1.

Introduction

Closed-head injuries (CHIs) are a type of traumatic brain injury in which the skull and dura mater remain intact. CHIs are usually caused by blows to the head and frequently occur in traffic accidents, falls, and assaults. CHIs can range from mild injuries to debilitating traumatic brain injuries and can lead to severe brain damage or even death.^1–6 Understanding neurophysiologic mechanism of brain function during CHI event can help the development of diagnostic strategies, optimize treatment, and improve therapeutic efficacy and the management of appropriate life saving care of head injuries. Computed axial tomography (CAT) and magnetic resonance imaging (MRI) are noninvasive imaging platforms used in the evaluation of head injury; however, the use of this instrument is expensive and cannot be used at the bedside for continuous monitoring.

To circumvent the above-mentioned clinical challenges, we used an alternative approach based on a diffuse light reflectance spectroscopy (DRS) paradigm because of its intrinsic sensitivity to tissue abnormalities and cerebral functions.^7–11 We reasoned that during CHI there are significant changes in the molecular concentrations of tissue chromophores, such as oxy- and deoxy-hemoglobin and water. These molecules absorb specific wavelengths of light, which alters the optical properties of the brain tissue. Hence, the goal of this research was to detect these alterations in the first critical hour of injury and quantitatively detect absolute cerebral hemodynamic and structural parameters. Compared to the above-mentioned MRI and CAT platforms, DRS is inexpensive and can be used repeatedly over a prolonged period of time with no adverse effects. It is also easy to maintain, offers high temporal resolution, and is useful for obtaining physiologic information continuously at the bedside.

DRS has been widely used so far to investigate both biochemical composition (chromophores’ content)^12–15 and morphologic (structural) information^16–18 about brain tissue in research laboratories as well as in clinical environments. In its simplest configuration, DRS includes a light source, detector (spectrograph), and a pair of flexible optical fiber probes separated by a fixed distance for delivery and collection of light during measurements. Light entering the tissue undergoes a combination of multiple scattering events (to the extent that it becomes randomized in direction) and absorption¹⁹ and the reflected light from the tissue, called diffuse reflectance ($R_d$), is recorded by the detector fiber. Generally, $R_d$ signal contains information about scattering and absorption components. With this context, it was shown that separation between the source and the detection points determines the sensitivity of the measured reflectance to the absorption coefficient (large separation distances) and to the scattering coefficient (short separation).^20–22 In the context of the aforementioned basic DRS operation, we present in this paper a different arrangement for measuring the diffuse reflected light during CHI. This arrangement resembles the spatially resolved steady-state diffuse reflectance setup;^23–25 however, it differs in its simplicity, in operation, and in handling. The principle of the proposed optical setup is to monitor indirectly the absorption coefficient in the near-infrared (NIR) spectral window (650 to 1000 nm) with no constraints through two steps and then translate it into absolute concentration and saturation of hemoglobin. The steps involve direct measurement of the reduced scattering coefficient in step 1 followed by measurement of the diffuse reflected light in step 2. A diffusion equation is then used to incorporate these steps revealing the absorption coefficient at different wavelengths, which is a key for obtaining physiologic cerebral hemodynamic parameters. Even though there are several ways to model $R_d$, in this work we used the two-source diffusion-based model as described by Farrel et al.²⁶ The use of diffusion theory is applicable here since the source–detector separation is $\sim 12\mathrm{mm}$, and the brain medium is very diffuse (absorption is very low compared to the scattering). The separation of absorption coefficient from the light scattering with this arrangement enables us to quantify tissue chemical constituents (related to light absorption), such as hemoglobin concentration and oxygen saturation and structural properties (related to light scattering) accurately.

We hypothesized that our orthogonal DRS can be utilized to detect changes in tissue chromophore compositions and structural changes in the brain in response to CHI. This major hypothesis has been based upon the rationale that any variations in physiological conditions as a result of injury is expected to cause differences or alterations in optical properties, which in turn provide significant changes in $R_d$. In this pilot study, we report on our experimental investigation on a CHI mouse model for supporting the above hypothesis. To the best of our literature search, very few studies have used optical modalities to investigate CHI. One such study was published recently by Yodh’s group following diffuse axonal injury, a type of CHI.²⁷ In that study, rotational head injuries in a neonatal piglet ($n=18$) were conducted, and diffuse correlation spectroscopy together with DRS was used noninvasively to monitor cerebral blood flow and hemodynamic parameters (hemoglobin concentration and oxygen saturation) before injury and up to 6 h after the injury.²⁸ Three main differences separate our study from the same: First, we use a simpler CHI model and optical setup, second the reduced scattering coefficient is determined with the aid of power-law wavelength dependence fitting whereas in Yodh’s work the scattering was assumed to be constant equal to $1/\mathrm{mm}$. To the best of our knowledge, this is the first report aimed at evaluating scattering properties changes in CHI with the help of DRS. Hence, information about the scattering power and amplitude, which are good markers of morphological variation, can be studied now. Third, cerebral hemodynamic parameters are reported here with their absolute concentration values. Although we were not able to monitor blood flow directly, an estimation of flow variations was obtained through total hemoglobin concentration (THC). THC tracks blood flow assuming the concentration of red blood cells remains constant. In this study, CHI was induced in anesthetized male imprinting control region (ICR) mice by weight-drop model onto the intact scalp, and an optical system monitors the diffuse reflectance and light scattering before injury and up to 60 min postinjury with a 10 min gap between measurements. Concurrently, vital physiological measurements were monitored for validation purposes.

2.

Materials and Methods

2.3.

Optical Instrumentation

Schematic of the system setup is depicted in Fig. 1(a). The setup consists of two wideband light sources, a bifurcated fiber optic probe placed in direct contact with the scalp surface, spectrometer, pulse oximeter, rectal probe, and a computer station with control software. The lamp inside the first light source (Stockler & Yale Inc., M1000) was replaced with a broadband quartz-tungsten halogen lamp (IT, 9596-ER) to give a smooth continuum broadband spectral profile along the NIR region and stable intensity over time. Optical fiber ($D=5\mathrm{mm}$) is connected to this light source placed on the scalp $\sim 1\mathrm{mm}$ from the surface of the head. The light emanating from the brain is delivered to the spectrometer (USB4000, Ocean Optics) via bifurcated fiber with external diameter of $D=1.3\mathrm{mm}$ mounted on the surface of the mice scalp orthogonal to the brain surface and hence perpendicular to the first light source fiber and the brain as well. The bifurcated fiber probe comprises two separate 400 µm core diameter fibers as follows: one fiber for light delivery from a light source (HL-2000-FHSA-LL, Ocean Optics) and a second fiber for light collection to the USB4000 spectrometer. The center-to-center separation between the source and detector fibers inside the probe is approximately 400 µm, which is schematically drawn in Fig. 1(b). The receiver fiber collects the diffuse reflected light in two different modes: Mode1 [Fig. 1(c)]: source–collector separation is $\rho =400\mu \mathrm{m}$ (reduced scattering coefficient,${\mu }_s^{\text{'}}$, sensitive) and Mode 2 [Fig. 1(d)]: source–collector separation is $\rho \approx 12\mathrm{mm}$ (absorption coefficient, ${\mu }_a$, sensitive). Consequently, at $\rho \approx 12\mathrm{mm}$ distance we relatively achieve deep sampling while at $\rho =400\mu \mathrm{m}$ we sample localized volumes (superficial layers). In that relation, as the distance between the source and detector decreases, we move from collection of multiply scattered light to collection of photons that experience few or single scattering events but with a lighter chance of absorption. We emphasized that once one of the light sources is operated (ON) the second source is blocked (OFF) and vice-versa. In this way of switching, we succeed in avoiding crosstalk between the two modes by sequentially operating. Hence, no overlap between measurements occurs and light scattering effect is separated from absorption. While the source-detector separation (SDS) in Fig. 1(c) is known (400 µm), the SDS in Fig. 1(e) was approximated as follows:

Eq. (1)

$${\mathrm{SDS}}_{\mathrm{mode}2}\approx \frac{1}{4}\times 2\pi \sqrt{\frac{d^2+h^2}{2}}.$$

The distances $d$ and $h$ are depicted in Fig. 1(e). The $1/4$ represents a quarter sector of the imaginary ellipse as shown in the figure. In this study, $d=10\mathrm{mm}$ and $h=1\mathrm{mm}$ reveal optical path $\approx 12\mathrm{mm}$. Please note that if we consider the brain as roughly spherical in shape, then the optical path (length of arc) can be calculated as $(\pi /2)\times R$, where $R$ is the mouse brain radius ($\sim 8\mathrm{mm}$). This product gives a length of $\sim 13\mathrm{mm}$. In both operation modes, the reflected signal is dispersed and detected by the charge-coupled device (CCD) array in the spectrometer. The spectrometer system has a 3648-elements linear CCD array ($8\times 200{\mu \mathrm{m}}^2$, pixel size) with 16-bit resolution and with a spectral range from 200 to 1100 nm. Optical fibers were connected to $x\text{-}y\text{-}z$ mechanical stage translation for position control, and care was taken to ensure full contact between the probes and the brain surface throughout the experiments. To the best of our knowledge, this is the first report of using this kind of DRS configuration, named orthogonal DRS, to evaluate brain chromophores and morphology during CHI.

Fig. 1

(a) Configuration of the orthogonal DRS (o-DRS) system. (b) Cross-section of the bifurcated fiber probe. (c) Schematic representation of Mode 1: scattering sensitivity. (d) Schematic representation of Mode 2: absorption sensitivity. (e) Illustration of the photon path from source No. 2 to detector in mode 2.

3.

Experimental Results and Discussion

Typical results of the trends in individual brain chromophores and reduced scattering properties ($A$, sp) over time after the CHI experiment obtained from a representative mouse are illustrated in Fig. 2(a). Please note that since the spectrometer acquired spectra every 250 ms, the data presented in Fig. 2(a) is the mean value of 20 spectra corresponding to 5 s measurement. The physiological (systematic) parameters, e.g., HR, arterial oxygen saturation, and body temperature are given in Fig. 2(b) left panel. In comparison, the HR was found to significantly decrease with time after CHI. In all tested animals these vital physiological parameters expressed the same profile. The effects of CHI on brain chromophore concentrations are clearly visible in Fig. 2(a); within the first 10 min after CHI, an increase of more than 15% in the ${\mathrm{HbO}}_2$, ${\mathrm{H}}_2\mathrm{O}$, and THC from the baseline measurement, respectively, was observed while the large increase was in Hbr, 55% from baseline following injury. As we progress in time, these percent changes continue to increase from the baseline. Under these conditions brain cells undergo a series of pathophysiologic changes; ultimately the injury is complicated by decreased oxygen supply as is detected by the decrease in the hemoglobin oxygen saturation (${\mathrm{StO}}_2$) by 10% from the baseline, contributing to secondary injury. It can be seen that the chromophore concentrations pre- and postinjury are distinct along the experiment duration postinjury. This observation enables one to take a representative measurement instead of long period of time to judge the physiologic status. As evidenced by directions of change in individual chromophore concentrations shown in Fig. 2(a), it can be seen that our setup is sensitive to quantitative tissue changes during CHI with time. These changes reflect the pathophysiologic state of the brain and our ability to quantify chromophore concentration during brain injury. Alteration in lipid is also observed after CHI and may be an indication of the dysregulation of lipid metabolism within brain cells. Altered lipid metabolism is believed to contribute to secondary brain injury, which occurs after traumatic brain injury.^47,48 However, from the entire study we found less than $5\%$ changes in lipid after CHI. Figure 2(a) further indicates variation in both scattering power (sp) and amplitude ($A$), respectively, suggesting that brain tissue scattering properties are also effected by brain injury and metabolism and highlight the morphological changes after CHI. The decrease in the scattering power with time after injury can be explained by an increase in the average scattering particle size. This could be the result of cellular and intracellular swelling in response to acute injury as confirmed by the increase in ${\mathrm{H}}_2\mathrm{O}$ content. To match the values of $A$ and sp in the graph, these parameters were multiplied here and in the following graphs for better presentation. Because of its high values, the logarithmic value of the scattering amplitude was taken and presented throughout the paper. For comparison, in Fig. 2(c) we present the same parameters as in Fig. 2(a), at the same time interval and protocol, obtained from a control (uninjured) mouse experiment. The differences in chromophores and scattering properties between the injured and the noninjured mouse are clearly demonstrated with these figures. In the results presented in Fig. 2(c), except for $A$ and THC (slightly), no significant fluctuations over time in ${\mathrm{HbO}}_2$, Hbr, ${\mathrm{H}}_2\mathrm{O}$, fat, and sp are observed, which reflects stability in measurements. The physiological parameters for the control mouse are given in Fig. 2(b) right panel. As can be seen, the biggest difference between the two is the HR value; about a twofold decrease in HR was observed for the control (anesthesia effect) while above a fourfold decrease was observed for the injured mouse. The decrease in HR in the injured mouse highlights, in addition to anesthesia, mostly the effect of the injury on the body. For completeness, the normalized reduced scattering spectra (i.e., ${{\mu }_{\mathrm{s}}}^{\prime }$ versus $\lambda$) measured pre- and post-CHI under different time intervals are provided in Fig. 3(a). It is interesting to observe the trend in sp (slope) after the injury; as we move from normal brain (baseline) to CHI the scattering slope becomes progressively flat with decrease of $\sim 60\%$ in sp compared to the baseline and then starts to increase back in time but remain lower than its baseline value. This behavior demonstrates the morphologic changes occurring in the brain and highlights the presence of cellular swelling within brain structure.^49–52 For comparison, in Fig. 3(b), we present the normalized reduced scattering spectra as obtained from the above control noninjured mouse. As expected, the spectral behavior displayed a similar trend, and scattering slope remains the same across the time, which confirms the results of Fig. 3(a) and the possibility of using the scattering properties as a marker of tissue in pathological injury.

Fig. 2

(a) Bar graph of chromophore concentrations and scattering properties of a representative mouse pre- and post-CHI in different time intervals. (b) Time-course of the vital physiological parameters for a control uninjured mouse (right panel) and for the representative mouse post-CHI (left panel). Note: $x$-axis appears in the left panel (injured mouse) represents the time post-CHI and the letter B represents the baseline. (c) Similar to (a); however, this new representative mouse did not experience injury. Please note that both $A$ and sp in graphs (a) and (c) were multiplied for better visualization.

Fig. 3

(a) Normalized reduced scattering spectra as measured by the setup of Mode 2 [Fig. 1(c)] for the injured mouse of Fig. 2(a). (b) Normalized reduced scattering spectra as measured by the setup of Mode 2 [Fig. 1(c)] for the noninjured mouse of Fig. 2(c).

We repeated the above single-animal experiment in 10 mice (Group 1) with the same setup and approximately similar body weights. Figure 4 shows bar graphs of the average and standard error of both chromophore concentration and scattering properties following CHI. Please note that the standard error or the variance in chromophore and scattering properties values may represent combinations of differences in tissue chromophores in individual mice, slight fluctuation in anesthetic state, etc. In the data presented in this graph, variations in chromophores and tissue morphology ($A$, sp) are clearly observed. These findings on chromophore variations are consistent with previous observation [Fig. 2(a)] and agree well with known directions of change with brain injury.^28,53–60 As evidenced by directions of change in individual chromophores shown, it can be seen that 10 min after CHI, all the chrompohores (except ${\mathrm{StO}}_2$) decreased and then showed a trend of gradually returning to the baseline level and continue to rise. This phenomenon may be related to the brain trying to overcome the stun effect of the injury. Note that the fat is the only constituent that does not change as dramatically as the others and approximately returns to its initial value preinjury. Our findings on water content variations after injury was also observed by Xie and coworkers (see Ref. 61, Table 2, p. 5411, Group 2) using the dry/wet weight method. They reported ${\mathrm{H}}_2\mathrm{O}$ of $78.08\pm 0.53\%$ 1 h after injury while here we report a content of $73.3\pm 5.1\%$ post-CHI. This very slight discrepancy in results might be explained by the different setup and theoretical approaches and by variation from different experimental conditions, although the numbers themselves indicate a general agreement with our experimental results. Additionally, the alterations in scattering parameters ($A$, sp), which reflects tissue anatomical injury during CHI, to our knowledge, have not been reported. By measuring scattering amplitude and power, one can get an impression of the degree of cellular injury in terms of cell swelling (edema) and membrane damage. With this context, the scattering amplitude versus the scattering power over time is plotted in Fig. 5(a) for Group 1 and for Group 2 in Fig. 5(b), respectively. Linear regression was used to compare the change in slope. Please note, each experimental data shown in each graph corresponds to a different time-point pre- and postinjury. As seen from both panels, the correlation between $A$ and sp is higher because of the coupling between these two parameters; however, the slope of the lines become different from the injured group ($\mathrm{slope}=0.68$) to the noninjured group ($\mathrm{slope}=0.52$), which indicates relationship changes or an unbalanced state between scatter density ($A$) and size (sp). Therefore, the slope between $A$ and sp can also be a possible indicator for detecting anatomical structure changes in injured brain. For a short presentation at the reader’s convenience, Table 1 summarizes statistical differences of specific time points of comparison in both chromophore parameters and scattering properties preinjury and 10 min and 1 h post-CHI, respectively, of Group 1.

Fig. 4

Bar graph summarizing the mean chromophore concentrations and scattering properties pre- and post-CHI in 10 mice. The results are presented as $\text{mean}\pm \mathrm{SE}$. Please note that both $A$ and sp were multiplied for better visualization.

Fig. 5

(a) Graph showing scattering amplitude ($A$) versus scattering power (sp) of Group 1 obtained from Fig. 4. High correlation between $A$ and sp was obtained with $R^2=0.99$ and slope of 0.68. (b) Graph showing scattering amplitude ($A$) versus scattering power (sp) of Group 2 (noninjured mice). High correlation between $A$ and sp was also obtained with $R^2=0.95$ and slope of 0.52. It should be noted that slope was increased by more than 20% after injury. In both panels, the broken line is the best-fit linear regression fits to the data [triangles in (a) and circles in (b)].

Table 1

Statistics comparing properties pre-CHI and 10 and 60 min post-CHI of Group 1. The standard error (SE) represents combinations of variations in experimental conditions, as well as differences in tissue properties in the individual mouse.

Based on our findings, the changes in chromophore content occur within the first 10 to 20 min, which highlights the early onset of cellular swelling and brain damage contributing to secondary damage. The rapid changes occurring within the first few minutes postinjury motivated us to explore the variation in brain physiology within this time interval. The same experiment protocol, setup, and approximately similar body weights was repeated in Group 3. Time-course of brain physiology is presented in Fig. 6. Immediately following CHI, ${\mathrm{HbO}}_2$, and THC levels increase while after 5 min a decrease is observed and then starts gradually to increase again. On the other hand, the Hbr level decreased and increased back 2 min after the injury. While in the previous figures a moderate decrease in ${\mathrm{StO}}_2$ over the course of the 60 min postinjury period was seen, in Fig. 6 a rapid decrease in oxygen saturation was observed reflecting the progressive trauma (stun effect, secondary injury, and/or edema) to the brain in the first few minutes following CHI. As shown, 1 min from the onset of injury a rapid increase in saturation was observed. This phenomenon can be explained by the fact that over a millisecond after injury the dysfunction of intra/extracellular tissues stimulates the brain to increase oxygen supply and blood flow as expressed by increase in oxyhemoglobin and THCs (resulting in postinjury hyperemia). This finding seems to be reasonable as it indicates a larger demand for oxygen and blood following the injury. However, the ability of the brain to recuperate following a CHI period seems to decrease as the injury duration increases, which may be an indication of a damaged mechanism of autoregulation and inability of the blood supply to get to the damaged area, which is influenced from the injury duration. This implies that the damage will expand to the entire brain as injury duration becomes longer and the lack of ability of the brain for self-recovery with the increasing duration of injury. The fluctuations in chromophores also can be explained by the fact that after injury a cascade of metabolic changes promotes the development of secondary brain damage and the reaction of brain to injury can be observed by the increase and decrease in chromophore concentrations over time. Also here, the fat is the only chromophore that exhibits minor change less than 3% from its baseline. As mentioned above, the fluctuation in fat may be an indication of changes in lipid metabolism. In Fig. 7(a) and 7(b) the changes occurred in both $A$ and sp are presented. Postinjury these two parameters were increased acutely, but after 3 min they both started to decrease gradually returning toward baseline level. This turning point in time was found to be earlier than that of the chromophores (5 min) and demonstrates that scattering variations (structural changes—cell density, morphological size, and shape) occur prior to the absorption process (hemodynamics changes) following CHI. In Fig. 7(c) the scattering amplitude versus the scattering power over time is presented. As we observed previously in Fig. 5, a linear relationship with high correlation and slope of 0.68 were obtained and now highlight our previous conclusion that the slope can also be a good indicator for detecting anatomical disorders.

Fig. 6

Responses of brain hemodynamic properties following CHI for Group 3. The results are presented as $\text{mean}\pm \mathrm{SE}$. Please note that the mice ($n=5$) with this experiment were not included in the previous experiments. Note: the $x$-represents the time post-CHI and the letter B represents the baseline.

Fig. 7

(a) Responses of brain morphology properties following CHI for Group 3. The results are presented as $\text{mean}\pm \mathrm{SE}$. These are the same mice group of Fig. 6. (b) Scattering amplitude ($A$) versus scattering power (sp). High correlation between the two is seen with $R^2=0.99$ and slope of 0.68. Note: the $x$-axis represents the time post-CHI and the letter B represents the baseline.

Generally speaking, CHI often creates zones of damage: a core area with severe damage and peripheral regions with moderate damage (analogous to penumbra in ischemic strokes). Because of our system configuration, the results of chromophores are influenced by the combination of both regions (volume effect) while scattering was affected mainly from the core zone. This may be a possible explanation of the difference in behavior between chromophores and structural changes and the fact that tissues with different degrees of injury will have different oxygenation states. Another source of the differences may be related to the fact that slight changes in positioning angle of the fiber probe can affect the NIR reflectance signal reading and hence the optical properties. As we mentioned in the Introduction, by assuming constant hematocrit concentration, THC can be considered as a good estimator of the concentration of blood vessels and blood flow. Since we sample diffuse zones of injury at a single measurement it is hard to conclude about the spatial brain blood flow trends. Overall, the above results and discussions monitored with our setup highlights our ability to quantify hemodynamic state and morphological variations associated with brain injury and can add valuable information and understanding regarding brain tissue in CHI suffering patients.

4.

Conclusion

CHI is a traumatic state in which the brain is injured as a result of a mechanical blow to the head, or a sudden, violent motion that causes dynamic shifts of the brain within the skull. The current study verifies the utility and ability of o-DRS for monitoring brain physiological properties occurring during CHI. Experiments were validated on intact mice brains of a total of 26 mice (11 control, 15 injured). Our results indicated, as we hypothesized, that CHI caused changes in both optical properties of the brain tissue and consequentially cause distinctive variations over time (up to 1 h) in both chromophore concentrations and structural changes (scattering properties) in response to CHI. These results are consistent with known directions of physiological changes mentioned in the literature regarding brain trauma. In addition, we demonstrate a good correlation between the scattering amplitude ($A$) and scattering power (sp) and found clear change in slope in comparison to the noninjured group of mice. Although these pilot results are preliminary, we believe that the slope between $A$ and sp can also serve as a good marker for injury. To the best of our knowledge, this is the first report aimed at evaluating scattering amplitude and power following CHI using o-DRS. The use of DRS is not new; however, the current system separates us from other groups in its configuration and our ability to separate light absorption from scattering effect in a more simple and inexpensive manner. Finally, experiments following 20 min postinjury were conducted with a gap of 1 min between measurements and results fairly resembled what we observed up to 1 h. However, a rapid decrease in oxygen saturation was observed and reflects the gradual trauma of the brain and its distress during the first minutes of injury. To sum up, the obtained results outlined here provide a proof-of-principle for the application of the aforementioned o-DRS modality in its ability to quantitatively provide information regarding the brain function following injury and potentially could be used in clinical practice. One should keep in mind that typical mean free path to an NIR absorption event in tissue is $\sim 10\mathrm{cm}$, while scattering length is $\sim 20$ to 40 µm. These numbers stand well with our setup, for example, in an adult human head where perpendicular positions of source and detector would bring very large separation ($\sim 10\mathrm{cm}$). Nonetheless, high sensitive detectors and the use of a supercontinuum laser source for measurement of wide spectrum will be needed in order to increase the signal-to-noise ratio. These requirements, on the contrary, are unnecessary for monitoring an infant’s head because of the relative small SDS. With the advantage of the simplicity and efficiency of this technique, o-DRS can also be applicable for other medical applications in which light is used for noninvasive diagnosis.