1.

Introduction

Fluorescence guidance during neurosurgical tumor resection has been shown to enhance contrast between normal and malignant tissues.¹ Fluorescein sodium (FS) is a vascular-targeted marker, which accumulates in areas of blood–brain barrier breakdown, making it useful for marking malignant gliomas.^2,3 While FS has high sensitivity,⁴ it has low tumor specificity, and vascular leakage into areas of peritumoral edema or surgical trauma limits its role as a unique tumor biomarker during neurosurgery. However, FS may provide complementary tissue contrast when coupled with other tumor-targeting fluorophores to guide surgeries. One potential multiplexed approach involves the coupled administration of FS with aminolevulinic acid, which is a nonfluorescent prodrug that serves to bypass the negative feedback controls of heme, leading to a temporary enhanced accumulation of the endogenous fluorophore protoporphyrin IX (PpIX).⁵ Tumor selectivity is a result of altered metabolic turnover of heme biosynthesis in diseased cells,⁵ providing tumor-to-normal-tissue contrast.^1,5–7 This study investigates the use of white light reflectance spectroscopy to accurately estimate the tissue optical properties necessary to quantify the biodistribution of the multiplexed fluorophores FS and PpIX.

FS-guided surgery has clinical implementations based on a high-dose regime ($20\mathrm{mg}/\mathrm{kg}$^2,4,8) sufficient to yield fluorescence emissions that are visible to neurosurgeons under white light illumination, and a low-dose regime (3 to $8\mathrm{mg}/\mathrm{kg}$^2,9–11) that produces fluorescence detectable with specialized excitation and filtering equipment within a surgical microscope.^1,2,4 In either case, the standard approach to clinical interpretation of FS biodistribution within the surgical field involves qualitative inspection of the fluorescence emission intensity maps. However, fluorescence emissions are influenced not only by the concentration of the fluorophore but also by background optical absorption and scattering of the tissue. Correction algorithms have been developed to transform raw fluorescence intensity signals into quantitative units that are independent of distortions from background optical properties.¹² These corrections usually require a paired measurement of localized white light reflectance to estimate the reduced scattering and absorption coefficients, the latter of which is defined by estimation of microvascular parameters (e.g., blood volume and hemoglobin saturation). While correction algorithms have been developed and translated to quantify fluorophores such as PpIX for tumor detection in the brain,^13,14 no such correction has yet been applied to FS.

Development of quantification algorithms for FS is complicated by the associated light transport. First, the excitation and emission bands of FS (which peak in the 450 to 500 nm and 500 to 550 nm regions, respectively) are attenuated in tissue by background absorption from whole blood, meaning that proper correction requires spectral estimation of absorption across both excitation and emission bands. Second, the strong fluorescence emission properties of FS can result in visually detectable fluorescence photons in response to white light illumination. The latter attribute presents an interesting white light spectral signature that samples not only elastically scattered photons originating from the light source but also fluorescence emissions from FS contained within the optically sampled tissue volume. The collection of fluorescence emissions within the reflectance spectra confounds explicit recovery of optical properties through model-based reflectance analysis.

This study focuses on the development of a spectral analysis algorithm to quantify optical properties from white light reflectance spectra in the presence of emission from a strong fluorescence marker (i.e., FS). Experimental measurements in tissue-simulating optical phantoms are used to characterize the light transport of spectral remission over a range of physiologically relevant FS concentrations. The data are used to characterize and validate the ability of a mathematical model to estimate background optical properties that are independent of FS concentration, returning accurate descriptions of microvascular physiology (including blood volume and hemoglobin saturation), and to observe model influences on quantitative estimates of PpIX fluorescence in the presence of FS.

2.

Methods

3.

Results

Figure 1(a) shows white light reflectance spectra measured in tissue-simulating optical phantoms over a range of FS concentrations [(0 to 500) $\mu \mathrm{g}/\mathrm{mL}$]. These phantoms had constant background optical properties that mimic tissue where scattering was defined by a LVF of 1.5%, and absorption from whole blood with BVF of 2%, in which case spectral distortions were attributable to FS. Specifically, the spectra show the emergence of a dominant peak between 500 and 550 nm with increasing FS concentration. This peak is attributed to FS emissions excited by the white light source during reflectance measurements—a link that is supported by comparisons with the FS emission bands shown in Fig. 1(b). While the magnitude of the emission peak increases with FS concentrations in the range of 0 to $125\mu \mathrm{g}/\mathrm{mL}$, the relationship does not hold for higher concentrations where the peak exhibits both a decrease in magnitude and a subtle shift toward longer wavelengths—distortions that are consistent with self-absorption and re-emission by FS.²³ Characterization of the FS absorption and emission effects embedded within the spectra are complicated by the overlap with the distinctive absorption bands of oxy- and deoxy-hemoglobin, shown in Fig. 1(c) for comparison. These observations motivated the investigation of mathematical models to decouple the elastic scatter portion of the signal from the FS emission in order to yield accurate estimates of background optical properties.

Fig. 1

(a) Reflectance spectra data sampled in optical phantoms with constant background optical properties ($\mathrm{BVF}=2\%$, $\mathrm{LVF}=1.5\%$) over a range of FS concentrations with variations in spectra dependent on emissions of FS. (b) The absorption and emission spectra for fluorescein and (c) absorption spectra for oxy- and deoxyhemoglobin incorporated into the fitting are shown, normalized to their respective peaks.

Figure 2 shows reflectance fits of multiple models (i.e., $R^M$, $R_E^M$, and $R_{AE}^M$) to selected spectra from Fig. 1(a). Here, each row of panels represents a different model fit while each column presents a different FS concentration. For all models, a fitting range of 500 to 750 nm was applied to avoid the near zero intensity sampled below 500 nm that was observed for FS concentrations $>125\mu \mathrm{g}/\mathrm{mL}$. The reflectance spectra shown in Fig. 2 were selected from a larger phantom set ($n=36$) that considered coupled variation in FS over (0 to 1000) $\mu \mathrm{g}/\mathrm{mL}$ and BVF over (1% to 3)%. Figure 3 contains the estimated parameters from the full phantom set, including goodness-of-fit (${\chi }^2/\nu$), BVF, ${\mathrm{StO}}_2$, ${\mu }_s^{\prime }$, and ${\mu }_a$; dashed lines in these plots signify either the average ${\chi }^2/\nu$ for the zero-FS phantoms or the true value of the phantom parameter.

Fig. 2

Reflectance spectra and model fits with constant background optical properties ($\mathrm{BVF}=2\%$, $\mathrm{LVF}=1.5\%$) and variations in FS. Data show differences in fit quality for (a)–(d) $R^M$, (e)–(h) $R_E^M$, and (i)–(l) $R_{AE}^M$. Black lines are model fits to data, and orange curves are the components of reflectance due to FS emission for $R_E^M$ and $R_{AE}^M$.

Fig. 3

Reduced chi-squared and optical parameter estimates from (a)–(e) $R^M$, (f)–(j) $R_E^M$, and (k)–(o) $R_{AE}^M$ from measurements of optical phantoms with constant scattering (1.5% LVF), and variation in both $\mathrm{BVF}=(1,2,3)\%$ and FS (0.98 to $1000\mu \mathrm{g}/\mathrm{mL}$). For ${\chi }^2/\nu$, the dashed line represents the zero-FS case. For all other plots, the dashed line represents known value.

Figures 2(a)–2(d) show $R^M$ model fits, which incorporated only elastically scattered reflectance. The inability to characterize the FS emission peak near 521 nm causes increasing error in model fits with increasing FS concentration. This phenomenon is characterized by a 250-fold increase in ${\chi }^2/\nu$ over the range of sampled FS concentrations. Parameter estimates from $R^M$ model fits show clear FS-dependent trends in Figs. 3(a)–3(e). Respective absolute mean percentage errors and errors for all estimated parameters are summarized in Table 1. The data in Fig. 3(e) show that both known and estimated ${\mu }_a(405\mathrm{nm})$ values stratify for different BVF (as in panel b) and reveal increasing contributions from FS at higher FS concentrations. Figures 2(e)–2(h) present fits for $R_E^M$, which consider both elastically scattered light and FS emission, and produce excellent spectral fidelity over the majority of the FS concentrations tested, with ${\chi }^2/\nu$ increases observed only at the highest FS concentrations of 500 and $1000\mu \mathrm{g}/\mathrm{mL}$. Despite the excellent fits, clear FS-dependent trends exist in estimates of BVF, ${\mathrm{StO}}_2$, and ${\mu }_a(405\mathrm{nm})$, as shown in Figs. 3(g), 3(h), and 3(j). Comparison of $R_E^M$ with $R^M$ showed increased accuracy of ${\mathrm{StO}}_2$ and ${\mu }_s^{\prime }$, but the error in BVF was not substantially improved (see Table 1). Additionally, the ${\mu }_a(405\mathrm{nm})$ estimates show deviation at higher FS concentrations. Figures 2(i)–2(l) show fits of $R_{AE}^M$, which account for optical property-based attenuation in the sampled FS emission peak. $R_{AE}^M$ produces excellent model fits over the entire range of FS concentrations tested and yielded a maximum ${\chi }^2/\nu$ twofold lower than that observed with $R_E^M$. The parameter estimates for $R_{AE}^M$ in Figs. 3(l)–3(o) show stability across the range of FS concentrations considered and increased accuracy in BVF and ${\mu }_a(405\mathrm{nm})$ recovery relative to $R_E^M$ (see Table 1).

Table 1

Comparison of RM, REM, and RAEM model estimates of optical parameters from measurements in whole blood and Intralipid optical phantoms. Error is the mean residual, as a percentage, averaged across each respective phantom set.

Figure 4 shows parameter estimates from reflectance measurements in a phantom set with variations in scattering, $\text{L}\mathrm{VF}=(1,1.5,2)\%$, for constant absorption, $\mathrm{BVF}=2\%$. Parameter estimates show similar trends to those in the BVF-variation data, with $R^M$ unable to fit spectra containing FS emission, yielding increases in ${\chi }^2/\nu$ and corresponding increases in error for estimates of BVF, ${\mathrm{StO}}_2$, and ${\mu }_s^{\prime }$, and ${\mu }_a$ (see Table 1). As with the phantom set varying BVF, $R_E^M$ led to improved ${\chi }^2/\nu$ values for the spectral fits and more accurate optical property estimates than $R^M$, while $R_{AE}^M$ provided the most stable parameter estimates. The data presented in Figs. 3 and 4 and Table 1 indicate that $R_{AE}^M$ accurately estimates background optical properties that are independent of FS concentration over a range of relevant blood volume variations and background scattering magnitudes.

Fig. 4

Reduced chi-squared and optical property estimates from (a)–(e) $R^M$, (f)–(j) $R_E^M$, and (k)–(o) $R_{AE}^M$ for phantom data exploring changes in scattering, with $\mathrm{LVF}=(11.52)\%$, $\mathrm{BVF}=2\%$, and FS (3.9 to $62.5\mu \mathrm{g}/\mathrm{mL}$). For ${\chi }^2/\nu$, the dashed line represent the zero-FS case. For all other plots, dashed lines represent known values.

Figure 5 presents spectral and intensity-based fluorescence responses for multiplexed measurements of FS over a range of (0, 0.98 to 62.5) $\mu \mathrm{g}/\mathrm{mL}$, and PpIX over a range of (0.012 to 1) $\mu \mathrm{g}/\mathrm{mL}$. Figure 5(a) shows fluorescence spectra for varying FS concentrations with PpIX held at $1\mu \mathrm{g}/\mathrm{mL}$, which show that the FS emission peak increases between 500 and 550 nm as the FS concentration increases, and a distinct PpIX-emission peak is visible near 635 nm. FS emission intensity was quantified over a wide range of FS concentrations [(0 to 1000) $\mu \mathrm{g}/\mathrm{mL}$] for multiple BVF [in the range (1, 2, 3)%], as shown in Figs. 5(b) and 5(c), on linear and log scales, respectively. These data include multiple attenuation-based effects: (1) BVF-based attenuation with an average of $34\pm 12\%$ variation in FS fluorescence intensity due to absorption differences from blood volume variations and (2) FS-based self-attenuation that is characterized by a nonlinear (i.e., power-law) response versus FS concentration, which is clearly evident above $100\mu \mathrm{g}/\mathrm{mL}$. These observed variations in FS fluorescence highlight the role of background optical properties in the distortion of remission intensity. Analysis of PpIX fluorescence utilized estimates of optical properties as inputs to a fluorescence correction algorithm, Eq. (7), to yield quantitative fluorescence, independent of absorption and scattering effects. PpIX concentration estimates were calculated using optical property estimates from each of the reflectance models considered in the study ($R^M$, $R_E^M$, and $R_{AE}^M$). Figure 5(d) shows the estimates of PpIX concentration obtained using $R_{AE}^M$ reflectance estimates are linear with the known PpIX concentration. The black line represents unity, and the colored markers follow the legend in Fig. 5(a). Figure 5(e) reports the mean residual percentage errors for phantoms containing $\mathrm{PpIX}=1\mu \mathrm{g}/\mathrm{mL}$ with either $R^M$ or $R_{AE}^M$ reflectance estimates used as inputs into the fluorescence correction algorithm. The data show FS-dependent error introduced into the PpIX estimates for models that do not consider emission (max errors of 86%, 28%, and 48% for BVFs of 1%, 2%, and 3%, respectively) are higher than estimates obtained from a model correctly accounting for emission (max errors of 28%, 9%, and 29%). These data highlight the importance of modeling the influence of FS on white light reflectance in order to properly quantify PpIX when measured in the presence of FS.

Fig. 5

(a) Representative fluorescence spectra showing the emission of both FS and PpIX simultaneously; (cpms) is counts per millisecond. The nonlinearity of FS fluorescence versus concentration is shown on (b) linear and (c) log scales. (d) Estimates of PpIX concentration obtained using $R_{AE}^M$ reflectance estimates are linear with the known PpIX concentration. The black line represents unity, and the colored markers follow the legend in (a). (e) The mean residual percentage errors for phantoms containing $\mathrm{PpIX}=1\mu \mathrm{g}/\mathrm{mL}$ with either $R^M$ or $R_{AE}^M$ reflectance estimates used as inputs into the fluorescence correction algorithm. Open symbols correspond to $R^M$, filled symbols correspond to $R_{AE}^M$, and symbol shape follows the legend in (c).

4.

Discussion

This paper develops a mathematical model to analyze localized reflectance spectra that are measured in the presence of a strong fluorescence marker (i.e., FS). Experimental data acquired from tissue-simulating optical phantoms highlight the contribution that FS emission can make to the collected reflectance spectrum. A model-based description of the reflectance spectrum was achieved by assembling a combination of elastically scattered photons and fluorescence photons emitted by FS. Interestingly, accurate estimation of optical properties required characterization of the subtle absorption and scattering-based distortions of the FS fluorescence emissions described within the model. Estimated optical properties yielded accurate metrics of localized vascular physiology (i.e., BVF and microvascular saturation) and accurate quantitative estimates of PpIX over a wide range of FS concentrations. The data highlight the need to account for fluorescence-based contributions that may be sampled in reflectance spectra.

This study considered a broad range of FS concentrations that span physiologically relevant values expected to occur during neurosurgery. FS doses can vary across a broad range [i.e., (3 to 20) $\mathrm{mg}/\mathrm{kg}$] depending on how FS is being excited.^2,4,8–11 High clinical FS doses of $20\mathrm{mg}/\mathrm{kg}$ are given in cases involving white light illumination.^2,4,8 Using the average adult body mass for North America (80.7 kg; body mass index $28.7\mathrm{kg}/{\mathrm{m}}^2$)²⁴ to calculate average blood volume (5 L),²⁵ the FS concentration in the circulating blood supply is estimated to be $\sim 320\mu \mathrm{g}/\mathrm{mL}$. For surgical applications in the brain, a wide range of blood volumes may be probed; while normal cortex may have a BVF range of 1% to 3%, with higher volumes observed in tumor due to increased vascular proliferation and a leaky blood–brain barrier, surgically induced trauma may result in BVFs of 1% to 20%.²⁶ Moreover, image-based assessment within the full field of view may sample larger vessels with BVFs near 100%. Considering a range of 1% to 20% BVF leads to volume averaged estimates of FS concentration in tissue of roughly 3 to $65\mu \mathrm{g}/\mathrm{mL}$; however, the relationship between BVF and FS may not be linear due to FS accumulation in cerebral areas as a result of leakage from a damaged blood–brain barrier.² This analysis suggests that FS concentrations within a surgical field may be sufficient to induce FS emissions in sampled reflectance spectra, and in these cases, modeling the influence of emission on the collected spectrum would be necessary to return accurate optical properties and quantitative estimates of sampled fluorophore concentrations. Lower FS doses, namely, 3 to $8\mathrm{mg}/\mathrm{kg}$,^2,9–11 may be used clinically in conjunction with specialized imaging equipment that increases optical sensitivity to FS. In these cases, the maximum FS concentration may be in the range of (10 to 30) $\mu \mathrm{g}/\mathrm{mL}$, which may reduce but not eliminate the need for modeling FS emission within reflectance spectra. Fortunately, the combined reflectance and emission model did not introduce errors into the optical property estimates in the absence of FS concentration, and therefore the model can be used reliably in any situation where FS may or may not be contained within the tissue.

Sampling a multiplexed set of fluorophores may provide enhanced contrast between normal and malignant tissue during neurosurgery. FS and PpIX represent an interesting combination that provides complimentary mechanisms of contrast, through FS assessment of vascular integrity and PpIX-indication of metabolic activity. Multiple factors must be considered when interpreting the optical signals resulting from the sampling of multiple fluorophores. First, the emissions from each fluorophore must be separated using spectral decomposition, which is simple when distinct peaks occur as shown in Fig. 5. Second, the absolute magnitude of fluorescence signals must be corrected for the distortion caused by optical absorption and scattering-based attenuation. Fluorescence correction algorithms can be developed that use optical properties as inputs to estimate the intrinsic fluorescence, or the fluorescence due solely to the fluorescent marker of interest. This study used Eqs. (6) and (7) to solve for intrinsic PpIX fluorescence,¹⁴ a correction that is dominated by absorption and scattering at the excitation wavelength. The data presented in Figs. 5(d) and 5(e) summarize the accuracy of the fluorescence correction, and the influence that choice of reflectance model can have on the quantitative estimates of PpIX. These differences, shown in Fig. 5(e), were heavily influenced by error in BVF and represent the rationale for characterizing error in ${\mu }_a$ and ${\mu }_s^{\prime }$ at the extrapolated wavelength of 405 nm. The data suggest that quantitative optical spectroscopy in the presence of FS likely requires consideration of FS contributions to reflectance spectra if a moderate amount of FS is expected, even if FS emissions are not being independently quantified. The study does not introduce an optical property correction for FS emissions, which would require independent modulation of BVF and ${\mathrm{StO}}_2$ to characterize the spectral aspects of absorption variation that can be found in tissue in vivo. Additionally, quantification of FS may require consideration of self-absorption and re-emission that can be observed with a fluorophore having a small stokes shift such as FS. These effects can be characterized by observing spectral distortions to the emission bands.²³ The data presented in the current study represent a first step toward quantitative optical spectroscopic guidance of neurosurgery in the presence of FS.