Fluorescent proteins1 have enabled us to observe cell shapes and the localization of molecules within live cells and tissue of transgenic animals expressing fluorescent protein, such as transgenic mice expressing green fluorescent protein. In the case of two-photon laser scanning microscopy (TPLSM), fluorescent molecules are excited within a small area around the focus.2 This localization in the two-photon excitation process allows cross-sectional fluorescent imaging in the absence of a confocal aperture. In addition, near-infrared laser light used for two-photon excitation processes is negligibly absorbed or scattered in a biospecimen. Owing to these advantages, the use of fluorescent proteins and TPLSM has enabled us to three-dimensionally visualize deep regions within a biospecimen, such as the brain of a living mouse expressing fluorescent proteins.34.5.–6 On the other hand, several optical clearing reagents for fixed tissues have been proposed to increase the tissue penetration depth and enable much deeper imaging.78.–9
However, the spatial resolution and the fluorescence signal in laser scanning microscopy are frequently degraded by wave-front aberrations caused by refractive-index mismatches in the optical path. These aberrations and their effects have been numerically calculated and experimentally investigated by several authors.1011.12.–13 In many biospecimens, one of the predominant aberrations that deteriorate the quality of an image obtained when observing deep regions of the sample is spherical aberration, which is usually caused by the difference in the refractive index between the sample and the immersion medium.14 A correction collar is usually built into the body of a high numerical aperture (NA) objective lens to correct some aberrations. However, adjusting the correction collar requires observers to touch the objective lens, which means that the disturbance may affect the accuracy of the adjustment. Similarly, although the alteration of the effective tube length11 and the refractive index of the immersion medium10 have been proposed for correcting some spherical aberrations, these techniques are performed statically and are difficult to adjust during observation. On the other hand, some adaptive optics techniques have been previously proposed. Electrically controllable spatial light modulators (SLMs), such as deformable mirror devices or liquid-crystal-on-silicon devices, were shown to reduce not only the spherical aberration but also various other aberrations1518.104.22.168.20.–21 while providing dynamic correction in three-dimensional (3-D) images.21 For example, with a oil immersion objective lens, the imaging depth in water was extended from approximately 3.4 to by using an SLM in TPLSM.15 Furthermore, the nonlinear guide-star concept was introduced to the adaptive optics technique using an SLM and succeeded in improving the image quality at deep regions within fixed and in vivo biological samples in TPLSM.20 However, these refractive SLMs require experimenters to change the basic design of the optical path in a conventional microscope. In these studies, researchers modified the conventional microscope and added a relay optical system in order to incorporate the refractive SLM in the system.1522.214.171.124.20.–21 Such a modification would be difficult to implement for biologists who are not necessarily optics experts.
Liquid-crystal devices have been used in various applications to modulate light waves, e.g., radially polarized beam generators, holographic microscopes, and optical pickups.2223.24.25.–26 To solve the aforementioned problems, we have developed transmissive liquid crystal devices for the correction of a specific spherical aberration. These devices consist of liquid-crystal cells (LCCs) wherein a layer of liquid crystal molecules is sandwiched by a pair of glass substrates equipped with transparent electrodes. Since the direction of the liquid-crystal molecule exhibiting refractive index anisotropy is electrically controllable, a segmented pattern of the transparent electrode generates a phase distribution that corresponds to a segmented pattern in the wave front of the penetrating light. The phase modulation is controlled by changing the applied voltages.
In our previous study,27 we numerically calculated spherical aberrations at the pupil of an objective lens when focusing on deep regions of a sample with a homogeneous refractive index. Furthermore, we experimentally confirmed the existence of the calculated spherical aberrations. Moreover, spherical aberrations during deep observations were numerically calculated based on the NA and pupil diameter of the objective lens, and the mentioned liquid crystal devices were designed to correct these spherical aberrations. The optimum design depended on the objective lens. We next evaluated the device by observing beads embedded at various depths in an agarose gel. By inserting the device in front of the objective lens and supplying it with the appropriate voltage to maximize the fluorescence signal of the object, we experimentally demonstrated that the device improved the spatial resolution and the fluorescence signal, which degraded at various regions. In this study, we estimated the axial resolution and evaluated the performance of the device in more detail. Furthermore, we compared experimental and numerical calculation results. Finally, we implemented the device in TPLSM for the observation of a brain slice of a yellow fluorescent protein (YFP) expressing mouse with features of the order of several micrometers. The spatial resolution and the fluorescence signal before and after correction by the device were also estimated. In conclusion, we experimentally demonstrated that the device enhanced the biospecimen’s image at various observation depths.
Theory and Methods
Experimental Setup of the Microscope and Device
Observations were performed with an upright microscope (Eclipse FN1, Nikon Co.) and a scanner (A1R MP+, Nikon Co.) for excitation light with wavelengths 488 and 950 nm. In this study, the confocal aperture was completely open and the 13-mm-thick device was inserted between a water-immersion objective lens (CFI Apo LWD , NA1.1, Nikon Co.) and the microscope revolver. A pulse amplitude modulation controller was used to control the performance of the device [Fig. 1(a)]. Figures 1(b)–1(d) illustrate the principle of the spherical aberration correction by the LCC. Figure 1(b) shows an example of a spherical aberration distribution and Fig. 1(c) shows a schematic of the six-level quantized phase distribution, which corrects the spherical aberration. Figure 1(d) shows the segmented annular electrodes and lead-out electrodes for applying voltage to the liquid-crystal layer to generate the discretized phase distribution in the LCC. The diameter of the outermost peripheral annular electrode was 17.6 mm, which was almost equal to the calculated pupil diameter of the objective lens, according to the manufacturer’s information. In this study, we first applied a voltage determined from the numerical calculation. Next, by repeatedly changing the applied voltage slightly, we determined the appropriate voltage required to achieve the maximized fluorescence signal of the object.27
After the correction, the discretized phase distribution in the LCC caused a residual aberration, which can be reduced by increasing the number of rings in the phase distribution in the LCC. However, the number of annular electrodes was limited by the production process and could not be further increased. In addition, even if the number of annular electrodes was increased, the corresponding increase in the number of lead-out electrodes would cause a deterioration of the spatial homogeneity and, thus, the optical performance. Therefore, we used numerical calculations to evaluate and optimize the ring number to obtain a maximum effect of correcting the spherical aberration. The numerical calculations were performed based on the Fourier transforming property of lenses. A fast Fourier transform was applied to the phase distribution of the residual aberration on the pupil plane of the objective lens, which resulted in an amplitude distribution on the focus plane. However, the device was not placed in the pupil position of the objective lens during actual implementation. The influence of the displacement of the device from the pupil position along the -axis is considered in the next section. For an NA1.1 water-immersion objective lens and a sample with a refractive index of 1.38, the amplitude of the induced spherical aberration at a depth of 0.7 mm was calculated as 3600 nm. This value was equal to that of the phase modulation, which can be generated by using three LCCs. The phase distribution quantized in 48 or more levels resulted in a Strehl ratio greater than 0.9 [Fig. 1(e)]. Hence, we used three LCCs to generate a 48-level quantized phase distribution. The LCCs had 31 segmented annular electrodes with linewidths 1.3–0.043 mm. The device achieved a phase modulation of 3600 nm. The phase distribution generated in the device was measured by laser interferometers (Zygo PTI 250, Zygo Corporation) and we confirmed that its form agreed very well with that of the calculated distribution [Fig. 1(f)].
Figure 1(g) shows the transmittance of the LCC. For the wavelength range 800–1100 nm, which was used for excitation in TPLSM, the transmittance was 95% per cell. For the wavelength range 460–600 nm, which was used for fluorescence measurements, the transmittance was 92%–95% per cell. Since we used three LCCs in this study, the transmittance of the device was approximately 88% and 78%–85% in the wavelength ranges 800–1100 and 460–600 nm, respectively.
Numerical Calculations Using the Objective Lens System
The point spread function (PSF) of the 488-nm collimated light beam was numerically calculated (CODEV, Optical Research Associates) assuming that the light was focused through a continuous phase distribution and a water-dipping objective lens (JP2011-75982A). The numerical calculation was performed based on the beam propagation method. In this calculation, the continuous phase distribution was placed in a plane perpendicular to the optical axis, 10 mm away from the front of the objective lens along the -axis (where the device was actually placed in the experiment). To evaluate the effect of the spatially discretized phase distribution of the device with a 48-level quantized phase distribution, the reduction rate of the Strehl ratio was also obtained in the numerical calculation, as mentioned in Sec. 2.1. Therefore, we were able to estimate the influences of both the device’s position along the -axis and the discretization of the phase distribution.
Sample Preparation and Analysis
Fluorescent yellow-green beads with a diameter of were mixed into agarose gel with a refractive index of 1.38. The refractive index of agarose gel was adjusted using sucrose solutions. The mixture was poured into a glass base dish (cover glass thickness of 0.16–0.19 mm). Under different observation conditions, we observed several beads within the volume of a cube located at the center of the field of view. The fluorescence intensity profiles across the intensity center along the -axis were fitted with a Gaussian function, and the peak intensities and full width at half maximum values along the -axis ( values) were obtained for each image. Thus, the average peak intensity and the average value of the images were obtained, along with the average intensity profile of those images. Similarly, fluorescence intensity profiles across the intensity center along the -axis were fitted with a Breit-Wigner-Fano line shape for each image, and the average FWHM value along the -axis ( value) and the average intensity profile of those images were obtained.
Previously, 2,2’-thiodiethanol (TDE) solutions were shown to quickly render fixed mouse brain tissues optically transparent.7,8 TDE-treated fixed mouse brain slices exhibited a higher penetration depth in the visible and the near-infrared regions, and a stronger fluorescence signal was emitted from the deep layers. In this study, we used 51% TDE solutions to clear the 0.95-mm-thick fixed brain slices of YFP expressing mouse (Thy1-YFP-H mouse28) and to adjust the refractive index to 1.42. The TDE-treated slices were immersed in a TDE solution of the same concentration in the mount, where the distance between the cover slip and the slide glass was 1 mm. To estimate the spatial resolution in a fixed brain slice, we utilized dendritic spines about in size as a ruler in the cortical layer V neurons. The intensity profiles of a single dendritic spine along the - and -axes were fitted with a Gaussian function and a Breit-Wigner-Fano line shape, respectively, to obtain the peak intensities and the FWHM values along the - and -axes.
All animal experiments were performed in accordance with the National University Corporation Hokkaido University Regulations on Animal Experimentation and the Guidelines for Proper Conduct of Animal Experiments (Science Council of Japan). The protocol was approved by the Institutional Animal Care and Use Committee of National University Corporation Hokkaido University (Permit No. 10-0119).
Numerically Calculated Point Spread Function at 488-nm Wavelength
First, in order to estimate the correction effect of the device, we numerically calculated the PSFs at the surface of the cover glass () and at depths of 0.3 and 0.6 mm in a sample with a refractive index of 1.38 (Fig. 2). The spatial resolution and the signal of the PSFs degraded in proportion to the depth [Figs. 2(a)–2(d), 2(g), 2(h)]. At a depth of 0.3 mm from the surface of the sample (), the peak intensity of the PSF dropped to 13% of the peak intensity at (). Additionally, the value degraded to from and the value to from [Figs. 2(k) and 2(l)]. Furthermore, at , the peak intensity dropped to 7% and the and values degraded to 0.37 and [Fig. 2(m)], correspondingly. Besides, we confirmed that the spatial resolution and the signal, which degraded as a result of spherical aberrations, improved after correction with the continuous phase distribution placed at the front of the objective lens. [Figs. 2(e), 2(f), 2(i), and 2(j)]. At , the peak intensity recovered 93% [Fig. 2(l)]. On the other hand, we numerically calculated that the peak intensity of the PSF corrected by the 48-level quantized phase distribution was 96% of that corrected by the continuous phase distribution. Therefore, it was assumed that 89% was recovered after the correction with the quantized phase distribution at the front of the objective lens. Similarly, at , the peak intensity recovered by 85% compared to after the correction by the continuous phase distribution [Fig. 2(m)]. Furthermore, it was numerically calculated that the peak intensity of the PSF corrected by the quantized phase distribution dropped to 90% of that corrected by the continuous phase distribution. Therefore, it was assumed that the peak intensity recovered 77% after the correction by the quantized phase distribution at the front of the objective lens. On the other hand, at and 0.6 mm, the values improved to 0.79 and , respectively, and the values improved to [Figs. 2(l) and 2(m)]. The FWHM values were almost equal to those at , after the correction by the continuous phase distribution.
Imaging of the Beads with Single-Photon Excitation Microscopy
Next, the correction effect of the device was experimentally evaluated by single-photon excitation laser scanning microscopy. In this experiment, fluorescent beads embedded in agarose gel were observed using 488-nm-wavelength laser light to evaluate the fluorescence signal and the FWHM of the image. The correction collar of the objective lens was adjusted beneath the cover glass’s surface () to obtain the best optical performance. At a depth of 0.3 mm from the cover glass surface (), the peak intensity of the image dropped to 47% , and the value degraded to 0.38 from . The value degraded to from [Figs. 3(a)–3(d), 3(k), and 3(l)]. Furthermore, at , the peak intensity dropped to 30% . The value degraded to , and the value degraded to [Figs. 3(g), 3(h), and 3(m)]. On the other hand, at , the peak intensity recovered by 116% compared to , and the value improved to after correction with the device. Furthermore, the device improved the value to [Figs. 3(e), 3(f), and 3(l)]. Similarly, at , the device recovered 78% , and improved the value to . The value improved to after correction by the device [Figs. 3(i), 3(j), and 3(m)]. Namely, at and 0.6 mm, the peak intensities of the corrected images were approximately 2.5 and 2.6 times higher than those of the aberrated images, respectively. Furthermore, the FWHM values were similar to those at after correction with the device.
Next, the correction collar of the objective lens was adjusted to obtain the best performance at . At depths smaller than , the spatial resolution degraded and the fluorescence signal decreased [Figs. 4(a)–4(d)]. At , the peak intensity dropped to 58% of the peak intensity at (). Also, the and values degraded to from and to from , respectively [Figs. 4(g) and 4(h)]. However, after correction with the device, the peak intensity at recovered 94% . Furthermore, the value improved to , and the value improved to [Figs. 4(e), 4(f), and 4(h)]. The correction with the device thus increased the peak intensity by approximately 1.6 times compared to that of the aberrated image. Additionally, the FWHM values improved to the values almost equal to those at . From these results, it is evident that the device improved the spatial resolution and the fluorescence signal, and restored the cross-sectioning ability within a depth of .
Imaging of the Beads with Two-Photon Excitation Microscopy
In preparation for the implementation of the device to observe a biospecimen using TPLSM, we introduced the device to a TPLSM illuminated by 950-nm-wavelength laser light and observed the fluorescent beads in order to confirm the correction effect of the device. The correction collar of the objective lens was adjusted to obtain the best performance at . As with single-photon excitation microscopy, the spatial resolution and the fluorescence signals of the images degraded in proportion to the depth where the beads were located [Figs. 5(a)–5(d), 5(g), and 5(h)]. At , the peak intensity dropped to 67% . Also, the and values degraded to from , and to from , respectively [Figs. 5(k) and 5(l)]. Furthermore, at , the peak intensity dropped to 45% . The value degraded to , and the value degraded to [Fig. 5(m)]. On the other hand, at and 0.6 mm, the device recovered 115% and 98% , respectively. The values at and 0.6 mm improved to 1.9 and , correspondingly, and the values to [Figs. 5(e), 5(f), 5(i), 5(j), 5(l), and 5(m)]; namely, the correction by the device increased the peak intensity by approximately 1.7 and 2.2 times, respectively, compared to the aberrated conditions. The FWHM values improved to the value almost equal to those at . At and 0.6 mm, the phase amplitudes generated by the device were 1550 and 3300 nm, respectively. In this way, we succeeded in improving the lateral and axial resolutions. Additionally, the fluorescence signal in deep regions was improved like in the case of single-photon excitation microscopy.
Imaging of the Biospecimen with Two-Photon Excitation Microscopy
Finally, we implemented the device for the observation of the biospecimen described earlier using TPLSM. Figures 6 and 7 show the images of the TDE-treated fixed mouse brain slice. The observation regions were at the surface of the cover glass () and at depths 0.19, 0.27, and 0.54 mm from the surface. The same areas were observed before and after correcting aberrations. As with the observation of the bead sample, we utilized dendritic spines about in size as a ruler to estimate the spatial resolution in the fixed brain slice.
Figure 6 shows the images acquired when the correction collar of the objective lens was adjusted to obtain the best performance at . From the lateral wide-field images at and 0.27 mm, the fluorescence signals improved after correction by the device, as well as with the correction collar [Figs. 6(a)–6(f)]. Furthermore, from the images of the dendritic spines, the device and the correction collar clearly improved the spatial resolution and the fluorescence signal [Figs. 6(g)–6(r)]. Specifically, at and a phase amplitude of 2300 nm, the device improved the value to from and the value to from . Furthermore, the peak intensity of the image corrected by the device was approximately 1.8 times higher than that of the aberrated image [Fig. 6(s)]. On the other hand, the correction collar improved the value to and the value to . The peak intensity of the image corrected by the correction collar was approximately 2.1 times higher than that of the aberrated image [Fig. 6(s)]. At , the device and the correction collar improved the value to from , they improved the value to 1.5 and from , respectively, and increased the peak intensity by approximately 2.4 times compared to that of the aberrated condition [Fig. 6(t)]. At , the phase amplitude of the device was 2900 nm. In the experiment with the bead sample, the correction by the device with phase amplitude 3300 nm increased the peak intensity 2.2 times compared to that of the aberrated condition (see Sec. 3.3). Accordingly, for the biospecimen, the device showed a similar improvement of the fluorescence signal to that observed for the bead sample. From this result, we confirmed that the device improved the lateral and the axial resolution; additionally, the fluorescence signal degraded in deep regions of the biospecimen, as with the bead sample. Furthermore, the device showed a correction effect similar to that of the correction collar.
Finally, in order to observe a wider range of depth, we adjusted the correction collar to obtain the best performance at a deep region of the biospecimen. In Sec. 3.2, we showed that the device improved the image quality at both shallower and deeper regions than the position in which the best optical performance was obtained. On the other hand, the device improved the image quality at when the correction collar was adjusted to obtain the best performance at (Fig. 6). Meanwhile, the maximum depth at which the depth-induced spherical aberration was correctable by the correction collar was 0.27 mm. By utilizing this property of the device and the objective lens, the device was expected to improve the image quality at when the correction collar was adjusted to obtain the best performance at . Thus, we observed the biospecimen at depths of 0–0.54 mm. As in Fig. 6, at and 0.54 mm, the fluorescence signal of the wide-field lateral images improved after correction by the device [Figs. 7(a)–7(d)]. From the images of the dendritic spines, at , the and values improved to from , and to from , respectively. Additionally, the peak intensity of the image corrected by the device was approximately 1.5 times higher than that of the aberrated image [Figs. 7(e)–7(h), 7(m)]. Furthermore, at , the value improved to from and the peak intensity of the corrected image was approximately 1.9 times higher than that of the aberrated image. At , before correction, the intensity profile along the -axis extended outside the observation range and the value was estimated from the fitting curve. Therefore, the value improved to from after correction by the device [Figs. 7(i)–7(l), 7(n)]. Thus, by using the device, we succeeded in the acquisition of a high-contrast and high-resolution image of the biospecimen in a wide range of depths, including a depth twice as large as that where depth-induced spherical aberration was correctable by the correction collar.
We succeeded in improving both the spatial resolution and the fluorescence signal originally degraded by aberrations in agarose gel and in a fixed mouse brain by inserting a transmissive liquid-crystal device between the objective lens and the revolver of the microscope.
Figures 6 and 7 show that the correction collar had an effect comparable to or higher than that of our device, although it was difficult to accurately adjust. However, the correction collar would not be able to correct dynamic depth-induced spherical aberrations, because an automatic system involving the rotation of the correction collar without any mechanical vibrations may not be realizable. In the future, an automatic adjustment system with the phase amplitude of our device would enable the dynamic correction of the spherical aberrations of a 3-D image over a wide range of depths. When the correction collar is adjusted to obtain the best performance at deep regions, as shown in Fig. 7, the device would enable visualization in a wider range of depths, including regions where the depth-induced spherical aberration is not correctable by the correction collar. For the sample with a refractive index of 1.42, the device improved the image quality of TPLSM within . Additionally, for a sample with refractive index 1.52, the device can achieve an optical performance with a Strehl ratio higher than 0.8 at .
An LCC with aligned liquid-crystal molecules was used to modulate the phase for the linear polarized light in a certain direction. In this study, the device corrected the aberration only for linearly polarized excitation light; the nonpolarized fluorescence signal was not completely modulated. However, since fluorescence detection through the confocal aperture is unnecessary in TPLSM, the aberrated fluorescence signal could be detected by the fluorescent detector; in these measurements no correction was required. In order to integrate the device with confocal laser scanning microscopy, the nonpolarized fluorescence signal also needs to be corrected. It is expected that for confocal laser scanning microscopy, the device will be adapted with two kinds of LCCs, with liquid-crystal molecules aligned in perpendicular directions.
When focusing in deep regions, we found that there was a discrepancy (i.e., a small shift) in the numerical and experimental values of the optimized depths. Therefore, besides other spherical aberration components, additional defocus elements may be included in the phase distribution of the device, which could result in a slightly shifted observation depth after correction by the device. The observation of the same position before and after correction required a fine adjustment of the observation depth after correction. For example, in Fig. 6, the observation depth shifted by 8.0 and at and 0.27 mm, respectively, after correction by the device. In the future, an automatic adjustment system of the imaging depth according to the amplitude of the phase modulation will be required.
In Figs. 3 and 5, the peak intensity of the corrected images at was higher than that at . It is presumed that the device corrects the original coma aberration of the objective lens. The different axial center of the spherical phase distribution and the objective lens induces coma aberration. Therefore, while the device corrects the spherical aberration, the coma aberration of the objective lens may be corrected by the coma phase component generated by the difference in the axial center between the device and the objective lens.
For the 488-nm wavelength, the experimental results qualitatively agreed with the numerically calculated results, while the peak intensity values differed from those of the numerically calculated PSFs (Figs. 2 and 3). Namely, at , the numerical and experimental peak intensities and FWHM values of the corrected images were almost equal to those at . On the other hand, at , the correction could not entirely recover the peak intensity, whereas the FWHM values improved to the values almost equal to those at . The correction effect of the device was experimentally confirmed with TPLSM. However, the numerical calculation did not obtain an adequate result because the optical performance of the objective lens system used in the calculation was considerably poor at a 950-nm wavelength. This degradation of the optical performance might be caused by several factors undisclosed by the manufacturer. It is desirable that more information is provided on the specifications of the objective lens.
The degradation of the correction performance at displayed in Figs. 2 and 3 can be explained as follows. The device was theoretically designed to correct a spherical aberration occurring on the pupil of the objective lens; however, the device was not placed exactly at the pupil position on the -axis. In addition to the water-immersion objective lens system, we numerically calculated the correction performance for and water-immersion objective lens systems (US7889432B and JP4097937B) by the method shown in Secs. 2.1 and 2.2 (Table 1). The numerical calculation revealed that the optical performance after correction lowered proportionally to the focusing depth, especially in the case of the and objective lens systems. It is inferred that the cause of this degradation is the long optical distance between the device and the pupil plane in the high-power objective lens system along the -axis. In order to improve the performance of the device and to correct such aberrations, more precise numerical calculations for the spherical aberration are required at the real position of the device.
The numerically calculated peak intensity of corrected point spread functions (PSFs) compared to that at z=0 mm.
|Objective lens (×)||z (mm)|
|0.3 (%)||0.6 (%)|
The adaptive optics technique with our device is important for biologists who are not experts in optics and who do not want to change the fundamental optical system of a conventional microscope. Furthermore, the device may also be applicable to conventional confocal laser scanning microscopy or stimulated emission depletion microscopy. The device can be applied to examine various samples, such as live organs. The ultimate goal of our device is the dynamic correction of various aberrations, including asymmetric aberrations such as coma aberration or astigmatism, which are induced by refractive index variations in the sample. In the future, TPLSM with our device is expected to provide a simplified approach to acquiring high-quality images of deep regions in live cells and tissue of fluorescent-protein-expressing transgenic animals.
We developed a transmissive liquid-crystal device for correcting spherical aberration. The device was placed in front of the objective lens in a conventional single-photon and a two-photon excitation laser scanning microscope and was shown to improve the spatial resolution and fluorescence signal originally degraded during observation in a wide range of depths. For a water-immersion objective lens and a sample with a refractive index of 1.38, the device recovered the spatial resolution and the fluorescence signal of a bead image within a depth. Furthermore, we implemented the device in TPLSM for the observation of a fixed mouse brain slice with a refractive index of 1.42. The device improved the spatial resolution and the YFP signal, and restored the cross-sectioning ability within a 0–0.54-mm depth, including the region where the depth-induced spherical aberration was not correctable by a correction collar.
We are grateful to Ms. E. Ito and Ms. M. Oguro for their technical assistance. We are also grateful to Dr. Y. Kozawa and Professor S. Sato (Institute of Multidisciplinary Research for Advanced Materials, Tohoku University), and Dr. R. Kawakami, Dr. K. Iijima, Dr. K. Otomo, and Mr. H. Osanai (Research Institute for Electronic Science, Hokkaido University) for their helpful advice. This study was partly supported by JSPS KAKENHI (under Grant Nos. 25-1699, 25560411, 22113005, 22300131, and 26242082) from the Ministry of Education, Culture, Sports, Science, and Technology (MEXT) of Japan; the Nano-Macro Materials, Devices, and System Research Alliance (MEXT); the Network Joint Research Center for Materials and Devices (MEXT); CREST, JST Japan; and Brain/MINDS, AMED, Japan.
Ayano Tanabe is pursuing her PhD degree at Hokkaido University, Japan. She is also involved in development of a liquid-crystal device at Citizen Holdings Co. Ltd. Her current research interests include applications of biomedical imaging. She received her MSc degree in engineering from the University of Electro-Communications.
Terumasa Hibi received his BSc, MSc, and PhD degrees from Nagoya City University. He is an assistant professor at the Research Institute for Electronic Science, Hokkaido University. He has expertise in cell biology and microscopy.
Sari Ipponjima is pursuing her PhD degree at Hokkaido University, Japan. Her current research interests include applications of biomedical imaging. She received her MSc degree in information science from Hokkaido University and her BSc degree in physics from Nara Women’s University.
Kenji Matsumoto is an engineer at Citizen Holdings Co. Ltd. His recent interests are optics of microscopy and holography. He received his BS degree in engineering from the University of Electro-Communications.
Masafumi Yokoyama is a chief engineer at Citizen Holdings Co. Ltd. He graduated from Tokyo University of Science in 1987.
Makoto Kurihara graduated from Tokyo University of Science in 1985. He is interested in liquid crystals and their applications.
Nobuyuki Hashimoto received his BSc, MSc, and PhD degrees from Waseda University. After joining Citizen Holdings Co. Ltd., he has been involved in developing applications of liquid-crystal optics in displays, holography, optical data storage, laser printers, telescopes, and bio-imaging. He is a member of SPIE, OSA, and OSJ. He is the president of the holography research group (HODIC) of OSJ.