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Nondestructive evaluation of progressive neuronal changes in organotypic rat hippocampal slice cultures using ultrahigh-resolution optical coherence microscopy

Nondestructive evaluation of progressive neuronal changes in organotypic rat hippocampal slice... Three-dimensional tissue cultures have been used as effective models for studying different diseases, including epilepsy. High-throughput, nondestructive techniques are essential for rapid assessment of diseaserelated processes, such as progressive cell death. An ultrahigh-resolution optical coherence microscopy (UHROCM) system with 1.5 m axial resolution and 2.3 m transverse resolution was developed to evaluate seizure-induced neuronal injury in organotypic rat hippocampal cultures. The capability of UHR-OCM to visualize cells in neural tissue was confirmed by comparison of UHR-OCM images with confocal immunostained images of the same cultures. In order to evaluate the progression of neuronal injury, UHR-OCM images were obtained from cultures on 7, 14, 21, and 28 days in vitro (DIVs). In comparison to DIV 7, statistically significant reductions in three-dimensional cell count and culture thickness from UHR-OCM images were observed on subsequent time points. In cultures treated with kynurenic acid, significantly less reduction in cell count and culture thickness was observed compared to the control specimens. These results demonstrate the capability of UHR-OCM to perform rapid, label-free, and nondestructive evaluation of neuronal death in organotypic hippocampal cultures. UHR-OCM, in combination with three-dimensional tissue cultures, can potentially prove to be a promising tool for high-throughput screening of drugs targeting various disorders. © 2014 Society of Photo-Optical Instrumentation Engineers (SPIE) [DOI: 10.1117/1.NPh.1.2.025002] Keywords: organotypic; neuron death; optical coherence microscopy; image segmentation. Paper 14047PRR received Apr. 21, 2014; revised manuscript received Jul. 22, 2014; accepted for publication Jul. 25, 2014; published online Sep. 2, 2014. Introduction Three-dimensional (3-D) tissue cultures and constructs, also called organs-on-a-chip, are being increasingly used to model functions of different organs in healthy and diseased states.1 A major application area of these model systems is high-throughput drug discovery.2 This application is enabled by the development of techniques for rapid assessment of disease-related processes in tissues. The rapid evaluation of the number of cells in the tissue is of particular importance in neurological applications, where death of neuron populations is a major hallmark of injury, stroke, epilepsy, Parkinson's, Alzheimer's, and other disorders. 3-D tissue cultures of hippocampus, also known as organotypic hippocampal cultures,3 have recently been used to model the development of epilepsy,4,5 a common neurological disease that affects 1% of the population.1 Organotypic hippocampal cultures model major events of human epilepsy: initial brain injury with immediate loss of some neurons, followed by a latent period with low or normal levels of neural activity and little to no neuron death, and the subsequent development of electrographic seizure activity accompanied by progressive neuron death.5 This model of epilepsy has been used for high-throughput discovery of drug targets with the goal of developing drugs that can prevent development of epilepsy or modify its course.4 The relationship between neuron death and seizures is complex: traumatic brain injury is one of the major causes of epilepsy; however, uncontrolled seizures can also cause progressive neuron loss.5 The prevention of neuron loss, or neuroprotection, during all stages of the disease, is an important property that an antiepileptic drug may possess. Neuroprotection may occur in the initial stages of the disease, leading to more neurons surviving the initial injury, or, in later stages, by preventing seizuredependent neuron death. It is, therefore, important to evaluate changes in the number of neurons in these 3-D cultures over time. The method to evaluate neuron numbers must also be rapid to enable high-throughput drug discovery. Current methods to evaluate neuroprotection in organotypic cultures include confocal microscopy to image surviving or dead neurons, and the measurement of lactate dehydrogenase (LDH) that is released by dying cells.4,6 Confocal microscopy can provide a highly accurate evaluation of neuron viability and death in organotypic cultures, but high-resolution imaging of 3D tissues is a time-consuming process that reduces experimental throughput. Evaluation of surviving neurons requires the use of staining agents that prohibit the use of the same specimens for longitudinal studies. On the other hand, LDH measurement is *Address all correspondence to: Chao Zhou, E-mail: chaozhou@lehigh.edu 0091-3286/2014/$25.00 © 2014 SPIE 025002-1 rapid, but cannot provide information on potentially different levels of neuron death in hippocampal subregions. Optical coherence tomography (OCT), an emerging noninvasive imaging modality, provides 3-D and micron-scale resolution images of biological samples without exogenous contrast agents.7 OCT has been used to monitor brain function of rat somatosensory cortex,8,9 quantify cerebral blood flow,10­12 and intracellular motility in rodent cerebral cortex.11 Optical coherence microscopy (OCM) is an extension of OCT and provides cellular image resolution using high numerical aperture (NA) objectives.13,14 In addition to the advantage of label-free imaging, OCM provides greater imaging depth and faster imaging speed compared to confocal microscopy. OCM has been used to image pathological specimens,15­20 characterize angiogenic sprouting in artificial blood vessels,21 visualize cerebral -amyloidosis in mouse models,22 and recently to quantify the neuron number and morphology in a live rat cortex.23,24 In this study, we aimed to demonstrate the feasibility of OCM imaging for a nondestructive evaluation of neuronal morphology and quantification of the neuron count in organotypic brain cultures. An ultrahigh-resolution OCM (UHR-OCM) system was developed and used to nondestructively image rat organotypic hippocampal slices. UHR-OCM images were compared to confocal images from the same brain slices in order to identify characteristic imaging features associated with viable cells. A custom cell counting algorithm was developed to quantify cell numbers in 3-D OCM and confocal images. A good linear correlation (R2 ¼ 0.89) for cell count was observed using two imaging modalities. Once the correlation was established, UHROCM imaging was used to evaluate the morphological changes in the brain slices associated with spontaneous seizures. A significant reduction of the total cell count and slice thickness were measured from organotypic brain slices on 7, 14, 21, and 28 days in vitro (DIV). Finally, kynurenic acid- (KYNA, a glutamate receptor antagonist that has antiexcitotoxic and anticonvulsant properties25­27) treated brain slices were compared to the control slices in order to evaluate the effects of KYNA on the hippocampal slices. These results suggest that UHR-OCM is a promising imaging tool that can be used for a nondestructive characterization of morphological changes in organotypic brain cultures. medium changes. All animal use protocols were approved by the Institutional Animal Care and Use Committee at Lehigh University and were conducted in accordance with the U.S. Public Health Service Policy on Humane Care and Use of Laboratory Animals. Ultrahigh-Resolution OCM An ultrahigh-resolution OCM system was used to image all the brain slices. Details of the system are described elsewhere.21 Briefly, a supercontinuum light source (SC-400-4, Fianium Ltd., Southampton, United Kingdom) with a center wavelength of 800 nm and bandwidth of 220 nm was used to provide 1.5 m axial resolution in the tissue. A 175-deg conical lens22,28 was used in the sample arm to provide an extended depth of focus of 200 m and the transverse resolution of 2.3 m at focus, 2.5 m at 40 m, and 3.1 m at 90 m above or below the focus with a 10× Olympus objective. The sensitivity of the OCM system was measured to be 90 dB with 3 mW power on a sample at 20,000 A-scans/s image speed. Before imaging, the organotypic hippocampal culture was removed from the incubator and gently placed in a Petri dish with a thin bottom (200 m). The slice was immersed in the culture medium at room temperature during imaging. The OCM system was configured as an inverted microscope in order to image the sample from the bottom. The focus of the OCM was put consistently 100 m above the bottom surfaces of all hippocampal slices. An imaging range of 1.8 × 2.1 mm2 was used to cover the entire brain slice with 800 × 800 axial scans per volume. A 3-D OCM data set was acquired in 40 s. Six repeated scans were performed for each brain slice and averaged in order to reduce speckle noise and improve the signal-to-noise ratio of the OCM images. Confocal Microscopy Materials and Methods Preparation of Organotypic Hippocampal Slice Cultures The slices with a thickness of 350 m were dissected from the hippocampus of seven-day-old Sprague-Dawley rats (Charles River Laboratories). After the dissection, all slices were maintained in a culture medium, which was a mixture of NeurobasalA, GlutaMax, Gentamicin (Life Technologies, New York), insulin, sodium selenite, and bovine serum albumin (Sigma, St. Louis). All slices were maintained at an air­culture interface and incubated in humidified 5% CO2 at 37°C. The culture medium was changed biweekly. For neuroprotection experiments, the KYNA solution (KYNA, Phenol red, and Gey's balanced salt solution) was added to the regular culture medium to achieve 3 mM final KYNA concentration in the KYNA group, and vehicle solution (Phenol red and Gey's balanced salt solution) was added to the regular culture medium in the control group after three DIV. KYNA and vehicle solutions were added to each batch of the fresh culture medium for biweekly For the validation experiments, organotypic hippocampal cultures were fixed immediately after OCM imaging with a mixture of 4% paraformaldehyde in phosphate buffered saline (PBS). After 2-h fixation, cultures were washed with PBS, permeabilized in 0.3% Triton X-100 in PBS and blocked with 10% goat serum in PBS. The cultures were then incubated with anti-NeuN antibody (NeuN is a neuron-specific nuclear protein) conjugated with Alexa Fluor 555 overnight at 4°C. Following the antibody incubation, cultures were washed and mounted for imaging. A laser scanning confocal microscope (Zeiss LSM 510 META, Jena, Germany) was used with a 5× and a 40× objective lens for sample localization and imaging, respectively. The cultures were illuminated from the same side with the confocal microscope in order to have consistent imaging with OCM. The excitation wavelength of the confocal microscope was 543 nm. Since imaging depth of the confocal microscope is limited, 3-D confocal image stacks were obtained only from the first 80 m from the tissue surface. With the 40× objective, each 3-D confocal stack (318 m × 318 m × 80 m) was acquired in 270 s by translating the specimen at 1-m step in the z-direction. Forty-two 3-D confocal stacks were acquired with 10% overlaps between stacks in order to cover the entire culture (2.0 mm × 2.7 mm × 80 m). A stitching program based on Fiji, an extension of ImageJ, was used to stitch individual 3-D confocal stacks into a completed 3-D image set of an entire brain slice. It took 8 h of imaging to complete one 3-D confocal stack for each culture. 025002-2 Identification and Quantification of Viable Cells in 3-D OCM and Confocal Images 3-D OCM images were compared to the 3-D confocal images obtained from the same cultures. Since the anti-NeuN antibodies used for confocal microscopy specifically bind to neuronal nuclei, individual neuronal nuclei were clearly seen on the confocal images [Figs. 1(b) and 1(d)]. In comparison, individual neurons were clearly identified in OCM images as hyposcattering circular regions with well-defined boundaries [Figs. 1(a) and 1(c)]. We were able to observe one-to-one matching of individual neurons in OCM and confocal images obtained from the same brain slice [Figs. 1(c) and 1(d)]. The well-defined boundaries observed in individual neurons suggested that neuronal membrane integrity had not been compromised. This was used as an indicator for neuron viability in our study. Based on these imaging features, we developed a MATLAB®-based algorithm to automatically identify and count cells in 3-D OCM and confocal image stacks. The key concepts were demonstrated in Fig. 2, using OCM images as examples. First, an intensity threshold was applied on the en face OCM image to generate a masked image showing only the hyposcattering regions. In parallel, a template image showing a dark circular region within a white background [Fig. 2(d)] was moved across the en face OCM image to calculate correlation coefficient values for all the pixels. The optimal thresholds for the template size (L ¼ 15 m) and the radius of the circle (R ¼ 6 m) were determined to match the size of the neuron and achieve the highest correlation coefficients. A second masked image was generated showing only regions with correlation coefficient values above a threshold. The two masked images were then multiplied. A third threshold was applied to generate a mask highlighting regions with both low intensity and high correlation coefficients from the en face OCM image. Next, all the masks from different depths were combined to form the 3-D mask stack. A 3-D watershed algorithm was applied to the stack in order to segment and identify individual neurons in the volume.29 A 3-D size filter was then used to remove objects identified by the watershed algorithm that were too small or too large for a neuron. Finally, the cells identified by the algorithm were marked on en face and 3-D OCM images as red dots/spheres [Figs. 2(e) and 3(a)] in order to facilitate visualization of the identified cells. The number of cells in 3-D image stacks was then automatically counted. All the threshold values were optimized to obtain a maximum neuron count while minimizing false positive identification of neurons by visual inspection of the 3-D imaging stacks. The same algorithm was used to quantify cell numbers in 3-D confocal stacks, except that different but optimized template image and threshold values were used. Since neurons presented as white spheres in black background in confocal images Fig. 2 (a) En face OCM image of an organotypic slice on DIV 7. (b) Magnified image of the brown rectangular region in (a). Individual neurons were clearly observed as well-defined hyposcattering circular regions. (c) An individual neuron corresponding to the neuron marked with dashed circle in (b). (d) A representative template image (L ¼ 15 m, R ¼ 6 um) used to calculate correlation coefficient values across en face OCM images. (e) En face OCM image corresponding to the region shown in (b) with neurons identified by the algorithm marked as red dots. Scale bars: 400 m in (a), 10 m in (c), 100 m in (b) and (e). Fig. 1 Ultrahigh-resolution optical coherence microscopy (OCM) image (a) and confocal image (b) from the same organotypic hippocampal culture on day in vitro DIV 7. (c) and (d) are magnified images of regions indicated by brown rectangular boxes in (a) and (b), respectively. Circles in (c) and (d) highlight corresponding individual neurons in OCM and confocal images. CA1-sub, cornuammonis I--subiculum; CA3, cornuammonis III; DG, dentate gyrus. Scale bars: 400 m in (a) and (b), 100 m in (c) and (d). Fig. 3 Three-dimensional (3-D) rendering reconstructed using OCM images (a) and confocal images (b) obtained from approximately the same region of a hippocampal culture with neurons marked as red spheres. 025002-3 [Figs. 1(b) and 1(d)], the template image was bright inside and dark outside for confocal images. Due to limited imaging depth for confocal microscopy, the quantification of cell numbers was only performed from the first 60 m of the slice surface. The quantification of cell counts in OCM was only performed in the matching depths for the three brain slices imaged with both confocal and OCM. For all other brain slices imaged with OCM, total cell counts were obtained in the first 150 m depth from the tissue surface, where the image resolution was the highest. To determine the sensitivity of the OCM imaging technique to count neurons, three matching regions [525 m × 525 m × 15 m, one from the left corner of Fig. 4(a), one from the right corner of Fig. 4(a), and one from another sample] from 3-D OCM and 3-D confocal images were used for comparison. The cells identified from confocal microscopy were used as the gold standard for neurons, since neuron-specific anti-NeuN antibodies were used. After merging the OCM and confocal en face projections, cell counts obtained by both techniques were determined manually. The sensitivity, false negative rate, and positive predictive value for OCM to identify neurons were calculated. Since there was no measurement of non-neuronal cell counts from confocal microscopy, the specificity and false positive rate values were not determined. Statistical Analysis For the validation experiment, 3-D OCM and confocal stacks were divided into four matching quadrants as shown in Figs. 4(a) and 4(b). Cell counts with OCM and confocal were obtained in the 12 independent quadrants from the three brain slices. A linear regression was performed to correlate cell counts measured with OCM and confocal microscopy. The R2 value, the best-fitting line, and the 95% confidence interval (CI) of the slope for the fitting line were calculated. For all the other experiments, the cell count and slice thickness in the CA1-sub and CA3 regions were measured from each brain slice. Group results were summarized as mean Æ SEM. A student's t test was performed to compare results from different experimental groups. A p value of <0.05 was used to indicate statistically significant changes between groups. Results and Discussion Nondestructive Imaging and Quantification of Individual Neurons Using UHR-OCM Brain Slice Thickness Measurements The thickness of the brain slices was also measured from the OCM images in order to characterize the time course of morphological changes. The thickness measurements were performed on cross-sectional OCM images in cornuammonis I, subiculum (CA1-sub), and cornuammonis III (CA3) regions. The average thickness from all axial scans within regions of interest selected from CA1-sub (570 m × 970 m on en face OCM) and CA3 (900 m × 450 m on en face OCM) was calculated after excluding thickness measurements of < 150 m to avoid measurements from the sample boundaries. Figure 1 compares the representative en face OCM and the confocal images of the same organotypic hippocampal culture from the same imaging depth. The same neuronal layers in the dentate gyrus, CA1-sub and CA3 regions of hippocampus, were clearly observed from the en face OCM image [Fig. 1(a)] as well as from the confocal image [Fig. 1(b)]. The same individual neurons can be easily identified from the enlarged OCM [Fig. 1(c)] and the confocal [Fig. 1(d)] images. The hyposcattering and circular features presented in individual neurons were consistent with previous observations with OCM from other research groups.23,24 The low backscattering intensity within the neuronal regions observed in OCM could be partially due to the relatively homogeneous refractive index property within the neuronal nuclei.24,30 This experiment identified neuron features in OCM and established the foundation for developing the algorithm Fig. 4 Corresponding OCM image (a) and confocal image (b) from the same organotypic slice on DIV 7. Brown dashed lines split OCM image and confocal image into four quadrants. (c) and (d) show the lower right quadrant of OCM image in (a) and confocal image in (b), respectively. (e) Also see (Video 1, MOV, 2.13 MB) [URL: http://dx.doi.org/10.1117/1.NPh.1.2.025002.1] for 3-D OCM rendering and (f) Also see (Video 2, MP4, 7.83 MB) [URL: http://dx.doi.org/10.1117/1.NPh.1.2.025002.2] for 3-D confocal rendering) label well-defined (viable) neurons as red dots in OCM and confocal images, respectively. (g) Regression line showing linear correlation (R 2 ¼ 0.89) between neuron count obtained from OCM and confocal images. Scale bars: 400 m in (a) and (b) 200 m in (c) to (f). 025002-4 described above for automatic identification and counting of viable neuron numbers in the brain slices. The same culture was divided into four quadrants in the OCM and the confocal image stacks [Figs. 4(a) and 4(b)]. Individual viable cells were automatically identified based on the algorithm described above and marked in the 3-D imaging stacks for both OCM and confocal [Figs. 4(c) to 4(f) show the lower right quadrant of the specimen, also see Videos 1 and 2 for 3-D rendering]. A very good linear correlation (R2 ¼ 0.89) was observed between the cell counts obtained from OCM and confocal microscopy [Fig. 4(g)]. The slope of the best-fitting line was 1.25, with a 95% CI of 0.94 to 1.57. For the detailed comparison of cell counts in OCM and confocal images, 200, 243, and 303 cells were identified in both imaging modalities from the three matching brain regions, respectively. There were 72, 79, and 67 cells identified from OCM images only, and 55, 82, and 93 cells were identified from confocal images only from the three regions, respectively. Table 1 summarizes these comparison results. Using the cells identified from confocal microscopy as the gold standard, OCM had a sensitivity of 76.4% to identify neurons. OCM missed 23.6% (false negative rate) of neurons compared to confocal microscopy. This was partly due to the limited resolution of OCM to differentiate small and clustered neurons [e.g., the lower left quadrant of Fig. 4(a)] and imperfect match in depth for OCM and confocal images (tissues may have been slightly distorted by fixation prior to immunostaining). The false positive cell count from OCM could be due to the detection of glial cells (not stained with the anti-NeuN antibody and, thus, not appearing in confocal counts) and counting errors of the algorithm. As a result, a positive predictive value of 77.4% was obtained. The actual specificity and false positive rate values could not be determined due to a lack of non-neuron-specific cell counts from confocal microscopy. However, since brain tissues may contain up to 10 times as many glia cells as neurons, a cell count obtained from OCM seems to be neuron-specific, especially considering that only the intrinsic scattering contrast was utilized in OCM imaging. These results demonstrated that UHR-OCM could be used to provide viable cell count in brain slices without the destructive fixation and staining processes involved using standard confocal microscopy. The imaging time for UHR-OCM is also short (a few minutes for each 3-D stack), making high-throughput evaluation of the samples possible using OCM. Other groups have demonstrated OCM imaging of individual neurons in rat cortex in vivo.23 A high-magnification objective lens (40×) was used in the OCM system to achieve submicron transverse image resolutions (0.9 m).23 However, the depth of focus of the OCM system (3.8 m) was very limited due to the high numerical aperture of the objective lens. As a result, the focal plane had to be translated to acquire multiple OCM data sets in order to obtain 3-D images from the rat cortex, which resulted in slow imaging speed. In our UHR-OCM system, a supercontinuum light source was used to provide 1.5 m axial resolution. A lower magnification objective lens (10×) and a conical lens were used to achieve 2.3 m transverse resolution over 200 m imaging depth. With this configuration, we were able to acquire ultrahigh-resolution images of the entire brain slice without translating the focus in tissue. The parallel depth imaging capability of OCM was utilized to significantly improve imaging speed compared to previous studies. Evaluation of Progressive Neuronal Injury in Organotypic Brain Slices using UHR-OCM Table 1 Comparison of number of cells identified in confocal and optical coherence microscopy (OCM) images from three matching brain regions. Cells identified in confocal Cells identified in OCM Cells not identified in OCM Sensitivity False negative rate Positive predictive value 746 Cells not identified in confocal 218 In this experiment, UHR-OCM images of the hippocampal brain slices were obtained on DIV 7 (n ¼ 18), DIV 14 (n ¼ 11), DIV 21 (n ¼ 18), and DIV 28 (n ¼ 9) in order to evaluate the progression of neuronal injury. Figures 5(a) to 5(h) compares representative en face OCM images from slices on different DIV. As shown more clearly in Figs. 5(e) to 5(h), neuron boundaries became diffusive and image contrast was reduced as DIV increased, suggesting the membrane integrity of some neurons in the slice cultures was compromised. The number of viable cells significantly decreased as DIV increased [Fig. 5(i)]. Compared to DIV 7, significant reductions in cell counts of 23.1% (p < 0.001), 33.7% (p < 0.001), and 45.8% (p < 0.001) were observed on DIV 14, DIV 21, and DIV 28, respectively. The largest reduction (23.1%) in cell count was observed between DIV 7 and DIV 14, suggesting neuronal injury was highest during this time period. Measurements of slice thickness also showed continuous decreases in both the CA1-sub and the CA3 regions as DIV increased [Figs. 6(a) to 6(e)]. In CA1sub, reductions in slice thickness of 1% (p ¼ 0.82), 12.0% (p < 0.001), and 19.3% (p < 0.001) were observed on DIV 14, DIV 21, and DIV 28, respectively, while in CA3, reductions of 2.7% (p ¼ 0.54), 13.5% (p < 0.001), and 16.1% (p < 0.001) were observed on DIV 14, DIV 21, and DIV 28, respectively. The decreasing trend in slice thickness was consistent with the trend in cell counts as DIV increased. The percentage of thickness reduction was less than the cell count reduction, suggesting that neuron loss may not be the only mechanism that contributes to changes in slice thickness with culture age. 230 -- Evaluation of Treatment Effects of KYNA to Hippocampal Slice Cultures 746ð746 þ 230Þ × 100% ¼ 76.4% 230ð746 þ 230Þ × 100% ¼ 23.6% 746ð746 þ 218Þ × 100% ¼ 77.4% Our previous work has demonstrated that seizures occur spontaneously in organotypic hippocampal slice cultures and lead to neuron death.6 KYNA reduces the amount of neuron death in the brain slices.31 Figures 7(a) to 7(h) compare representative en face OCM images obtained from the control and KYNA-treated brain slices at DIV 7 (n ¼ 9) and DIV 21 (n ¼ 9), respectively. In the control group, significantly fewer cells with well-defined 025002-5 Fig. 5 Representative OCM images obtained from different cultures on (a) DIV 7, (b) 14, (e) 21, and (f) 28, respectively. The representative OCM images were obtained from a depth of 50 m from the slice surface. (c), (d), (g), and (h) are the magnified images of the brown rectangular regions in (a), (b), (e), and (f), respectively. Viable neurons are marked as red dots. (i) Total viable neuron counts from the first 150 m of the organotypic hippocampal cultures from different DIVs. ***p < 0.001. Scale bars: 400 m in (a), (b), (e), and (f), 200 m in (c), (d), (g), and (h). boundaries were observed on DIV 21 (n ¼ 9) compared to DIV 7 (n ¼ 9) [Figs. 7(a) to 7(d)]. The reduction of well-defined cells in the KYNA group was less dramatic on DIV 21 compared to DIV 7 [Figs. 7(e) to 7(h)]. The quantification of cell numbers in the two groups [Fig. 7(i)] further confirmed the observations from visual inspection of the OCM images. A significant reduction of 40.3% in cell counts (DIV 21 versus DIV 7, p < 0.001) was observed in the control group, while a reduction of 20.0% in cell count (DIV 21 versus DIV 7, p < 0.05) was observed in the KYNA group. Viable cell count was similar in the two groups on DIV 7 (p ¼ 0.35), but was significantly lower (19%, p < 0.05) in the control group compared to the KYNA group on DIV 21. Figures 8(a) to 8(d) compare the representative cross-sectional OCM images from the CA3 regions of the brain slices from the control and the KYNA groups. The slice thickness measured from the CA1-sub and CA3 regions [Fig. 8(e)] was significantly smaller on DIV 21 compared to DIV 7. In the control group, thickness reductions of 12.0% (p < 0.001) and 13.3% (p < 0.001) were observed in the CA1-sub and CA3 regions, respectively. In the KYNA group, thickness reductions of 8.6% (p < 0.05) and 8.0% (p < 0.05) were observed in the CA1-sub and CA3 regions, respectively. The reduction of slice thickness was consistent with the trend observed in the cell counts. Our results clearly showed that progressive neuron death and the neuroprotective effect of KYNA could be observed by UHROCM. The data were in agreement with our previous observations that used confocal imaging of propidium iodide uptake and LDH release as markers of neuron death.5 UHR-OCM was validated as a powerful tool for label-free, live evaluation of organotypic brain cultures. The quantitative information, such as cell counts and slice thickness, could be obtained from 3-D UHROCM images. Due to the high imaging speed of OCM, it is possible to use OCM and 3-D tissue culture disease models for high-throughput drug discovery for disorders where evaluation of progressive changes in cell numbers is required. The UHR-OCM imaging is nondestructive and noncontact. The samples can be kept sterile and intact during imaging. This enables longitudinal studies using the same specimen to evaluate disease progression and treatment efficacy of various drugs. Fig. 6 (a) to (d) Representative cross-sectional OCM images obtained from the CA3 region on different DIVs. (e) Thickness of brain cultures on different DIVs in CA1-sub and CA3 regions, respectively. ***p < 0.001. Scale bars: 200 m. 025002-6 Fig. 7 Comparison of OCM images from control group [(a) to (d)] and kynurenic acid (KYNA)-treated group [(e) to (h)]. (a) and (b) Representative OCM images obtained on DIV 7 and DIV 21, respectively, from the control group. (e) and (f) Representative OCM images obtained on DIV 7 and DIV 21, respectively, from the KYNA-treated group. (c), (d), (g), and (h) are the magnified images of the brown rectangular regions in (a), (b), (e), and (f), respectively. Red dots label viable neurons. (i) Total viable neuron count from the first 150 m of slices on DIV 7 and DIV 21 in control and KYNA-treated groups. Number of cultures imaged n ¼ 9 for each group on DIVs 7 and 21, respectively. *p < 0.05 and ***p < 0.001. Scale bars: 400 m in (a), (b), (e), and (f), 200 m in (c), (d), (g), and (h). Conclusion In summary, we developed an UHR-OCM system with micrometer image resolutions to resolve individual cells in rat organotypic hippocampal cultures. A custom cell counting algorithm was developed to quantify cell numbers in 3-D OCM and confocal images and a good linear correlation (R2 ¼ 0.89) in cell count was observed using the two imaging modalities. With UHR-OCM, we observed significant progressive reductions in cell count and the neuroprotective effect of KYNA. These results demonstrated UHR-OCM's capability to accurately count cells and quantitatively measure culture thickness, which proves UHR-OCM as a promising 3-D imaging tool that could be used for high-throughput label-free and nondestructive characterization of micron-scale morphological changes in organotypic hippocampal cultures and potentially other organ-on-a-chip or 3-D tissue constructs. Acknowledgments The authors would like to thank Dr. Aneesh Alex and Dr. Xiaolei Huang for constructive discussions. This work was supported by the Lehigh University Start-up Fund and the National Institute of Health/National Institute of Biomedical Imaging and Bioengineering (NIH/NIBIB) Pathway to Independence Award (R00EB010071 to C. Z.). F. L., Y. S., and W. C. also acknowledge Lehigh's Biosystems Dynamics Summer Institute, which was supported in part by a grant to Lehigh University from the Howard Hughes Medical Institute through the Science Education Program. Fig. 8 Representative cross-sectional OCM images of the control group [(a) and (b)] and the KYNA-treated group [(c) and (d)] obtained from CA3 region on DIV 7 and DIV 21, respectively. (e) Culture thickness measurements on DIV 7 and DIV 21 in control and KYNAtreated groups in CA1-sub and CA3 regions, respectively. *p < 0.05 and ***p < 0.001. Scale bars: 200 m. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Neurophotonics SPIE

Nondestructive evaluation of progressive neuronal changes in organotypic rat hippocampal slice cultures using ultrahigh-resolution optical coherence microscopy

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Publisher
SPIE
Copyright
© 2014 Society of Photo-Optical Instrumentation Engineers (SPIE)
Subject
Research Papers; Paper
ISSN
2329-423X
eISSN
2329-4248
DOI
10.1117/1.NPh.1.2.025002
pmid
25750928
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Abstract

Three-dimensional tissue cultures have been used as effective models for studying different diseases, including epilepsy. High-throughput, nondestructive techniques are essential for rapid assessment of diseaserelated processes, such as progressive cell death. An ultrahigh-resolution optical coherence microscopy (UHROCM) system with 1.5 m axial resolution and 2.3 m transverse resolution was developed to evaluate seizure-induced neuronal injury in organotypic rat hippocampal cultures. The capability of UHR-OCM to visualize cells in neural tissue was confirmed by comparison of UHR-OCM images with confocal immunostained images of the same cultures. In order to evaluate the progression of neuronal injury, UHR-OCM images were obtained from cultures on 7, 14, 21, and 28 days in vitro (DIVs). In comparison to DIV 7, statistically significant reductions in three-dimensional cell count and culture thickness from UHR-OCM images were observed on subsequent time points. In cultures treated with kynurenic acid, significantly less reduction in cell count and culture thickness was observed compared to the control specimens. These results demonstrate the capability of UHR-OCM to perform rapid, label-free, and nondestructive evaluation of neuronal death in organotypic hippocampal cultures. UHR-OCM, in combination with three-dimensional tissue cultures, can potentially prove to be a promising tool for high-throughput screening of drugs targeting various disorders. © 2014 Society of Photo-Optical Instrumentation Engineers (SPIE) [DOI: 10.1117/1.NPh.1.2.025002] Keywords: organotypic; neuron death; optical coherence microscopy; image segmentation. Paper 14047PRR received Apr. 21, 2014; revised manuscript received Jul. 22, 2014; accepted for publication Jul. 25, 2014; published online Sep. 2, 2014. Introduction Three-dimensional (3-D) tissue cultures and constructs, also called organs-on-a-chip, are being increasingly used to model functions of different organs in healthy and diseased states.1 A major application area of these model systems is high-throughput drug discovery.2 This application is enabled by the development of techniques for rapid assessment of disease-related processes in tissues. The rapid evaluation of the number of cells in the tissue is of particular importance in neurological applications, where death of neuron populations is a major hallmark of injury, stroke, epilepsy, Parkinson's, Alzheimer's, and other disorders. 3-D tissue cultures of hippocampus, also known as organotypic hippocampal cultures,3 have recently been used to model the development of epilepsy,4,5 a common neurological disease that affects 1% of the population.1 Organotypic hippocampal cultures model major events of human epilepsy: initial brain injury with immediate loss of some neurons, followed by a latent period with low or normal levels of neural activity and little to no neuron death, and the subsequent development of electrographic seizure activity accompanied by progressive neuron death.5 This model of epilepsy has been used for high-throughput discovery of drug targets with the goal of developing drugs that can prevent development of epilepsy or modify its course.4 The relationship between neuron death and seizures is complex: traumatic brain injury is one of the major causes of epilepsy; however, uncontrolled seizures can also cause progressive neuron loss.5 The prevention of neuron loss, or neuroprotection, during all stages of the disease, is an important property that an antiepileptic drug may possess. Neuroprotection may occur in the initial stages of the disease, leading to more neurons surviving the initial injury, or, in later stages, by preventing seizuredependent neuron death. It is, therefore, important to evaluate changes in the number of neurons in these 3-D cultures over time. The method to evaluate neuron numbers must also be rapid to enable high-throughput drug discovery. Current methods to evaluate neuroprotection in organotypic cultures include confocal microscopy to image surviving or dead neurons, and the measurement of lactate dehydrogenase (LDH) that is released by dying cells.4,6 Confocal microscopy can provide a highly accurate evaluation of neuron viability and death in organotypic cultures, but high-resolution imaging of 3D tissues is a time-consuming process that reduces experimental throughput. Evaluation of surviving neurons requires the use of staining agents that prohibit the use of the same specimens for longitudinal studies. On the other hand, LDH measurement is *Address all correspondence to: Chao Zhou, E-mail: chaozhou@lehigh.edu 0091-3286/2014/$25.00 © 2014 SPIE 025002-1 rapid, but cannot provide information on potentially different levels of neuron death in hippocampal subregions. Optical coherence tomography (OCT), an emerging noninvasive imaging modality, provides 3-D and micron-scale resolution images of biological samples without exogenous contrast agents.7 OCT has been used to monitor brain function of rat somatosensory cortex,8,9 quantify cerebral blood flow,10­12 and intracellular motility in rodent cerebral cortex.11 Optical coherence microscopy (OCM) is an extension of OCT and provides cellular image resolution using high numerical aperture (NA) objectives.13,14 In addition to the advantage of label-free imaging, OCM provides greater imaging depth and faster imaging speed compared to confocal microscopy. OCM has been used to image pathological specimens,15­20 characterize angiogenic sprouting in artificial blood vessels,21 visualize cerebral -amyloidosis in mouse models,22 and recently to quantify the neuron number and morphology in a live rat cortex.23,24 In this study, we aimed to demonstrate the feasibility of OCM imaging for a nondestructive evaluation of neuronal morphology and quantification of the neuron count in organotypic brain cultures. An ultrahigh-resolution OCM (UHR-OCM) system was developed and used to nondestructively image rat organotypic hippocampal slices. UHR-OCM images were compared to confocal images from the same brain slices in order to identify characteristic imaging features associated with viable cells. A custom cell counting algorithm was developed to quantify cell numbers in 3-D OCM and confocal images. A good linear correlation (R2 ¼ 0.89) for cell count was observed using two imaging modalities. Once the correlation was established, UHROCM imaging was used to evaluate the morphological changes in the brain slices associated with spontaneous seizures. A significant reduction of the total cell count and slice thickness were measured from organotypic brain slices on 7, 14, 21, and 28 days in vitro (DIV). Finally, kynurenic acid- (KYNA, a glutamate receptor antagonist that has antiexcitotoxic and anticonvulsant properties25­27) treated brain slices were compared to the control slices in order to evaluate the effects of KYNA on the hippocampal slices. These results suggest that UHR-OCM is a promising imaging tool that can be used for a nondestructive characterization of morphological changes in organotypic brain cultures. medium changes. All animal use protocols were approved by the Institutional Animal Care and Use Committee at Lehigh University and were conducted in accordance with the U.S. Public Health Service Policy on Humane Care and Use of Laboratory Animals. Ultrahigh-Resolution OCM An ultrahigh-resolution OCM system was used to image all the brain slices. Details of the system are described elsewhere.21 Briefly, a supercontinuum light source (SC-400-4, Fianium Ltd., Southampton, United Kingdom) with a center wavelength of 800 nm and bandwidth of 220 nm was used to provide 1.5 m axial resolution in the tissue. A 175-deg conical lens22,28 was used in the sample arm to provide an extended depth of focus of 200 m and the transverse resolution of 2.3 m at focus, 2.5 m at 40 m, and 3.1 m at 90 m above or below the focus with a 10× Olympus objective. The sensitivity of the OCM system was measured to be 90 dB with 3 mW power on a sample at 20,000 A-scans/s image speed. Before imaging, the organotypic hippocampal culture was removed from the incubator and gently placed in a Petri dish with a thin bottom (200 m). The slice was immersed in the culture medium at room temperature during imaging. The OCM system was configured as an inverted microscope in order to image the sample from the bottom. The focus of the OCM was put consistently 100 m above the bottom surfaces of all hippocampal slices. An imaging range of 1.8 × 2.1 mm2 was used to cover the entire brain slice with 800 × 800 axial scans per volume. A 3-D OCM data set was acquired in 40 s. Six repeated scans were performed for each brain slice and averaged in order to reduce speckle noise and improve the signal-to-noise ratio of the OCM images. Confocal Microscopy Materials and Methods Preparation of Organotypic Hippocampal Slice Cultures The slices with a thickness of 350 m were dissected from the hippocampus of seven-day-old Sprague-Dawley rats (Charles River Laboratories). After the dissection, all slices were maintained in a culture medium, which was a mixture of NeurobasalA, GlutaMax, Gentamicin (Life Technologies, New York), insulin, sodium selenite, and bovine serum albumin (Sigma, St. Louis). All slices were maintained at an air­culture interface and incubated in humidified 5% CO2 at 37°C. The culture medium was changed biweekly. For neuroprotection experiments, the KYNA solution (KYNA, Phenol red, and Gey's balanced salt solution) was added to the regular culture medium to achieve 3 mM final KYNA concentration in the KYNA group, and vehicle solution (Phenol red and Gey's balanced salt solution) was added to the regular culture medium in the control group after three DIV. KYNA and vehicle solutions were added to each batch of the fresh culture medium for biweekly For the validation experiments, organotypic hippocampal cultures were fixed immediately after OCM imaging with a mixture of 4% paraformaldehyde in phosphate buffered saline (PBS). After 2-h fixation, cultures were washed with PBS, permeabilized in 0.3% Triton X-100 in PBS and blocked with 10% goat serum in PBS. The cultures were then incubated with anti-NeuN antibody (NeuN is a neuron-specific nuclear protein) conjugated with Alexa Fluor 555 overnight at 4°C. Following the antibody incubation, cultures were washed and mounted for imaging. A laser scanning confocal microscope (Zeiss LSM 510 META, Jena, Germany) was used with a 5× and a 40× objective lens for sample localization and imaging, respectively. The cultures were illuminated from the same side with the confocal microscope in order to have consistent imaging with OCM. The excitation wavelength of the confocal microscope was 543 nm. Since imaging depth of the confocal microscope is limited, 3-D confocal image stacks were obtained only from the first 80 m from the tissue surface. With the 40× objective, each 3-D confocal stack (318 m × 318 m × 80 m) was acquired in 270 s by translating the specimen at 1-m step in the z-direction. Forty-two 3-D confocal stacks were acquired with 10% overlaps between stacks in order to cover the entire culture (2.0 mm × 2.7 mm × 80 m). A stitching program based on Fiji, an extension of ImageJ, was used to stitch individual 3-D confocal stacks into a completed 3-D image set of an entire brain slice. It took 8 h of imaging to complete one 3-D confocal stack for each culture. 025002-2 Identification and Quantification of Viable Cells in 3-D OCM and Confocal Images 3-D OCM images were compared to the 3-D confocal images obtained from the same cultures. Since the anti-NeuN antibodies used for confocal microscopy specifically bind to neuronal nuclei, individual neuronal nuclei were clearly seen on the confocal images [Figs. 1(b) and 1(d)]. In comparison, individual neurons were clearly identified in OCM images as hyposcattering circular regions with well-defined boundaries [Figs. 1(a) and 1(c)]. We were able to observe one-to-one matching of individual neurons in OCM and confocal images obtained from the same brain slice [Figs. 1(c) and 1(d)]. The well-defined boundaries observed in individual neurons suggested that neuronal membrane integrity had not been compromised. This was used as an indicator for neuron viability in our study. Based on these imaging features, we developed a MATLAB®-based algorithm to automatically identify and count cells in 3-D OCM and confocal image stacks. The key concepts were demonstrated in Fig. 2, using OCM images as examples. First, an intensity threshold was applied on the en face OCM image to generate a masked image showing only the hyposcattering regions. In parallel, a template image showing a dark circular region within a white background [Fig. 2(d)] was moved across the en face OCM image to calculate correlation coefficient values for all the pixels. The optimal thresholds for the template size (L ¼ 15 m) and the radius of the circle (R ¼ 6 m) were determined to match the size of the neuron and achieve the highest correlation coefficients. A second masked image was generated showing only regions with correlation coefficient values above a threshold. The two masked images were then multiplied. A third threshold was applied to generate a mask highlighting regions with both low intensity and high correlation coefficients from the en face OCM image. Next, all the masks from different depths were combined to form the 3-D mask stack. A 3-D watershed algorithm was applied to the stack in order to segment and identify individual neurons in the volume.29 A 3-D size filter was then used to remove objects identified by the watershed algorithm that were too small or too large for a neuron. Finally, the cells identified by the algorithm were marked on en face and 3-D OCM images as red dots/spheres [Figs. 2(e) and 3(a)] in order to facilitate visualization of the identified cells. The number of cells in 3-D image stacks was then automatically counted. All the threshold values were optimized to obtain a maximum neuron count while minimizing false positive identification of neurons by visual inspection of the 3-D imaging stacks. The same algorithm was used to quantify cell numbers in 3-D confocal stacks, except that different but optimized template image and threshold values were used. Since neurons presented as white spheres in black background in confocal images Fig. 2 (a) En face OCM image of an organotypic slice on DIV 7. (b) Magnified image of the brown rectangular region in (a). Individual neurons were clearly observed as well-defined hyposcattering circular regions. (c) An individual neuron corresponding to the neuron marked with dashed circle in (b). (d) A representative template image (L ¼ 15 m, R ¼ 6 um) used to calculate correlation coefficient values across en face OCM images. (e) En face OCM image corresponding to the region shown in (b) with neurons identified by the algorithm marked as red dots. Scale bars: 400 m in (a), 10 m in (c), 100 m in (b) and (e). Fig. 1 Ultrahigh-resolution optical coherence microscopy (OCM) image (a) and confocal image (b) from the same organotypic hippocampal culture on day in vitro DIV 7. (c) and (d) are magnified images of regions indicated by brown rectangular boxes in (a) and (b), respectively. Circles in (c) and (d) highlight corresponding individual neurons in OCM and confocal images. CA1-sub, cornuammonis I--subiculum; CA3, cornuammonis III; DG, dentate gyrus. Scale bars: 400 m in (a) and (b), 100 m in (c) and (d). Fig. 3 Three-dimensional (3-D) rendering reconstructed using OCM images (a) and confocal images (b) obtained from approximately the same region of a hippocampal culture with neurons marked as red spheres. 025002-3 [Figs. 1(b) and 1(d)], the template image was bright inside and dark outside for confocal images. Due to limited imaging depth for confocal microscopy, the quantification of cell numbers was only performed from the first 60 m of the slice surface. The quantification of cell counts in OCM was only performed in the matching depths for the three brain slices imaged with both confocal and OCM. For all other brain slices imaged with OCM, total cell counts were obtained in the first 150 m depth from the tissue surface, where the image resolution was the highest. To determine the sensitivity of the OCM imaging technique to count neurons, three matching regions [525 m × 525 m × 15 m, one from the left corner of Fig. 4(a), one from the right corner of Fig. 4(a), and one from another sample] from 3-D OCM and 3-D confocal images were used for comparison. The cells identified from confocal microscopy were used as the gold standard for neurons, since neuron-specific anti-NeuN antibodies were used. After merging the OCM and confocal en face projections, cell counts obtained by both techniques were determined manually. The sensitivity, false negative rate, and positive predictive value for OCM to identify neurons were calculated. Since there was no measurement of non-neuronal cell counts from confocal microscopy, the specificity and false positive rate values were not determined. Statistical Analysis For the validation experiment, 3-D OCM and confocal stacks were divided into four matching quadrants as shown in Figs. 4(a) and 4(b). Cell counts with OCM and confocal were obtained in the 12 independent quadrants from the three brain slices. A linear regression was performed to correlate cell counts measured with OCM and confocal microscopy. The R2 value, the best-fitting line, and the 95% confidence interval (CI) of the slope for the fitting line were calculated. For all the other experiments, the cell count and slice thickness in the CA1-sub and CA3 regions were measured from each brain slice. Group results were summarized as mean Æ SEM. A student's t test was performed to compare results from different experimental groups. A p value of <0.05 was used to indicate statistically significant changes between groups. Results and Discussion Nondestructive Imaging and Quantification of Individual Neurons Using UHR-OCM Brain Slice Thickness Measurements The thickness of the brain slices was also measured from the OCM images in order to characterize the time course of morphological changes. The thickness measurements were performed on cross-sectional OCM images in cornuammonis I, subiculum (CA1-sub), and cornuammonis III (CA3) regions. The average thickness from all axial scans within regions of interest selected from CA1-sub (570 m × 970 m on en face OCM) and CA3 (900 m × 450 m on en face OCM) was calculated after excluding thickness measurements of < 150 m to avoid measurements from the sample boundaries. Figure 1 compares the representative en face OCM and the confocal images of the same organotypic hippocampal culture from the same imaging depth. The same neuronal layers in the dentate gyrus, CA1-sub and CA3 regions of hippocampus, were clearly observed from the en face OCM image [Fig. 1(a)] as well as from the confocal image [Fig. 1(b)]. The same individual neurons can be easily identified from the enlarged OCM [Fig. 1(c)] and the confocal [Fig. 1(d)] images. The hyposcattering and circular features presented in individual neurons were consistent with previous observations with OCM from other research groups.23,24 The low backscattering intensity within the neuronal regions observed in OCM could be partially due to the relatively homogeneous refractive index property within the neuronal nuclei.24,30 This experiment identified neuron features in OCM and established the foundation for developing the algorithm Fig. 4 Corresponding OCM image (a) and confocal image (b) from the same organotypic slice on DIV 7. Brown dashed lines split OCM image and confocal image into four quadrants. (c) and (d) show the lower right quadrant of OCM image in (a) and confocal image in (b), respectively. (e) Also see (Video 1, MOV, 2.13 MB) [URL: http://dx.doi.org/10.1117/1.NPh.1.2.025002.1] for 3-D OCM rendering and (f) Also see (Video 2, MP4, 7.83 MB) [URL: http://dx.doi.org/10.1117/1.NPh.1.2.025002.2] for 3-D confocal rendering) label well-defined (viable) neurons as red dots in OCM and confocal images, respectively. (g) Regression line showing linear correlation (R 2 ¼ 0.89) between neuron count obtained from OCM and confocal images. Scale bars: 400 m in (a) and (b) 200 m in (c) to (f). 025002-4 described above for automatic identification and counting of viable neuron numbers in the brain slices. The same culture was divided into four quadrants in the OCM and the confocal image stacks [Figs. 4(a) and 4(b)]. Individual viable cells were automatically identified based on the algorithm described above and marked in the 3-D imaging stacks for both OCM and confocal [Figs. 4(c) to 4(f) show the lower right quadrant of the specimen, also see Videos 1 and 2 for 3-D rendering]. A very good linear correlation (R2 ¼ 0.89) was observed between the cell counts obtained from OCM and confocal microscopy [Fig. 4(g)]. The slope of the best-fitting line was 1.25, with a 95% CI of 0.94 to 1.57. For the detailed comparison of cell counts in OCM and confocal images, 200, 243, and 303 cells were identified in both imaging modalities from the three matching brain regions, respectively. There were 72, 79, and 67 cells identified from OCM images only, and 55, 82, and 93 cells were identified from confocal images only from the three regions, respectively. Table 1 summarizes these comparison results. Using the cells identified from confocal microscopy as the gold standard, OCM had a sensitivity of 76.4% to identify neurons. OCM missed 23.6% (false negative rate) of neurons compared to confocal microscopy. This was partly due to the limited resolution of OCM to differentiate small and clustered neurons [e.g., the lower left quadrant of Fig. 4(a)] and imperfect match in depth for OCM and confocal images (tissues may have been slightly distorted by fixation prior to immunostaining). The false positive cell count from OCM could be due to the detection of glial cells (not stained with the anti-NeuN antibody and, thus, not appearing in confocal counts) and counting errors of the algorithm. As a result, a positive predictive value of 77.4% was obtained. The actual specificity and false positive rate values could not be determined due to a lack of non-neuron-specific cell counts from confocal microscopy. However, since brain tissues may contain up to 10 times as many glia cells as neurons, a cell count obtained from OCM seems to be neuron-specific, especially considering that only the intrinsic scattering contrast was utilized in OCM imaging. These results demonstrated that UHR-OCM could be used to provide viable cell count in brain slices without the destructive fixation and staining processes involved using standard confocal microscopy. The imaging time for UHR-OCM is also short (a few minutes for each 3-D stack), making high-throughput evaluation of the samples possible using OCM. Other groups have demonstrated OCM imaging of individual neurons in rat cortex in vivo.23 A high-magnification objective lens (40×) was used in the OCM system to achieve submicron transverse image resolutions (0.9 m).23 However, the depth of focus of the OCM system (3.8 m) was very limited due to the high numerical aperture of the objective lens. As a result, the focal plane had to be translated to acquire multiple OCM data sets in order to obtain 3-D images from the rat cortex, which resulted in slow imaging speed. In our UHR-OCM system, a supercontinuum light source was used to provide 1.5 m axial resolution. A lower magnification objective lens (10×) and a conical lens were used to achieve 2.3 m transverse resolution over 200 m imaging depth. With this configuration, we were able to acquire ultrahigh-resolution images of the entire brain slice without translating the focus in tissue. The parallel depth imaging capability of OCM was utilized to significantly improve imaging speed compared to previous studies. Evaluation of Progressive Neuronal Injury in Organotypic Brain Slices using UHR-OCM Table 1 Comparison of number of cells identified in confocal and optical coherence microscopy (OCM) images from three matching brain regions. Cells identified in confocal Cells identified in OCM Cells not identified in OCM Sensitivity False negative rate Positive predictive value 746 Cells not identified in confocal 218 In this experiment, UHR-OCM images of the hippocampal brain slices were obtained on DIV 7 (n ¼ 18), DIV 14 (n ¼ 11), DIV 21 (n ¼ 18), and DIV 28 (n ¼ 9) in order to evaluate the progression of neuronal injury. Figures 5(a) to 5(h) compares representative en face OCM images from slices on different DIV. As shown more clearly in Figs. 5(e) to 5(h), neuron boundaries became diffusive and image contrast was reduced as DIV increased, suggesting the membrane integrity of some neurons in the slice cultures was compromised. The number of viable cells significantly decreased as DIV increased [Fig. 5(i)]. Compared to DIV 7, significant reductions in cell counts of 23.1% (p < 0.001), 33.7% (p < 0.001), and 45.8% (p < 0.001) were observed on DIV 14, DIV 21, and DIV 28, respectively. The largest reduction (23.1%) in cell count was observed between DIV 7 and DIV 14, suggesting neuronal injury was highest during this time period. Measurements of slice thickness also showed continuous decreases in both the CA1-sub and the CA3 regions as DIV increased [Figs. 6(a) to 6(e)]. In CA1sub, reductions in slice thickness of 1% (p ¼ 0.82), 12.0% (p < 0.001), and 19.3% (p < 0.001) were observed on DIV 14, DIV 21, and DIV 28, respectively, while in CA3, reductions of 2.7% (p ¼ 0.54), 13.5% (p < 0.001), and 16.1% (p < 0.001) were observed on DIV 14, DIV 21, and DIV 28, respectively. The decreasing trend in slice thickness was consistent with the trend in cell counts as DIV increased. The percentage of thickness reduction was less than the cell count reduction, suggesting that neuron loss may not be the only mechanism that contributes to changes in slice thickness with culture age. 230 -- Evaluation of Treatment Effects of KYNA to Hippocampal Slice Cultures 746ð746 þ 230Þ × 100% ¼ 76.4% 230ð746 þ 230Þ × 100% ¼ 23.6% 746ð746 þ 218Þ × 100% ¼ 77.4% Our previous work has demonstrated that seizures occur spontaneously in organotypic hippocampal slice cultures and lead to neuron death.6 KYNA reduces the amount of neuron death in the brain slices.31 Figures 7(a) to 7(h) compare representative en face OCM images obtained from the control and KYNA-treated brain slices at DIV 7 (n ¼ 9) and DIV 21 (n ¼ 9), respectively. In the control group, significantly fewer cells with well-defined 025002-5 Fig. 5 Representative OCM images obtained from different cultures on (a) DIV 7, (b) 14, (e) 21, and (f) 28, respectively. The representative OCM images were obtained from a depth of 50 m from the slice surface. (c), (d), (g), and (h) are the magnified images of the brown rectangular regions in (a), (b), (e), and (f), respectively. Viable neurons are marked as red dots. (i) Total viable neuron counts from the first 150 m of the organotypic hippocampal cultures from different DIVs. ***p < 0.001. Scale bars: 400 m in (a), (b), (e), and (f), 200 m in (c), (d), (g), and (h). boundaries were observed on DIV 21 (n ¼ 9) compared to DIV 7 (n ¼ 9) [Figs. 7(a) to 7(d)]. The reduction of well-defined cells in the KYNA group was less dramatic on DIV 21 compared to DIV 7 [Figs. 7(e) to 7(h)]. The quantification of cell numbers in the two groups [Fig. 7(i)] further confirmed the observations from visual inspection of the OCM images. A significant reduction of 40.3% in cell counts (DIV 21 versus DIV 7, p < 0.001) was observed in the control group, while a reduction of 20.0% in cell count (DIV 21 versus DIV 7, p < 0.05) was observed in the KYNA group. Viable cell count was similar in the two groups on DIV 7 (p ¼ 0.35), but was significantly lower (19%, p < 0.05) in the control group compared to the KYNA group on DIV 21. Figures 8(a) to 8(d) compare the representative cross-sectional OCM images from the CA3 regions of the brain slices from the control and the KYNA groups. The slice thickness measured from the CA1-sub and CA3 regions [Fig. 8(e)] was significantly smaller on DIV 21 compared to DIV 7. In the control group, thickness reductions of 12.0% (p < 0.001) and 13.3% (p < 0.001) were observed in the CA1-sub and CA3 regions, respectively. In the KYNA group, thickness reductions of 8.6% (p < 0.05) and 8.0% (p < 0.05) were observed in the CA1-sub and CA3 regions, respectively. The reduction of slice thickness was consistent with the trend observed in the cell counts. Our results clearly showed that progressive neuron death and the neuroprotective effect of KYNA could be observed by UHROCM. The data were in agreement with our previous observations that used confocal imaging of propidium iodide uptake and LDH release as markers of neuron death.5 UHR-OCM was validated as a powerful tool for label-free, live evaluation of organotypic brain cultures. The quantitative information, such as cell counts and slice thickness, could be obtained from 3-D UHROCM images. Due to the high imaging speed of OCM, it is possible to use OCM and 3-D tissue culture disease models for high-throughput drug discovery for disorders where evaluation of progressive changes in cell numbers is required. The UHR-OCM imaging is nondestructive and noncontact. The samples can be kept sterile and intact during imaging. This enables longitudinal studies using the same specimen to evaluate disease progression and treatment efficacy of various drugs. Fig. 6 (a) to (d) Representative cross-sectional OCM images obtained from the CA3 region on different DIVs. (e) Thickness of brain cultures on different DIVs in CA1-sub and CA3 regions, respectively. ***p < 0.001. Scale bars: 200 m. 025002-6 Fig. 7 Comparison of OCM images from control group [(a) to (d)] and kynurenic acid (KYNA)-treated group [(e) to (h)]. (a) and (b) Representative OCM images obtained on DIV 7 and DIV 21, respectively, from the control group. (e) and (f) Representative OCM images obtained on DIV 7 and DIV 21, respectively, from the KYNA-treated group. (c), (d), (g), and (h) are the magnified images of the brown rectangular regions in (a), (b), (e), and (f), respectively. Red dots label viable neurons. (i) Total viable neuron count from the first 150 m of slices on DIV 7 and DIV 21 in control and KYNA-treated groups. Number of cultures imaged n ¼ 9 for each group on DIVs 7 and 21, respectively. *p < 0.05 and ***p < 0.001. Scale bars: 400 m in (a), (b), (e), and (f), 200 m in (c), (d), (g), and (h). Conclusion In summary, we developed an UHR-OCM system with micrometer image resolutions to resolve individual cells in rat organotypic hippocampal cultures. A custom cell counting algorithm was developed to quantify cell numbers in 3-D OCM and confocal images and a good linear correlation (R2 ¼ 0.89) in cell count was observed using the two imaging modalities. With UHR-OCM, we observed significant progressive reductions in cell count and the neuroprotective effect of KYNA. These results demonstrated UHR-OCM's capability to accurately count cells and quantitatively measure culture thickness, which proves UHR-OCM as a promising 3-D imaging tool that could be used for high-throughput label-free and nondestructive characterization of micron-scale morphological changes in organotypic hippocampal cultures and potentially other organ-on-a-chip or 3-D tissue constructs. Acknowledgments The authors would like to thank Dr. Aneesh Alex and Dr. Xiaolei Huang for constructive discussions. This work was supported by the Lehigh University Start-up Fund and the National Institute of Health/National Institute of Biomedical Imaging and Bioengineering (NIH/NIBIB) Pathway to Independence Award (R00EB010071 to C. Z.). F. L., Y. S., and W. C. also acknowledge Lehigh's Biosystems Dynamics Summer Institute, which was supported in part by a grant to Lehigh University from the Howard Hughes Medical Institute through the Science Education Program. Fig. 8 Representative cross-sectional OCM images of the control group [(a) and (b)] and the KYNA-treated group [(c) and (d)] obtained from CA3 region on DIV 7 and DIV 21, respectively. (e) Culture thickness measurements on DIV 7 and DIV 21 in control and KYNAtreated groups in CA1-sub and CA3 regions, respectively. *p < 0.05 and ***p < 0.001. Scale bars: 200 m.

Journal

NeurophotonicsSPIE

Published: Oct 1, 2014

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