On the Hyper Thermal Therapy of Tumor Tissues by Direct Laser Heating and Gold Nano Particles ()

Badiaa Fasla, Reda Benmouna, Mustapha Benmouna

Macromolecular Research Laboratory, Department of Physics, Faculty of Sciences, University Abou Bekr Belkaid, Tlemcen, Algeria.

**DOI: **10.4236/jbnb.2014.51007
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Macromolecular Research Laboratory, Department of Physics, Faculty of Sciences, University Abou Bekr Belkaid, Tlemcen, Algeria.

Hyper thermal therapy using lasers is
emerging as a new promising route for the cancer
treatment. The tumor can be directly heated by the
radiation or indirectly using gold nano particles based on plasmon
resonance phenolmenon. These two possibilities are explored here by solving the space and time
dependent bio-heat equation under different
conditions. The knowledge of temperature profiles in the tumor region helps to
bypass the painful placement of sensors for
monitoring tumor’s heating by the laser. Important properties which could be
useful for developing an efficient tumor therapy are introduced for the first
time. It is found that the effects of metabolism consist
essentially in a redefinition of the blood temperature which increases
proportional to the heat of metabolism. Blood perfusion in a given
tissue leads to a new characteristic length of order one or two centimeters and
a blood convection parameter typically of order 30 W·m^{-1}·K^{-1}. Effects of these parameters are
scrutinized within the resolution of the bio-heat equation
under a variety of conditions. In general, space modulations of the temperature
throughout biological tissues are weak but front kinetics are quite fast.
Specific examples show the way to monitor the temperature rise taking into
account the tumor’s nature and size.

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B. Fasla, R. Benmouna and M. Benmouna, "On the Hyper Thermal Therapy of Tumor Tissues by Direct Laser Heating and Gold Nano Particles," *Journal of Biomaterials and Nanobiotechnology*, Vol. 5 No. 1, 2014, pp. 44-51. doi: 10.4236/jbnb.2014.51007.

1. Introduction

This paper deals with the temperature modeling in connection with hyper thermal therapy using laser radiation to heat up and eliminate tumor tissues in biological organs. Cells in tumor tissues are more sensitive to heating and show compact conformations as compared to healthy ones leading to inhibition of normal circulation of nutrients and oxygen in tumor cells. In addition, this behavior can be used to develop therapy strategies with the capability of differentiating between tumor and healthy tissues and tuning interactions between lasers and biological tissues to generate adequate responses. The energy deposited into biological tissues by short wavelength high energy lasers exceeds their binding energy which means that these lasers can be used to remove micron sized tumors. Photosensitive dyes provide the possibility to turn to lasers with a lower power and wavelength is adapted to the absorption spectra of the dyes [1-4].

Hyper thermal therapy is emerging as an alternative to conventional treatments based on surgery, chemotherapy or radiotherapy with the advantages of reducing collateral effects and treatment discomfort. Its success relies on a detailed analysis of the heat transfer problem including control of time and space temperature developments throughout the tumor. In such an analysis, one should take into account the specific thermophysical parameters of tissues along with the appropriate conditions initially and at boundaries. A protocol of tumor’s heating should be designed to comply with the recommendations of the medical team according to the nature of tumor and standard regulation norms [5-8].

Laser therapy can be operated in two ways depending on whether the tumor can be exposed to a direct beam or by indirect heating via gold nano particles (GNPs). In the latter case, the capacity to reduce collateral effects is enhanced by targeting tumor tissues with a great accuracy. Therefore a good selection of an adequate distribution of GNPs together with an efficient sensing method may combine to make the particles responsive to external remote command signals helping to implement the therapy protocol. For this reason, GNPs are often used because of their specific response to lasers with given wavelengths and intensities via the surface plasmon resonance phenomenon [9-12].

The present paper is organized as follows. The celebrated Pennes bio-heat equation is firstly introduced with the necessary definitions. Then the case of direct heating of a tumor in contact with the ambient is solved before considering the case of indirect heating via GNPs for a tumor located deep inside the body. Initial temperature distributions were examined first prior to the time temperature development in terms of the laser power and the duration of exposure. Specific examples and applications were given in an effort to help develop efficient therapy strategies with the relevant thermophysical and biological parameters and a variety of biological tissues.

2. The Bio-Heat Equation

Accommodating temperature sensors throughout the tumor’s region to monitor the heating process is certainly quite painful for the patient and efforts are made to alleviate such discomforts by designing models for solving the following bio-heat equation [13] under reasonable conditions of practical interest

(1)

The subscript b refers to blood while letter without subscript refer to the tumor unless specified otherwise. represents the temperature field at point r and time t, is the gradient operator; letters r, c and k refer to density, heat capacity and conductivity, respectively; w_{b} is the rate of blood perfusion and T_{b} the blood temperature. The metabolic heat generation of living cells is Q_{m} while the heat produced by the laser beam is denoted. The left hand side of Equation (1) represents the rate of thermal energy absorbed per unit volume of the biological tissue; the first term in the right hand side is the rate of heat conduction according to Fourier’s law and the second term represents the rate of heat convection through blood vessels. The convective heat exchange via blood circulation insures thermal regulation throughout the body. Blood enters the tissue at the arterial temperature T_{b}, exchanges a certain amount of energy which is equivalent to bringing the blood temperature to the level of that of the tissue. Resolution of such an equation is subject to the knowledge of initial and boundary conditions in addition to relying on appropriate values for the thermo-physical and biological parameters of the tissues, the flow rate of blood, the metabolic heat generation and the energy deposited by the laser. This problem is solved first under the conditions of a direct exposure to the incident beam before turning to the case of heating via GNPs.

3. Direct Laser Heating

The heating process starts at time t = 0 by shining the laser beam on the tumor. Resolution of this problem requires first the knowledge of the initial temperature distribution which is sensitive to the thermophysical and biological properties of the tumor as well as to environmental conditions.

3.1. The Initial Temperature Distribution T_{0}(x)

For simplicity and without loss of generality, we consider the rectangular geometry of Figure 1(a) and a square target represented in the inset. The temperature remains constant in the yOz plane and depends on x only. Panel b of this figure concerns the case of indirect heating via GNPs as it will be discussed in a later section.

Here, the initial temperature T_{0}(x) may be obtained by solving the following equation

(2)

This equation exhibits the newly introduced properties such as the characteristic length l_{b} and the effective blood temperature depending on the metabolic heat generation Q_{m}

(3)

The characteristic length l_{b} represents the distance over which blood temperature goes from an effective value to the body temperature T_{B}. Equation (2) can be easily solved using appropriate boundary conditions. At contact with the ambient, air convection tends to compensate the heat flux and one may write

(4)

where h_{e} designates the air convection parameter and T_{e} the ambient temperature (see Figure 1(a)). On the other side of the tumor at x = L, two possibilities may arise depending on whether the interface with healthy tissues is isothermal or adiabatic. In the former case, T_{0}(x = L) coincides with the body temperature T_{B} while in the latter case, the derivative of T_{0}(x) vanishes. The mathematics is

(a)(b)

Figure 1. (a) Tumor’s volume in the rectangular coordinate system and its one dimensional representation; (b) Heating by a distribution of GNPs: Schematic representation of a spherical target with radius R by a dispersion of GNPs and amplification of the temperature distribution of a single GNP (Schematic representation of DT(r, t) versus r).

somewhat tedious in both cases and only the final results are reproduced here. For the case of an isothermal interface, it can be shown that the temperature profile is given by [14,15]

(5)

where and the ratios and represent the tumor’s size L reduced to the blood perfusion and air convection lengths, respectively. The newly introduced characteristic length describes the distance over which the ambient temperature goes from T_{e} to that of the surface T_{0}(x = 0). Letting x = L in Equation (5), one gets T_{0}(x = L) = T_{B} while at x = 0, the temperature exhibits the effects of several parameters as one can see from the following expression

(6)

In the weak perfusion limit when z approaches zero, T_{0}(x = 0) tends to T_{B} independent of x. For a high convection rate, x is large and one finds the expected result T_{0}(x = 0) = T_{e}.

In the case where the interface at x = L is adiabatic, the solution of Equation (2) reads

(7)

At x = L, this result reduces to

(8)

which shows that the ratio is simply chz meaning that at low perfusion rates, and the temperature remains constant throughout the tumor. The perfusion of blood generates throughout tissues a convection mechanism characterized by the parameter.

Typical values for a case of practical interest [16,17] would be Q_{m} =4 × 10^{3} Wm^{−3}, r_{b}w_{b} =0.5 kgm^{−3}s^{−1}, c_{b} = 4 × 10^{3} Jkg^{−1}K^{−1} and k = 0.5 Wm^{−1}K^{−1}. Those numbers yield dT_{b} =2 K showing that metabolic heating is not negligible. Moreover, one has l_{b}—1.7 cm and h_{b}—33 W^{−1}mK^{−1} which means that for an air convection with h_{e} close to 33 W^{−1}mK^{−1}, l_{e} would be of the same order as l_{b} while for a lower air convection (h_{e} =10 W^{−1}mK^{−1}) it would become much higher. Note that the ratios l_{b}/l_{e} and h_{e}/h_{b} are equal.

The initial temperature profile exhibits a weak space dependence over the tumor’s region but a high sensitivity to l_{e}/l_{b}. Increasing the latter quantity makes heating less effective while decreasing it would lead to a surface temperature closer to the ambient T_{e}.

The knowledge of initial temperature distributions is necessary to get the complete solution subsequent to a direct heating by laser beams which is considered below through the resolution of the space and time dependent bio-heat equation.

3.2. Space and Time Temperature Profiles

Space and time temperature profiles due to a direct laser heating may be obtained by solving the following partial differential equation

(9)

which exhibits two distinct characteristic times and, being the heat diffusivity. The first characteristic time t_{b} represents the blood perfusion in the biological tissue while the second t represents the temperature relaxation over the tumor. The power laser P depends on the incident intensity q_{0} as P = q_{0}L^{2} (see Figure 1(a)).

Shih et al. [18] reported an analytical solution of this problem assuming a constant initial temperature (i.e. T_{0}(x) = T_{b}) and neglecting the effects of blood perfusion and metabolism

(10)

where T(x, t), T_{P}_{1} and the complementary error function [19] are defined as follows

(11)

The remarkable feature here is the emergence of a single lumped parameter combining the space and time. This behavior is characteristic of a diffusion process with a mean square diffusion distance proportional to time and diffusivity as

(12)

3.3. Effects of Blood Perfusion and Metabolism

Introducing the effects of blood perfusion breaks the universality and the solution becomes function of separate space and time variables, the space scaling with the length l_{b} and time scaling with t_{b}. Thus, the result becomes

(13)

By expanding erfc(x + e) in terms of e and letting e®0, Equation (13) reduces to (10). It is remarkable to note that the metabolism can be included simply by redefining the blood temperature and using the effective value instead of T_{b}.

The temperature fronts shown in Figure 2 indicate that space modulations are weak but the rise of temperature with time is fast. Panels a, b illustrate the high sensitivity to the blood perfusion. At low perfusion rates, the temperature reaches quickly relatively high values but as the perfusion rate increases, a net damping of the heating process takes place and the temperature reaches a saturation limit at short times.

In Figure 3, one can better apprehend the kinetic rise of temperature since heating operates fast at short times

Figure 2. DT(x, t)/DT_{P1} versus x/L at different times t/t (see Equation (10)) for (a) z = 0.1 (weak blood perfusion), and (b) 0.5 (high blood perfusion).

undergoing a severe damping as z increases due to the blood regulation mechanism. The blood perfusion provokes some delay in early stages which can be seen in the amplified representation of panel b since the curves exhibit a horizontal initial slope (say t/t £ 0.1) before the steep rise.

4. Indirect Laser Heating via GNPs

In the case where tumors are not directly accessible to the laser beam from the ambient, the recourse to an indirect heating via GNPs turns out to be particularly useful for treatment efficiency. Panel b of Figure 1 mimics the discrete temperature distribution in a spherical tumor embedded with GNPs. One can see in the same figure, the single sphere temperature profile in the immediate vicinity of a single GNP with spherical geometry [20]. From a practical point of view, the problem may be simplified by solving the bio-heat equation in spherical coordinates assuming point sources representing the GNPs.

(14)

The last term in the right hand side comes from the external heat deposited in the tumor. Resolution of such a

(a)(b)

Figure 3. (a) DT(x, t)/DT_{P1} versus t/t for x/L = 0.5 and different values of z. (b) Amplification of DT(x, t)/DT_{P1} at short times (i.e., t/t < 0.1; see Equation (10)). Note the initial horizontal slope indicating perfusion induced delays in the heating process. The curves in panel (a) are weakly sensitive to x/L. For 0.1, they are slightly above and for 0.5 slightly below those shown and they all follow the same trends.

problem is subject to the knowledge of the initial distribution which should be determined first as stated before.

4.1. Initial Temperature Distribution for a Spherical Tumor

The initial temperature for a spherical tumor can be obtained by equating the left hand side and P in Equation (14) to zero. The spherical symmetry implies that heating is maximum at the center for r = 0. For an isothermal interface, the temperature should remain equal to the body temperature T_{B} and the result is

(15)

In the weak perfusion limit, z is small and the initial temperature remains equal to T_{B}. Most authors in the literature generally assume that the initial temperature is simply the blood temperature T_{b} while here, we stress the point that this temperature deserves a particular attention and depends on important thermo-physical and biological parameters of both blood and tissues.

4.2. Time Temperature Fronts

Once the initial temperature is known, one may proceed to solve the kinetic problem for which the mathematics combine classical methods of Laplace transform and variation of constants. Resolution of Equation (14) yields

(16)

where the normalizing temperature is slightly different from the one in Equations (10) and (13) for geometry considerations. The characteristic time of heat diffusion is also different for the same reason. Unlike the previous situation (see Equation (13)), space and time variables are separated and no universality is found here in spite of the fact that blood perfusion is not taken into account. Including metabolism and blood perfusion, one would have to solve the following bioheat equation

(17)

Whose solution subject to the same initial and boundary conditions becomes

(18)

This result is quite different from that of equation 16 which is recovered only when. Formally, those results are different from those obtained in the case of the discrete distribution shown in Figure 1(b) but numerically, the temperature profiles are quite close in terms of space and time variations. Figure 4(a) confirms the very weak space dependence of temperature. Space modulations do not exceed few percents while kinetics shows a fast rise of temperature with time (see Figure 4(b)). Blood perfusion reduces both the amplitude and rate of heating. A slight enhancement of the space dependence is observed at high blood perfusion rates. The initial slope is not horizontal as in the previous case meaning that no delays in o heating should exist in early stages (see Figure 4(c)). The other qualitative trends are similar to those of Figure 3.

5. Applications

Table 1 gives typical values for the parameters appearing in the bio-heat equation for a variety of biological tissues. No distinction is made between healthy and tumor tissues consistent with the model calculations. The density r is roughly 1 g∙cm^{−3} but higher by about 20% for epidermis and 50% for fat and bones. The heat conductivity k is essentially 0.5 Wm^{−1}K^{−1} except epidermis and fat for which it is 20% lower and bones for which it is 20% higher. The heat capacity c is near 3.7 Jg^{−1}K^{−1} except fat and bones that show a much lower heat capacity. The blood perfusion parameter w_{b} exhibits a large dispersion of values going from 0.07 × 10^{−2} s^{−1} for fat to 6.25 × 10^{−2} s^{−1} for kidney. Epidermis is characterized by a blood perfusion rate several orders of magnitude smaller. In the literature, this parameter is often expressed by the prod-

(a)(b)(c)

Figure 4. (a) DT(r,t)/DT_{P2} versus r/R for a dispersion of GNPs at different times and for z = 0.01 (see Equation (18)). The cases of z = 0.1 and 0.5 essentially yield the same qualitative behavior with lower values as illustrated in panel b; (b) DT(r,t)/DT_{P2} versus t/t for z = 0.01, 0.1 and 0.5; (c) Amplified version at short times. Unlike Figure 3(b), the initial slope is not horizontal.

uct r_{b}w_{b} in units of kg∙m^{−3}s^{−1}.

Table 2 gives selected data of heat transfer properties for the same biological tissues. The heat diffusivity b for most tissues is about 0.15 mm^{2}∙s^{−}^{1} but it is lower by

Table 1. Typical values for the thermo-physical parameters of main biological tissues.

Table 2. Selected properties of space and time temperature distributions for the same biological tissues.

nearly a factor two for epidermis and three for fat while for bone it is twice higher. The blood perfusion length l_{b} is typically of the order of 1 to 2 centimeters while the blood perfusion time t_{b} is typically of the order of 30 minutes. It is slightly lower for bones and slightly higher for epidermis and fat. The characteristic time of heat diffusion in tissues t is slightly above 10 min for a centimeter sized tumor except epidermis and fat for which it is much lower. The ratio t/t_{b} = z^{2} increases with increasing blood perfusion rate and tumor’s size. Metabolism induces a blood temperature increase by nearly a couple of degrees. Although rough, those numbers lead to temperature rise of tumor tissues with amplitudes and times adapted for developing a strategy of hyper thermal therapy.

6. Conclusion

One of the major challenges in developing efficient hyper thermal therapy strategies resides in the precise knowledge of temperature profiles appropriate for the nature and size of the tumor. The present work is a contribution along the line of facing this challenge based on simple analytical models supplemented with typical thermophysical and biological parameters of practical interest. Effects of blood perfusion, metabolism and laser beam intensity were quantified with simple arguments starting from the resolution of the bio-heat equation with a distinction between direct laser heating and indirect heating via GNPs. The results obtained under a variety of conditions showed a systematic consistency with regard to a weak sensitivity of temperature to the position within the tumor but a strong dependence over time. Heat metabolism contributes to increasing the blood temperature by a couple of degrees while blood perfusion significantly damps the heating process. In the early stages of laser treatment, the temperature rises fast but quickly reaches an upper limit which is systematically lower as the blood flow rate is higher. New characteristic lengths are introduced and evaluated together with typical time scales characterizing the heat diffusion mechanism in tumor tissues.

Conflicts of Interest

The authors declare no conflicts of interest.

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