rabbit aorta. For arterial tissues, a temperature elevation of 1.1°C was observed for a laser fluence of 60 mJ/cm 2 and lesser than 1°C for lower energy levels normally associated with IVPA imaging. Therefore, the developed ultrasound technique can be used to monitor temperature during IVPA imaging. Furthermore, the analysis based on the Arrhenius thermal damage model indicates no thermal injury in the arterial tissue; suggesting the safety of IVPA imaging

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Rate process model for arterial tissue thermal damage: Implications on vessel photocoagulation

Cited by 104 publications

References 17 publications

Investigation of radiofrequency ablation process in liver tissue by finite element modeling and experiment

Investigation of radiofrequency ablation process in liver tissue by finite element modeling and experiment

Prototype laser-activated shape memory polymer foam device for embolic treatment of aneurysms

Remote Temperature Estimation in Intravascular Photoacoustic Imaging

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