Numerical investigation of thermal response of laser-irradiated biological tissue phantoms embedded with gold nanoshells.

The work presented in this paper focuses on numerically investigating the thermal response of gold nanoshells-embedded biological tissue phantoms with potential applications into photo-thermal therapy wherein the interest is in destroying the cancerous cells with minimum damage to the surrounding healthy cells. The tissue phantom has been irradiated with a pico-second laser. Radiative transfer equation (RTE) has been employed to model the light-tissue interaction using discrete ordinate method (DOM). For determining the temperature distribution inside the tissue phantom, the RTE has been solved in combination with a generalized non-Fourier heat conduction model namely the dual phase lag bio-heat transfer model. The numerical code comprising the coupled RTE-bio-heat transfer equation, developed as a part of the current work, has been benchmarked against the experimental as well as the numerical results available in the literature. It has been demonstrated that the temperature of the optical inhomogeneity inside the biological tissue phantom embedded with gold nanoshells is relatively higher than that of the baseline case (no nanoshells) for the same laser power and operation time. The study clearly underlines the impact of nanoshell concentration and its size on the thermal response of the biological tissue sample. The comparative study concerned with the size and concentration of nanoshells showed that 60nm nanoshells with concentration of 5×1015mm-3 result into the temperature levels that are optimum for the irreversible destruction of cancer infected cells in the context of photo-thermal therapy. To the best of the knowledge of the authors, the present study is one of the first attempts to quantify the influence of gold nanoshells on the temperature distributions inside the biological tissue phantoms upon laser irradiation using the dual phase lag heat conduction model.

Phadnis A ，Kumar S ，Srivastava A 《JOURNAL OF THERMAL BIOLOGY》

Investigation of thermal distribution for pulsed laser radiation in cancer treatment with nanoparticle-mediated hyperthermia.

In this paper, we have simulated the efficacy of gold/gold sulfide (GGS) nanoshells in NIR laser hyperthermia to achieve effective targeting for tumor photothermal therapy. The problem statement takes into account the heat transfer with the blood perfusion through capillaries, and pulsed laser irradiation during the hyperthermia. Although previous researchers have used short laser pulses (nanosecond and less), in order to prevent heat leakage to the neighbor tissues, we have examined the effect of millisecond pulses, as the extent of the target volume to which hyperthermia is induced is usually larger and also the lasers with this specification are more available. A tumor with surrounding tissue was simulated in COMSOL software (a finite element analysis, solver and simulation software) and also in a phantom made of agarose and intralipid. The tumor was irradiated by 10, 20 and 30 laser pulses with durations of 15, 50 and 200ms and fluences of 20, 40 and 60J/cm(2). Experimental tests performed on a phantom prove the ability of the applied numerical model to capture the temperature distribution in the target tissue. We have shown that our simulation permits prediction of treatment outcome from computation of thermal distribution within the tumor during laser hyperthermia using GGS nanoshells and millisecond pulsed laser irradiation. The advantage of this simulation is its simplicity as well as its accuracy. Although, to develop the model completely for a given organ and application, all the parameters should be estimated based on a real vasculature of the organ, physiological conditions, and expected variation in those physiological conditions for that application in the organ.

Sazgarnia A ，Naghavi N ，Mehdizadeh H ，Shahamat Z ... -  《JOURNAL OF THERMAL BIOLOGY》

Potentials and pitfalls of gold-silica nanoshell as the exogenous contrast agent for optical diagnosis of cancers: a numerical parametric study.

Xu X 《-》

Computational study of photo-thermal ablation of large blood vessel embedded tumor using localized injection of gold nanoshells.

Attaining a precise necrosis of tumor sparing normal tissue during carcinomas thermo-therapy via nominally invasive scheme like irradiation of laser is a recent challenge. In this study, a combined diffusion and convective energy equations were solved using COMSOL Multiphysics to predict the tissue thermal profile during laser assisted thermo-therapy with different tissue vascular networks. A comparative analysis between intratumoral and intravenous loading scheme of silica-gold nanoshells (AuNs) was also performed. AuNs cluster position and alignment was altered to achieve precise ablation of a large tumor with minimum damage to healthy tissue and improvement in necrosis in the vicinity of large blood vessels (LBV). A modified Beer-Lambert law and Arrhenius equation was applied to model laser heat propagation and to compute thermal damage respectively. Simulation results suggests the dominance of targeted nanostructure injection in cluster form over intravenous scheme in terms of precise control over spreading of necrotic zone due to selective laser dose delivery into the tumor. An effective tumor ablation, sparing normal tissue is best revealed for Type-A intratumoral scheme comparing Type-B and C as the reallocation of cluster position can help to achieve an irregular shaped necrotic zone. In addition a comparative analysis between dual-phase-lag (DPL) and classical Fourier approach within a tumor-blood inhomogeneous inner structure was made to access the effect of relaxation time onto biological thermal response. Numerical results show a difference in temperature profile between these two approaches during non-equilibrium condition i.e at the prior phases of laser heating and cooling whereas the results overlaps at higher instants. Since the DPL based bioheat conduction model can predict the inherent wave nature of the thermal front which is propagating at a finite speed. This study may improve the real clinical invasive schemes applied to ablate malignant tumor during hyperthermia treatment.

Paul A ，Paul A 《JOURNAL OF THERMAL BIOLOGY》

Modeling of plasmonic heating from individual gold nanoshells for near-infrared laser-induced thermal therapy.

Cheong SK ，Krishnan S ，Cho SH 《MEDICAL PHYSICS》