2.1.

Optical Diffusion Theory

The total radiant emission of Cherenkov light from tissue, $R$, can be approximated as the diffuse emitted light that has been diffused by scattering interactions and escapes the surface. As there is exponential attenuation of non-scattered light by the total attenuation coefficient of tissue, ${\mu }_t\approx 100{\mathrm{cm}}^{-1}$, after a few hundred microns, the light is fully diffused, meaning that the original directionality of the photons is lost due to multiple scattering. Here, we assume that all light that escapes the surface is fully diffuse. For highly scattered light, attenuation in tissue over distances greater than a few millimeters can be reasonably accurately described by the diffusion equation ¹¹:

Fig. 2

The geometry of a slab of tissue is shown (a) with orthogonal axes $(x,y,z)$ and radiant emission $R(z=0)$ out of the top surface, in the $-z$ direction. The geometry to estimate internal fluence with the extrapolated boundary method is shown in (b) with the assumption that at some distance above the surface, the fluence drops to zero. $z_0$ represents the depth of the apparent source, $S(r)$.

To predict a light distribution, the diffusion theory functional form solution to Eq. (1), $G(r)$, becomes the kernel for transport away from the source, so it needs to be convolved with the source distribution to accurately reflect the light field from an extended source, as

Fig. 3

Conceptually, the emitted Cherenkov light from tissue is a convolution of the Cherenkov generation with the probability of escape from the upper surface. This latter probability is dictated by the attenuation by tissue optical interaction coefficients, predicted from the diffusion equation over moderate distances.

2.2.

X-Ray Radiation Dose & Build-Up as the Source of Cherenkov

As in the approximations stated above, the source of optical photons, $S(r)$, could be assumed to be directly proportional to the dose deposited by a specific megavoltage beam with a given energy spectrum, assuming that beam hardening effects are negligible. Typical depth dose measurements show that these shallow depths are dominated by the build-up region, where the dose is below the maximum, and builds up to $d_{\max }$, the point of maximum dose deposition, which is larger than the limit of Cherenkov detection depth. In Fig. 4, the Eclipse treatment planning system (TPS) percent depth dose (PDD) curves, calculated using the Analytical Anisotropic Algorithm (Varian Medical Systems, Palo Alto, California) are displayed over the full range of 6, 10, and 18 MV x-ray beams over a depth of 30 cm, and in the first 0.8 cm where the build-up region is nearly linear.¹³ These plots are typical and are affected by factors such as the source-to-surface distance (SSD), beam diameter, variations in collimator scatter, and irradiated volume backscatter. However, in general, for a water-equivalent material, the dose increases approximately linearly within a depth smaller than 0.5 $d_{\max }$, owing to the charge particle disequilibrium.

Fig. 4

The TPS calculated PDD curves are shown for photon beams at $\mathrm{SSD}=100\mathrm{cm}$. The first 0.8 cm of dose deposition contains the only relevant contribution to Cherenkov light that can be emitted from tissue, given that deeper Cherenkov light is largely attenuated as it exits the surface. For each energy, a linear approximation is quite accurate in this shallow depth range.

In this study, where Cherenkov emission is known to only escape from tissue within the top 0.4 to 0.8 cm based upon Monte Carlo simulations,¹⁴ we use the dose deposition inside the tissue to approximate the Cherenkov source equation increasing with depth,

While this definition of the source function is physically representative of the generation of Cherenkov photons within the tissue, it poses a mathematical issue for the definition of the radiant emission, $R$, given by Fick’s Law in Eq. (2). $R$ is proportional to the spatial derivative of $\phi (r)$ at $\mathrm{z}=0$. However, $\phi (r)$ is discontinuous at this point, and therefore nondifferentiable, and so a common approach to solving this issue is to use the extrapolated boundary method to formulating the diffusion solution. While this approach has a long history of developing the formalism, it can be simplified by taking the derivative inside the boundary where the fluence exists.^15–17

2.3.

Diffuse Cherenkov Emission in One Dimension

For the specific case of a broad planar irradiation of tissue, this theory approximates a 1D situation. The 1D diffusion equation may be used, and assuming the tissue is homogenous in $x$ and $y$, the equations above simplify significantly. Equation (1) therefore becomes:

Combining Eq. (9) with Fick’s Law in Eq. (2), the radiant Cherenkov emission, $R$, from the tissue surface at $z=0$ is evaluated as a function of $k_1$ and $k_2$, and this is plotted in Figs. 5(a) and 5(b). For tissue, where ${\mu }_a=0.1{\mathrm{cm}}^{-1}$ and ${{\mu }^{\prime }}_s=10.0{\mathrm{cm}}^{-1}$, we approximate the optical coefficients as $D=1/3{{\mu }^{\prime }}_s\approx 0.033\mathrm{cm}$, and ${\mu }_{\mathrm{eff}}\approx 1.7{\mathrm{cm}}^{-1}$ in the near infrared. Figure 5(c) shows the relationship between $R$ and ${\mu }_{\mathrm{eff}}$ for each x-ray beam energy over a practical human tissue range, 0.9 to $3.2{\mathrm{cm}}^{-1}$. Figure 5(c) provides insight into the origins of the signal emitted at the surface, accounting both for beam energy and tissue optical properties. It is worth noting that the derivation of $R$ does not account for more Cherenkov photons generated at higher energies.⁷

Fig. 5

The calculated radiant Cherenkov emission from Eqs. (2) and (9) is plotted as a function of surface dose (a), dose build-up slope (b), and the effective attenuation coefficient in tissue (c). In (a), $k_1$ is varied with constant $k_2$ values for 6, 10, and 18 MV x-ray beams as indicated. The black arrows denote the specific $k_1$ and $k_2$ values for the corresponding energies. Figure (b) is analogous to (a), with $k_2$ varied over three constant $k_1$ values for 6, 10, and 18 MV.

3.1.

Imaging Irradiated Tissue Phantoms

Diffuse liquid tissue phantoms were made with a combination of water, bovine blood, and Intralipid^® to simulate the optical properties of human tissue.¹⁹ The concentration of Intralipid^® varied between 0.5% and 2%, in steps of 0. 25%, whereas the concentration of blood varied between 0.5% and 3.5%, in steps of 0.5%. These values were chosen to reflect the range of optical scattering and absorption properties for various human tissue types. The tissue phantoms were contained in a black, open-top, plastic cylinder of depth 1.9 cm, inner diameter 8.8 cm, and outer diameter 9.1 cm when irradiated.

A TrueBeam linear accelerator (Varian Medical Systems, Palo Alto, California) was used to irradiate the tissue phantoms with 200 MU using 6, 10, and 18 MV x-rays, shown in Fig. 6. The SSD was kept at a constant 100 cm, and the field-size was ${10\times 10\mathrm{cm}}^2$. To measure the radiant Cherenkov emission from the entrance surface where the x-ray beam penetrates the phantom, the gantry was positioned top-down at 0 deg. To measure the Cherenkov emission from the exit surface, opposite to where the beam penetrates the phantom, the gantry was positioned at 180 deg. Data collection was performed using an intensified CMOS camera (C-Dose Research, DoseOptics LLC, Lebanon NH) fixed with a 50-mm $f/2.8$ lens (Nikkor 50 mm, Nikon, Tokyo Japan). The image intensifier in the camera used a red-sensitive photocathode, as described by Alexander et al.²⁰ The camera remained fixed to the ceiling for each imaging acquisition, and the room lights were turned off the minimize external noise.

Fig. 6

Illustration of experimental setup. The linear accelerator irradiates a tissue phantom placed on the couch with MV x-rays, and the gantry can rotate around the couch. The Cherenkov camera fixed to the ceiling captures the Cherenkov emission from the phantom. The clinical setup also includes an optical surface guidance system that is not utilized during these measurements.

To image the emission from the exit surface, $d_{\max }$ was approximated using the PDD profiles in Fig. 4. For each x-ray energy, the phantom depth was effectively adjusted to the height of the corresponding $d_{\max }$ by adding water-equivalent slabs underneath the phantom container at the beam entrance surface. Entrance and exit surface images were then taken at these depths for each Intralipid^®/blood concentration. Figure 7 illustrates the x-ray dose delivery, Cherenkov light generation, and optical emission from the tissue.

Fig. 7

Illustration of what is being measured by the camera. MV x-rays are delivered to a tissue phantom (a) and deposit dose as a function of depth, represented qualitatively by the graph. The depth at maximum dose, $d_{\max }$, is also the point of maximum Cherenkov light production (b). As tissue optical properties vary, so does the amount of light that exits the surface. As the tissue absorption increases, less Cherenkov light makes it out of the phantom (c).

3.2.

Data Processing

Image data acquired by the CMOS camera was processed and displayed with C-Dose software (C-Dose Research, DoseOptics LLC, Lebanon NH). All image analysis was conducted via MATLAB Version R2020b (MathWorks, Natick, Massachusetts). For each image acquisition, all Cherenkov frames were summed into a cumulative image⁶ and flat-field corrected.²⁰ The radiant Cherenkov emission was then determined by taking the mean pixel intensity of a rectangular region-of-interest (ROI) at the center of each irradiated phantom. The slopes of the PDD curves were approximated by applying a linear least squares regression between 0 and 0.8 cm using MATLAB’s curve fitting tool.

4.1.

Comparison of Entrance and Exit Surface Cherenkov Emission

The 1% blood/1% Intralipid^® diffuse liquid tissue phantom was designed to match the typical absorption and scattering properties of soft human tissue. This was irradiated to compare the intensity of the radiant Cherenkov emission out of the beam entrance surface to that emitted out of the beam exit surface at $d_{\max }$. Figure 8(a) shows the Cherenkov emission intensity measured out of the entrance surface for 6, 10, and 18 MV x-rays. Over this range of clinically significant energies, the radiant Cherenkov emission from the entrance surface is approximately constant, deviating no more than 1.3% between 6 and 18 MV. The radiant Cherenkov emission from the exit surface is plotted in Fig. 8(b). Overall, the Cherenkov emission from the exit surface at $d_{\max }$ is $\sim 2\times$ to $3\times$ greater than that which escapes the entrance surface due to less tissue attenuation.

Fig. 8

The Cherenkov emission from the entrance surface (a) and the exit surface (b) of the 1% blood/1% Intralipid^® diffuse liquid tissue phantom as a function of x-ray energy. The measurements were taken over the full range of energies on the Varian TrueBeam linear accelerator. Figure (c) shows the entrance Cherenkov emission normalized by the relative exit Cherenkov emission plotted as a function of the slopes of the Varian Eclipse TPS PDD data. Figure (c) also shows the calculated values of R from Sec. 2.3, which predicts the normalized Cherenkov light emission from the entrance surface.

At the exit surface, the radiant Cherenkov emission increases $\sim 44\%$ with increasing x-ray energy from 6 to 18 MV, as the amount of Cherenkov photons generated within the tissue phantoms increases.⁷ For this reason, the exit surface Cherenkov emission is taken to be approximately proportional to the amount of Cherenkov photons generated. Thus, to isolate the effect of the slope of the dose build-up on the Cherenkov emission from the entrance surface, the entrance surface values are normalized by the corresponding exit surface values and plotted as a function of $k_2$, shown in Fig. 8(c). At 6 MV, the normalized radiant Cherenkov emission is $\sim 46\%$ greater than at 18 MV. These values are then compared to the theoretical derivation for the radiant Cherenkov emission from the surface as a function of $k_2$. The calculated values were normalized such that $R$ at 6 MV ($k_2=0.664{\mathrm{cm}}^{-1}$) is equal to the normalized measured Cherenkov emission at 6 MV. For the normalized measured Cherenkov emission at 10 and 18 MV, this leads to a 15% and 20% deviation, respectively, from the theoretical predictions of $R$.

4.2.

Varying Absorption and Scattering Properties

Figures 9(a) and 9(b) show the radiant Cherenkov emission measured at the exit and entrance surfaces as a function of Intralipid^® and blood concentrations for 6, 10, and 18 MV x-ray beams. Increasing the concentration of Intralipid^® effectively increased the tissue reduced scattering coefficient, ${{\mu }^{\prime }}_s$. Measured at the exit surface, the Cherenkov emission decreased with increased scattering by $\sim 10\%$ over the full range of measurements. At the entrance surface, the radiant Cherenkov emission increased with increasing Intralipid^® concentration by $\sim 10\%$. Increasing the bovine blood concentration effectively demonstrated how the Cherenkov emission changes with increasing the absorption coefficient, ${\mu }_a$. Varying the blood concentration from 0.5% to 3.5% had $\sim 20\%$ reduction effect for both the exit and entrance measurements. With both increasing blood and Intralipid concentrations, a main discrepancy between the opposing surface measurements is that at the entrance surface, varying x-ray energy did not have an effect on the Cherenkov emission as the optical properties of the phantom changed. At the exit surface, however, a higher x-ray energy routinely produced greater Cherenkov emission.

Fig. 9

Radiant Cherenkov emission as a function of Intralipid^® concentration (scattering) is shown in (a) and blood concentration (absorption) is shown in (b). Each figure displays the Cherenkov emission at both the exit and entrance surfaces. All measurements were taken over the range of linear accelerator x-ray energies: 6, 10, and 18 MV.