1.IntroductionMany natural and synthetic systems have disordered properties that render them optically turbid. Examples abound in science, technology, medicine, and the natural environment, and include such diverse systems as interstellar gases, biological tissues, turbulent flows, colloidal suspensions, and microcrystalline solids. Optical examinations of these random media are challenging due to extensive multiple light scattering which scrambles potentially useful sample information encoded in the light beam. For example, most biological tissues are highly scattering at visible and near-infrared (IR) wavelengths,1 so quantitative tissue spectroscopy and imaging are difficult. In recent investigations researchers have attempted to utilize the polarization properties of light to probe biological tissues and other random media, since diffusely scattered light is often partially polarized to an extent that can be experimentally detected. Several research groups are thus investigating the response of turbid media to polarized light by examining the polarization properties of multiply scattered light.2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 These polarization methodologies have been developed to study various aspects of polarized light interaction with turbid media, including the investigation of the depolarization mechanisms, quantification of depolarization length scales, determination of system Mueller matrices, and derivation of the Stokes parameters of scattered light. In several recent publications polarization imaging studies of multiply scattering media were described.6 11 20 21 22 Optical investigations of turbid media that contain chiral components have also been reported.23 24 25 26 27 28 29 30 31 The interest in chiral turbid media is driven by the attractive possibility of noninvasive optical monitoring of the glucose level in diabetic patients. This is a very difficult unresolved problem in clinical medicine and an active area of research that utilizes different biomedical optics approaches.32 33 For polarized light research, detection of glucose and quantification of its concentration rely on the molecule’s chirality that stems from its asymmetric molecular structure, resulting in a number of characteristic effects generically called optical activity.34 A well-known manifestation of optical activity is the ability of a glucose solution to rotate the plane of linearly polarized light about the axis of propagation. The amount of rotation depends on the molecular concentration, the pathlength through the medium, and the optical rotatory power at the interrogation wavelength.35 This and other chiral asymmetries encoded in the polarization properties of light transmitted through largely transparent (nonscattering) media enable very sensitive and accurate determination of glucose concentrations. With turbid materials, however, the scattering effects dominate, loss of polarization information is significant, pathlengths get scrambled, and chiral effects stemming from a small amount of dissolved glucose are much more difficult to discern. We have previously developed polarization modulation and synchronous detection methods to measure surviving polarization fractions in diffusive scattering even in the presence of large noisy depolarized backgrounds, such as in the case of synthetic turbid media25 27 28 30 31 and ex vivo 28 and in vivo biological tissues.31 Furthermore, we have experimentally observed chiral asymmetries due to the presence of glucose. Both varied the level of polarization preservation and the rotation of linearly polarized light fraction varied with glucose concentrations in the turbid samples.25 27 28 30 In comparing turbid microsphere suspensions with and without chiral molecules, depolarization was diminished in the former case both in the lateral and backscattering directions, although the mechanism responsible for this polarization enhancement effect was not determined. In this paper, we extend our methodology to perform this determination. Specifically, we analyze the polarization characteristics of laterally scattered light from chiral, racemic (equal amounts of oppositely handed isomers), and achiral solutions that contain scattering polystyrene microspheres in an effort to determine whether the chirality or the refractive index matching mechanism is the dominant cause of preservation of the enhanced polarization. We also develop methods to explicitly derive linear and circular degrees of polarization, and compare these depolarization rates in microsphere suspensions. Finally, the dependence of optical rotation of the linearly polarized light fraction on the chirality of the turbid medium is quantified. 2.TheoryLight of any arbitrary polarization state may be represented by a Stokes vector (S) of the form where I represents the total light intensity, Q and U represent the linearly polarized components of the beam, and V represents the circularly polarized component. The intensity I is directly measurable with a photodetector. For an arbitrary light beam, these terms are related by where the equality holds for fully polarized light, and the inequality applies to partially polarized light. The total degree of polarization (DOP) is defined as The linearly polarized fraction is represented by the degree of linear polarization, The degree of circular polarization is similarly defined asOf interest in the current study were the linear and circular depolarizations that occurred due to multiple scattering within the turbid sample and the optical rotation of the linearly polarized light that may be induced by the chirality of the medium. The sample was thus illuminated with a polarized light beam whose incident polarization varied in a time-dependent, controlled fashion. Upon diffusive interactions with the scattering medium, the surviving polarization properties of the light were detected at 90°, synchronously with the incident polarization modulation. The surviving linear and circular polarization fractions, βL and βC, respectively, are defined in terms of the incident (subscript i) and scattered (subscript s) polarization states as The layout of optical elements is schematically presented in Figure 1. There were two experimental arrangements employed for this study that differed in the analyzing elements placed between the sample and the detector. In arrangement A, the analyzing optics consisted of a linear polarizer (analyzer) with pass axis θ ° to the horizontal plane. Positive angles indicate rotation of the analyzer counterclockwise as one looks down the beam in the direction of its propagation. This arrangement was useful for determining the optical rotation α and the degree of linear polarization βL. To extract the degree of circular polarization βC, arrangement B was employed, which included a quarter wave plate with its fast axis 45° to the horizontal placed between the sample and the linear analyzer. The time-varying source of incident polarized light was furnished by passing linearly polarized laser light through a transparent quartz element of a photoelastic modulator (PEM). This device provides controlled, time-varying birefringence that converts the incoming linearly polarized light into transmitted elliptically polarized light,36 the polarization states of which vary over time at the PEM’s resonant frequency of 50 kHz. The use of this time-varying polarization modulation is useful in turbid media experiments because it enables high sensitivity measurements of weak polarization signals in a large noisy depolarized background using synchronous detection with a lock-in amplifier. After scattering interactions with the microsphere sample, photons directed 90° to the incident beam passed through analyzing elements and impinged on a polarization-insensitive detector. To model the polarization effects in this experimental system, the various optical components were represented by Mueller matrices. Using Mueller calculus, an optical element that acts on a light beam is represented by multiplication of the incident light Stokes vector by the Mueller matrix for that optical element. The result is the Stokes vector of the transmitted beam. Mueller matrices for common optical elements, such as a linear polarizer, a quarter wave plate (QWP), and the PEM, are available in optics textbooks.37 38 Representing the turbid chiral sample by a suitable matrix is more challenging, as described below. The resultant Stokes vector for arrangement A is similarly, for arrangement B, These expressions are now derived.Following the passage of incident light through the 45° linear polarizer P1 and the PEM with its modulation axis horizontal is the light incident on the sample has the following Stokes vector δ(t) is the retardation of the PEM as a function of time, where δ=δ0 sin(2πft). δ0 is the maximum retardation imposed by the PEM, and f is the resonant frequency of its oscillation.The turbid sample is modeled as an optical rotator (imposing a rotation of α°) and a depolarizing element [imposing linear and circular depolarizations βL and βC, defined in Eqs. (6) and (7)]. The transmitted Stokes vector is thus Two comments about the sample matrix are in order. First, although in general matrix multiplication is not commutative, in this case the order of multiplication of the two sample matrices does not matter. Second, the choice of sample matrix with different depolarization rates for linear (βL) and circular (βC) polarized light is an improvement over that in our previous work which modeled the sample with a generic depolarization parameter, β.25 27 28 30 31 Although other depolarizer matrix formulations can be suggested, the current representation is relatively straightforward and is in line with reported observations of polarization-state dependent degrees of polarization in diffusive scattering.6 7 8 16 19 For arrangement A that employs a linear analyzer oriented θ ° to the horizontal, information about the circular polarization state of the scattered light is lost, but the optical rotation α and the degree of linear polarization βL can be determined with high precision. Multiplying the Stokes vector in Eq. (8) by the Mueller matrix for a linear polarizer oriented at θ ° , and selecting the resulting Stokes parameter I that represents the measured light intensity, where k A is an unimportant experimental constant. The signal observed at the detector is thus a function of user-defined variables [the analyzer angle θ, the time varying PEM retardation δ(t)=δ0 sin(2πft) ] and the sample unknowns (α and βL ) that can be obtained by fitting Eq. (9) to the experimental data.For arrangement B, performing the additional multiplication with a Mueller matrix for a quarter wave plate with 45° fast axis orientation yields This expression contains all three important sample unknowns (α, βL , and βC ), so the insertion of the quarter wave plate permits the determination of βC as well. Note, however, that in contrast with Eq. (9), α and βL now occur as a product of βL⋅cos(2α), so independent determination of them appears difficult.To facilitate the data analysis with the help of Eqs. (9) and (10), we expand the time-dependent retardation terms cos δ(t) and sin δ(t) in a series of spherical harmonics using the following expressions:39 where Jn are the Bessel functions of the first kind of order n. Since lock-in amplification isolates signals at specific frequencies ( 1f and 2 f in these experiments), we expand the series up to the 2 f terms, with z=δ0 and ψ=2πf, to obtainIn arrangement A, taking the ratio of the signal photocurrent component at 2 f to the constant (dc) signal removes the experimental constant k A and yields Thus, by dividing the signals at 2 f by the signals at dc at a range of analyzer angles θ, parameters α and βL can be extracted by fitting the data ratios to the curve described by Eq. (14). Similarly, in arrangement B, the ratio of the signal at 1f to dc is And the 2 f/dc ratio isAs mentioned above for arrangement B, the terms βL and α appear together as the product of βL⋅cos(2α) in Eqs. (15) and (16). This prevents independent determination of these two parameters. However, if α is small (less than a few degrees, a reasonable assumption for most biological applications), then cos(2α)∼1, and βL can be determined. Making this assumption, βC and βL can be found using the 1f/dc ratio described in Eq. (15). Then an additional determination of βL can be performed by fitting Eq. (16) to the 2 f/dc signal ratios. To summarize, the optical rotation α can only be measured in arrangement A. Also, this arrangement permits the measurement of βL without the need to make any assumptions about the size of α. However, no information about circular polarization can be obtained from this setup. Insertion of a quarter wave plate in front of the linear analyzer (arrangement B) permits the determination of βC and allows βL to be evaluated with reasonable precision assuming a small induced optical rotation via a 1f/dc data fit to Eq. (15). Also, with the same assumption about α, βL can be independently estimated from a 2 f/dc fit to Eq. (16). 3.Experimental MethodsA schematic of the measurement system is shown in Figure 1. Unpolarized light from a HeNe laser (λ=632.8 nm) passed through a linear polarizer oriented 45° to the vertical. The linearly polarized light traversed the PEM (Hinds, PEM-80), oriented with its modulation axis horizontal and modulation frequency f of 50 kHz. The resulting time-varying elliptically polarized light was incident on a 1-cm-sq quartz spectrophotometer cuvette that contained the liquid turbid suspension. The detector arm was perpendicular to the incident beam, and consisted of a linear polarizer (analyzer) with its pass axis at θ ° and a photomultiplier tube (PMT) (arrangement A). For arrangement B, a quarter wave plate with its fast axis at 45° was placed between the sample and the linear analyzer. Apertures (pinhole diaphragms) were located between the sample and the analyzing optical elements, and in front of the PMT, to limit the acceptance angle of the detector. The PMT signal was fed to a preamplifier (Stanford Research Systems, SR570) before entering the lock-in amplifier (Stanford Research Systems, SR350) which enabled detection of photocurrents at the PEM modulation frequency and its first harmonic ( 1f and 2 f ). The dc signal was measured by mechanically chopping the beam at low frequency of ∼150 Hz and synchronously detecting it with the same preamp/lock-in amplifier pair. Chiral samples consisted of L−(+) -arabinose (Sigma) dissolved in de-ionized water at concentrations up to ∼2 M. Racemic samples were prepared from equal quantities of L−(+) -arabinose and D−(+) -arabinose by weight. Arabinose is a naturally occurring plant sugar similar to glucose. It was selected for these experiments because it has a significant specific rotatory power and because both its chiral isomers (L and D) are readily available and are inexpensive. Achiral samples were prepared from glycerol (ACP) in distilled water at concentrations of up to ∼35 glycerol by volume. These glycerol–water solutions were prepared to match the refractive index of the arabinose solutions. By comparing chiral and achiral samples of equal refractive index, the influence of refractive index variations versus the influence of chirality of the molecules could be separated. The turbidity in all samples was provided by suspended polystyrene microspheres, 1.4 μm in diameter at a concentration of 0.2 (2 g/L). By measuring signals at 2 f and dc in arrangement A at various angular settings of the analyzer, a plot of 2 f/dc vs θ was drawn for each sample. The θ range selected was 30°–150° to encompass a large part of the cyclic function of Eq. (14). The fitted value of α is particularly sensitive to data ratios in the rapidly changing region around 90°. A commercial software package was used for nonlinear curve fitting (SigmaPlot, Jandel Scientific Software) to extract α and βL by fitting to Eq. (14). Peak PEM retardation δ0 was set to 3.469 rad to generate relatively large values of J0(δ0) and J2(δ0). Maximizing these coefficients ensures a large amplitude of the 2 f/dc signal variation as a function of θ. This in turn makes the curve fit more sensitive to changes in βL. In arrangement B, analyzer angles from −80° to +80° were chosen to capture a large range of 1f/dc ratios. From these data, and assuming a small value of α, a two-parameter fit of βC and βL can be performed using Eq. (15). It should be noted that the small assumption for α only affects βL, and the accuracy of the βC determination remains unchanged. It was also possible to make measurements at 2 f with this arrangement of the components. Using the same assumption of cos(2α)∼1, a single-parameter fit βL was performed on a plot of 2 f/dc vs θ [Eq. (16)] as a check of the fit from the 1f/dc plot. δ0 was set to 1.433 rad when collecting 1f/dc data and to 1.898 rad when collecting both 1f/dc and 2 f/dc data to generate relatively large values of Jn(δ0) in Eqs. (15) and (16). Again, large Bessel function values lead to more sensitive fits of the parameters. As a check for the consistency of the three fitting techniques [Eqs. (14 15 16)], the values of βL generated by each one can be compared. 4.Results and DiscussionFigure 2 shows results from a sample of 2 g/L suspension of 1.4 μm diam microspheres in pure de-ionized water. From a Mie scattering calculation,40 this corresponds to a scattering coefficient μs of 73.1 cm−1, scattering anisotropy g of 0.936, and reduced scattering coefficient μs ′ of 4.7 cm−1. The vertical axis in Figure 2(a) is the ratio of the lock-in amplifier photocurrent at 2 f (100 kHz) to the dc signal measured at mechanical chopper frequency of 150 Hz. Negative ordinate values correspond to negative phase reading of the 2 f signal on the lock-in amplifier. The PEM retardation δ0 was set to 3.469 rad to maximize the magnitude of the 2 f/dc ratio. The plotted points represents the experimental data ratios acquired with arrangement A; the line represents the theoretical best fit from Eq. (14). The fitting parameters were optical rotation α and the degree of linear polarization βL, and the best fit was obtained with α=(1.43±0.21)° and βL=(23.7±0.2), with the nonlinear regression goodness-of-fit parameter R2=0.9992. The quoted uncertainties represent standard deviations from the fitting routine. As seen from the close correspondence between experiment and theory, Eq. (14) describes the data well, and the values of α and βL derived appear to be reasonable ( α∼0°, βL<100, as would be expected for a turbid achiral sample). It is somewhat surprising that the optical rotation derived is not closer to zero; to investigate this further, we examined the specular reflection from a 45° metallic mirror placed on the sample platform (results not shown). This arrangement yielded α=(−0.08±0.21)° and βL=(100.0±0.2), with R2=0.9998, very close to the theoretical values expected. This result validated the accuracy of the methodology, and ensured sound operation of the optical, electronic, and analytical fitting systems. The apparent offset in α of ∼−1.4° from the microspheres-only turbid sample could be caused by some unknown sample birefringence or stray reflections from the cuvette walls. Although the true cause of this apparent optical rotation was not determined, its presence did not obscure interesting trends in α that resulted from increasing concentrations of chiral, achiral, and racemic molecules in the turbid suspensions. To obtain the degree of circular polarization βC, and to independently validate the derived value of βL, the same turbid microsphere sample was examined in arrangement B. The PEM retardation δ0 was set to 1.898 rad for this arrangement in order to maximize the magnitude of both the 1f/dc and the 2 f/dc ratios. Figure 2(b) shows the 1f/dc data ratios and the corresponding theoretical fit from Eq. (15). There are three unknowns in the fit, βC, βL, and α. As described in Sec. 2, the latter two always occur in combination βL⋅cos(2α), so they cannot be determined independently from this analysis. Fortunately, setting cos(2α) equal to unity resolves this ambiguity while introducing less than a ∼3 error in βL for even a reasonably large optical rotation of α∼4°. When this is done, a two-parameter nonlinear regression fit to the data in Figure 2(b) yields βC=(47.4±0.1), βL=(22.5±0.2), and R2=0.9997. The error in βL is actually somewhat larger because of the assumption of cos(2α)∼1; nevertheless, the degree of linear polarization obtained is in good agreement with the value obtained above for arrangement A in Figure 2(a). Of note is the much larger degree of circular over linear polarization preservation for this turbid sample. This preferential retention of circular polarization has been reported previously in turbid samples with predominantly forward-peaked single scattering phase functions.6 7 8 16 19 25 This is certainly the case for the current investigations, where Mie scattering calculations suggest that the 1.4-μm-diam polystyrene microspheres in water exhibit a scattering anisotropy parameter g∼0.94 at 632.8 nm, indicating predominantly forward scattering.40 The preferential retention of circular over linear polarization states is further explored below within the context of chiral, achiral, and racemic turbid suspensions (Figure 5 below). For completeness and a check of self-consistency, there is additional analysis that can be performed with arrangement B used in Figure 2(b). Figure 2(c) displays the 2 f/dc ratio obtained from the same experiment. The fit is performed using the expression in Eq. (16). Like above, the βL⋅cos(2α) combination precludes independent determination of α and βL. Again, assuming cos(2α)∼1, the one-parameter fit gives βL=(23.2±0.1), with R2=0.9989. This result further corroborates the degrees of linear polarization derived in Figures 2(a) and 2(b). We thus conclude that experimental arrangement B is better suited for an accurate determination of the degree of circular polarization βC and a reasonably accurate determination of the degree of linear polarization βL [by fitting the 1f/dc data to Eq. (15); βL can also be determined by fitting the 2 f/dc data to Eq. (16)]; if optical rotation is desired, the best approach is to remove the quarter wave plate and fit the resulting 2 f/dc data ratios to Eq. (14) like in arrangement A. Such a setup will also yield an accurate βL value, which can serve as an additional check of the slightly less accurate values βL derived with the λ/4 plate in place. Having thus determined optimal ways in which to determine βC, βL, and α, we examine the dependence of these derived parameters on the properties of the turbid samples. Specifically, the preservation of enhanced polarization in turbid samples caused by the presence of dissolved chiral molecules has previously been reported.25 27 28 30 Two putative explanations for this observed effect have been proposed. The electromagnetic (EM) wave propagation eigenmodes in a chiral medium are circular polarization states,41 and circular polarization has been shown to be preferentially preserved in a medium with strong forward anisotropic scattering.4 6 Alternatively, the solute-induced increase in the refractive index of the aqueous solution reduces the index mismatch of the suspended scatterers, making the samples less turbid23 24 and thus lowering the depolarization rates. To determine which explanation is correct, we examine the degrees of polarization of light scattered from turbid suspensions containing (i) chiral molecules, (ii) racemic mixtures of chiral molecules, and (iii) achiral molecules, while matching the refractive indices of the aqueous phase of the three sample types. Figure 3 shows the degree of linear polarization βL derived from measurements in arrangement A via Eq. (14). The three sets of symbols represent (i) 0–2 M L-arabinose chiral solution, (ii) a 50–50 L/D mixture of 0–2 M racemic arabinose solution, and (iii) 0–35 (v/v) glycerol achiral solution. The horizontal axis represents the resultant common refractive index of the solutions. The trend of increasing βL with an increase in the solution refractive index is clear, and it indicates that index matching lowers the turbidity of the medium and provides improved retention of linear polarization. For the range of refractive index values in Figure 3 over which the βL is seen to double from ∼23 to ∼45, the corresponding reduction in the scattering coefficients calculated from Mie theory is μs of 73.1 and 58.7 cm−1 (reduced scattering coefficient range μs ′ of 4.7 and 2.8 cm−1). Note that, for a given refractive index, the chiral versus achiral nature of the solute does not affect the preservation of linear polarization. It thus appears that the chiral nature of the dissolved molecules is unimportant in enhancing the degree of linear polarization, and the effect is entirely due to refractive index matching. Figure 4 summarizes the corresponding derived values of the optical rotation α as a function of the solution’s refractive index. These results are from the same data set and fit as those in Figure 3. There is a small offset of the optical rotations (approximately −1.5°) that we have not been able to explain nor eliminate. As well, the uncertainty in α is considerably greater than that in β as is evident by the size of the error bars in Figure 3. This indicates a much more sensitive dependence of functions in Eqs. (14 15 16) on β than on α. Nonetheless, of interest are the trends in optical rotation noted for each solute type. For both the racemic arabinose mixtures and the achiral glycerol solutions of equal refractive index, the optical rotation induced by the sample remained essentially constant, independent of the solute concentration. This was expected, since racemic mixtures and achiral solutes should not induce optical rotation. The apparent slight upward trend is probably related to the unexplained α offset noted above. For chiral solutions of L−(+) -arabinose, the optical rotation observed increased in a linear fashion with the concentration of solute. These results imply that the methodology developed is capable of measuring small optical rotations of linearly polarized light even in diffusive scattering. While the preservation of linear polarization is insensitive to the chiral nature of the molecules, measurements of optical rotation may reveal if the dissolved solute is chiral or achiral/racemic. Figure 5 shows the dependence of circular polarization βC and linear polarization βL as a function of the solution refractive index. These results are from experimental measurement with the quarter wave plate in place (arrangement B), analyzed with Eq. (15) at the 1f/dc signal, as per Figure 2(b). Both degrees of polarization are seen to increase by ∼23 in a strikingly linear fashion. Like in Figure 3, the surviving polarization fractions seems to be solely a function of the solution refractive index. Chirality of the solute had no visible effect on βL or βC. Again, this suggests that the increase in βL or βC is the result of a smaller difference between the refractive index of the solution and that of the suspended polystyrene microspheres. This smaller refractive index difference decreases the turbidity of the medium, resulting in less depolarization. The difference in levels of polarization preservation for linearly versus circularly polarized light is significant; the latter appears greater by approximately a factor of 2 across the entire refractive index range (corresponding to a scattering coefficient range of μs of 73.1–61.3 cm −1, and a reduced scattering coefficient range μs ′ of 4.7–3.1 cm −1 ). This preferential retention of circular over linear polarization states has been noted before in media composed of predominantly forward-scattering particles.4 6 7 16 19 25 In the current turbid samples, the anisotropy parameter g∼0.94, so scattering is certainly forward peaked, and the larger magnitude of βC compared to βL is not surprising. However, one must exercise caution in extrapolating these microsphere scattering results to biological tissues. The differences in the nature of refractive index variation in the two systems, including the potential contribution of dependent scattering, can lead to a variety of unexpected effects, including larger magnitudes of βL compared to βC. 16 19 Even within the microsphere system, the relative magnitude of the two depolarization parameters is predicted to depend sensitively on the size (and thus the scattering anisotropy) of the inclusions.7 8 Further studies are planned to measure βL and βC parameters in a variety of turbid systems, including those of biological origin. 5.Summary and ConclusionsA methodology for determining the optical rotation, the degree of linear polarization, and the degree of circular polarization of light diffusely scattered from turbid media was developed, and was applied to determine the cause of the previously reported chirality-induced increase in the preservation of polarization. The chiral nature of the dissolved solutes was only evident in the derived optical rotations, which were seen to increase linearly with chiral molecule concentrations but stayed essentially constant with increasing concentrations of achiral or racemic additives. The observed increase in the linear and circular degrees of polarization with dissolved solutes in turbid suspensions was caused by the refractive-index matching effect and was shown to be independent of the molecular chirality. Circularly polarized light was preserved to a greater extent (∼2×) than linearly polarized light in all turbid samples examined. The capability to measure polarization properties of multiply scattered light is exciting in that it yields several experimental observables which can be used to study and characterize turbid systems. Parameters such as optical rotation and the degrees of (linear, circular) polarization can be determined with high sensitivity even in the presence of a large depolarized background, for example, using polarization modulation and synchronous detection techniques. The potential sensitivity of these parameters to weak chiral asymmetries is important for conceptual and for practical reasons, such as noninvasive detection of chiral glucose molecules in turbid biological tissues. Much work remains to be done in the effort to determine the applicability of the methodology developed to this difficult clinical problem. The physiological concentrations of blood glucose is ∼1 g/L, hence the optical rotation for a typical physiological measurement would be ∼10−3 deg; this is ∼40× smaller than the current α detection limit estimated from Figures 2 and 4. However, chiral molecules also affect the derived degrees of linear and circular polarizations, so there may be ways of inferring glucose concentrations from β results as well.27 In future research we will address the optimal selection of experimental observables best suited for sensitive detection of small concentrations of chiral inclusions, the incorporation of tissue linear birefringence and spatial inhomogeneity into polarization models, and evaluation of the confounding effects of other optically active species present in biological media. AcknowledgmentsThe financial support of the Natural Sciences and Engineering Research Council of Canada (NSERC) and Photonics Research Ontario (PRO) is gratefully acknowledged. REFERENCES
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CITATIONS
Cited by 61 scholarly publications and 1 patent.
Polarization
Light scattering
Scattering
Refractive index
Molecules
Glucose
Mie scattering