A Miniaturized Electrothermal-MEMS-Based Optical Coherence Tomography (OCT) Handheld Microscope
1
School of Integrated Circuits and Electronics, Beijing Institute of Technology, Beijing 100081, China
2
BIT Chongqing Institute of Microelectronics and Microsystems, Chongqing 400000, China
3
LightVision Technologies Inc., Ltd., Foshan 528000, China
*
Author to whom correspondence should be addressed.
Photonics 2024, 11(1), 17; https://0-doi-org.brum.beds.ac.uk/10.3390/photonics11010017
Submission received: 10 November 2023
/
Revised: 15 December 2023
/
Accepted: 19 December 2023
/
Published: 26 December 2023
(This article belongs to the Special Issue Technologies and Applications of Biophotonics)
Abstract
:Swept-source optical coherence tomography (SS-OCT), benefiting from its high sensitivity, relatively large penetration depth, and non-contact and non-invasive imaging capability, is ideal for human skin imaging. However, limited by the size and performance of the reported optical galvanometer scanners, existing portable/handheld OCT probes are still bulky, which makes continuously handheld imaging difficult. Here, we reported a miniaturized electrothermal-MEMS-based SS-OCT microscope that only weighs about 25 g and has a cylinder with a diameter of 15 mm and a length of 40 mm. This MEMS-based handheld imaging probe can achieve a lateral resolution of 25 μm, a 3D imaging time of 5 s, a penetration depth of up to 3.3 mm, and an effective imaging field of view (FOV) of 3 × 3 mm2. We have carried out both calibration plate and biological tissue imaging experiments to test the imaging performance of this microscope. OCT imaging of leaves, dragonfly, and human skin has been successfully obtained, showing the imaging performance and potential applications of this probe on human skin in the future.
1. Introduction
As the first protective barrier from the outside world, the skin is the largest organ of human body, and always closely responds to the balance of the endocrine environment [1,2]. The morphological structure of skin tissue is one of the important concerns that experts pay attention to regarding the physiological health of skin [3,4]. Existing clinical imaging techniques including high-frequency ultrasonography (US) and skin surface microscopy have been widely used for the diagnosis of numerous skin diseases, but still suffer from some limitations, such as poor contrast and a lack of depth information [5,6]. At the same time, benefiting from a high resolution, good imaging contrast and penetration depth, some other optical imaging modalities like laser speckle contrast imaging and photoacoustic microscopy have also been applied to study the vascular microcirculation of skin surface for studying the functional and structural information [7,8]. For example, Zhu et al. reported a transmission-type laser speckle contrast imaging technique for detecting blood flow distribution in thick tissue, successfully obtaining the information and dynamic changes in blood flow distribution in human subcutaneous skin with non-contact and a high resolution [9]. Yang et al. reported several innovative photoacoustic imaging techniques, such as 532/1064 nm dual-wavelength photoacoustic microscopy, a switchable optical and acoustic resolution photoacoustic dermoscope, and a miniaturized photoacoustic probe [10,11,12]. However, the resolution of laser speckle contrast imaging makes it hard to observe the capillary vasculature under a micro-level and still needs to be improved, and photoacoustic imaging always requires coupling gels, being easily affected by the bubbles inside the gels [13,14,15]. Featuring high optical sensitivity, a large penetration depth, non-contact and non-invasive imaging capability, optical coherence tomography (OCT) is considered a promising technology for human skin imaging [16]. Fujimoto et al. and Fercher et al. successfully developed the first time-domain OCT (TD-OCT) and Fourier-domain OCT (FD-OCT) in 1991 and 2002, respectively [17,18]. With faster imaging speed and good sensitivity as there is no need to move the reference arm to obtain the depth information, FD-OCT attracts more attention. Utilizing different laser sources and detection methods, two FD-OCT techniques, spectra-domain OCT (SD-OCT) and swept-source OCT (SS-OCT) were developed and applied in dermatology [19,20]. For example, Anthony J. Deegan et al. used a self-made clinical prototype OCT system to acquire OCT/OCTA images of patients undergoing medium and thick skin grafts after severe skin burns at multiple time points and multiple locations [20]. Compared with SD-OCT, SS-OCT has larger bandwidth, deeper penetration of biological tissues, and a high instantaneous coherence of sweep light sources, allowing for deeper longitudinal imaging ranges. SS-OCT is suitable for real-time observation of skin tissue structures with high resolution, fast imaging speed and relatively large imaging depth [21].
Most of the existing SS-OCT systems usually utilize galvanometer scanners for laser scanning, with a size similar to that of a tabletop optical microscope [22,23]. Handheld SS-OCT probes were proposed, but they were still bulky and inconvenient for long-time handheld imaging [24,25,26]. Thus, it is necessary to find miniaturized fast scanners for handheld SS-OCT imaging [27]. Micro-electro-mechanical system (MEMS) micromirrors are small and fast, and can thus be used to reduce the size and weight of imaging probes in optical imaging systems [28]. Many kinds of MEMS-based imaging techniques have been reported and applied in human skin imaging, demonstrating the feasibility of realizing miniaturized, portable and handheld imaging [26,27,28,29,30].
In this study, we proposed a miniaturized electrothermal-MEMS-based SS-OCT microscope, with a small size and light weight for long-time handheld clinical use. We applied the probe to capture the structure of some biological samples, such as the veins of leaves and the wings of a dragonfly. We also employed it to observe the tissue structures of a volunteer’s finger, fingernails and wounded skin, showing the clinical feasibility and potential of this technology.
2. Materials and Methods
2.1. System Configuration and the Imaging Probe Design
Figure 1 shows the configuration of the SS-OCT system (LVM-1000, Light Vision, China). A swept laser source (HSL-20, Santec, Japan) was utilized to emit a 1310 nm laser beam with a 100 nm bandwidth. The laser is transmitted through a single-mode fiber (SMF) and divided into two laser beams via a 2 × 2 coupler. One laser beam reaches the mirror in the reference arm through a polarization controller (PC) and a collimator (CL), while the other laser beam passes through the sample arm whose end is an MEMS-OCT probe. Interference signals are produced by the two laser beams reflected back from the reference arm and sample arm (imaging probe), respectively, and are detected via a balanced photodetector (PDB570C, Thorlabs, USA). Then, the signals are collected using a high-speed data acquisition card (ATS-9350, Alazar Inc., Canada) with a sampling rate of 250 MS/s. An MEMS controller is used to drive the MEMS mirror to generate 2D raster scanning and thus realize 3D OCT imaging. An external trigger signal is used to keep the synchronization among the laser emitting, MEMS scanning, and data acquisition.
In the bottom right corner of Figure 1, the schematic of the imaging probe is shown in the black dash box, with all optical and electrical components inside a small handheld tube. The optical path is designed as simply as possible, and a minimum number of components is used to reduce the volume size and weight of the probe. In detail, the laser beam output from the fiber is collimated via a fiber collimator (F230FC-C, Thorlabs Inc., USA), and then converged using a doublet lens with a diameter of 6 mm and a focal length of 30 mm (GCL-010601, Daheng Optics, China). An electrothermal MEMS scanner (WM-L5-5, WiO Tech., China) is used to reflect the converged light beam to the sample surface, and scans the laser beam in a raster pattern for three dimensional (3D) imaging. The miniaturized handheld probe is a cylinder with a diameter of 15 mm and a length of 40 mm, with a weight of 25 g. It has a spatial resolution of 25 μm, a temporal resolution of 5 s, and an imaging FOV of 3 × 3 mm2.
2.2. Sample Preparation and Experimental Process
The commercial and custom light stereotypes with target patterns are used to test the basic imaging performance of the imaging probe. In addition, two types of leaves with thick and dense veins were chosen and boiled in a 10% sodium hydroxide solution for 5 min. When the leaves turned black, they were rinsed carefully with clean water. A small test tube brush with soft hair was used to gently brush off the rotten mesophyll and clean it until only the veins were left. Finally, the leaf veins were dried to form experimental specimens for imaging. Dragonfly samples were purchased online, and the wings were partially used for biological imaging tests. For skin imaging, due to the characteristics of contactless, safe, and non-destructive imaging mode, after seeking the oral and written consent of a healthy volunteer, we used the probe to perform simple imaging operations on various parts of her skin, without involving any complex procedures. The single imaging time was of about 5 s, and all skin imaging experiments were finished within a few minutes, which also verifies the advantages of portability and speed of skin imaging by using our proposed handheld probe.
2.3. Data Acquisition and Processing
Commercial software (LVM-1000, OCT Viewer, Light Vision, China) was used for data acquisition, processing, and image reconstruction. Within the software’s platform, the underlying code was written based on Labview2019 software, with the functions of original signal filtering, Fourier transform processing, image reconstruction based on acquired 3D data, and image brightness enhancement, among others.
3. Results
3.1. Parameter Testing of the MEMS and MEMS-Based Handheld Probe
As the most important scanning components, a photograph of electrothermal MEMS inside the probe is also shown in Figure 2a. In Figure 2b,c, the testing curve of MEMS shows that the optical deflection angle is proportional to the driver voltages, and allowed for a maximum optical scanning angle of 8 degrees, with a 4 V DC voltage on the arms of MEMS, which corresponds to a maximal scanning range of 3 mm. We found that even though the MEMS mirror deflection has a similar linear correspondence to the voltage, when the given voltage is smaller than 1.6 V, and between 1.6 V to 4 V, it still has slightly different slopes. This is related to the circuit characteristics of the MEMS chip and inconsistency of the resistance values of the four MEMS drive arms. This is a well-known phenomenon for electrothermal MEMS mirrors [31,32].
A photograph of the probe is shown in Figure 3a, which is miniaturized and suitable for handheld imaging. To evaluate the spatial and lateral resolution of the SS-OCT probe, we imaged the pattern of a resolution plate. The minimum 5–3 line pair can be distinguished, indicating a practical imaging resolution of 25 μm, as shown in Figure 3b. We also tested the penetration depth of the probe by imaging the stack of cover glass with a known layer thickness of 150 μm. Figure 3c shows that the maximum number of observed cover glass is about 22, which corresponds to the penetration depth of 3.3 mm. In addition, we also imaged the photolithography patterns with known scales, and tested the FOV of the probe, which is about 3 × 3 mm2, as shown in Figure 3d.
3.2. The Ex Vivo Biological Sample and In Vivo Human Skin Imaging Results
To determine the performance of the miniaturized SS-OCT probe, we applied it to observe the biological specimens with dense vein structures. Figure 4a,b shows the imaging results of the veins’ texture in two leaves, showing sparsely and densely reticular structures, respectively. In addition, we also captured the veins of dragonfly wings, which were quadrilateral or pentagonal grids, as shown in Figure 4c. The enlarged view of a localized dragonfly wing marked with a yellow dash box shows that the wings were filled with complicated columnar structures, which played important roles during flight, helping to keep the wings from becoming stuck to each other with water and dust. These results demonstrated the potential of the SS-OCT microscope in high-resolution observation of microstructures of biological specimens.
We also carried out in vivo skin imaging experiments, including the fingernails, finger joints and the inner wrist, by using the miniaturized SS-OCT microscope. Figure 5(a-1) shows the photograph of a fingernail under biological microscopy. We carried out OCT imaging on the marked local site (red box), obtained the 3D visualization and x-z section view of the fingernail, and found densely and regularly connective tissue structures, as shown in Figure 5(a-2),(a-3). Furthermore, we employed the probe to observe the skin tissue structure and deep blood vessels on human finger joints, as shown in Figure 5(b-1)–(b-3). The skin tissue structure of the volunteers’ inner wrist was visualized using OCT imaging, including the epidermal folds, internal blisters, and damaged skin tissue on the scalded site, as shown in Figure 5(c-1)–(c-3). In the soft skin tissue, obviously irregular boundaries due to the rich biological compositions were observed. The in vivo imaging results also showed that the miniaturized probe had the capability to visualize skin structures with satisfactory imaging performance.
4. Discussion
SS-OCT is a popular imaging technology and is widely used in fundamental and clinical studies [33,34,35], especially for biological tissue imaging, considering that skin tissue has strong optical absorption and scattering characteristics, which will affect the penetration depth of lasers. In order to maximize the imaging depth, the near-infrared band is generally used for imaging, such as 1060 nm or 1310 nm. With an increase in the wavelength, the scattering decreases strongly. Therefore, we finally selected the 1310 nm wavelength to minimize the scattering even though 1310 nm has stronger absorption from the water than 1060 nm. While imaging, 3D imaging with high performance can be realized using either a motor stage or galvanometer. However, motor stages have a slow scanning speed and will cause motion artifacts, and this scanning method is gradually eliminated. On the other hand, the use of galvanometer scanning for imaging can solve the above problems, but still has a bulky size, which will lead to operation fatigue with handheld imaging for a long time [36,37]. With the rapid development of MEMS, electrothermal MEMS mirrors have been widely used in biological imaging, which benefits from their low-voltage driving, large scanning angle, small size and low cost [30,38]. In this study, we applied electrothermal MEMS to SS-OCT imaging, and demonstrated a handheld imaging probe with a simple optical design and high imaging performance, which greatly reduces the instrument’s size and weight, and provides a new technology for biological imaging.
This paper describes a handheld SS-OCT probe with an internal simple optical light path and relative miniaturized mechanical structure that is easy to install. Using a 2D electrothermal MEMS for laser scanning and imaging can effectively reduce the size and weight of the probe, with a low cost. We tested its imaging performance including a lateral resolution of 25 μm, a penetration depth of 3.3 mm, and a scanning range of 3 × 3 mm2, among other factors. In addition, we also used the handheld probe to carry out high-resolution imaging of in vitro biological samples and in vivo human skin tissue, demonstrating a good three-dimensional imaging performance. It is worth explaining that the theoretical penetration depth of a 1310 laser is large, but the actual biological imaging depth is still relatively shallow, which is closely related to the physical characteristics of different tissues. For example, the nail imaging depth is only of about 0.8 mm due to the thick interdigital cortex, and the skin tissue can only reach about 1.5 mm imaging depth because of the epidermal pigmentation and blood vessel absorption in the dermis, which may reduce the useful backscattered light (Figure 5(a-3),(b-3),(c-3)). The more tender skin tissue, such as the face skin and the inner arm skin, will allow for a more satisfactory imaging depth. Even so, the nail imaging results still clearly show the distribution of the stratum corneum structure, showing the potential to study gray-nail-related diseases. The human finger abdominal imaging results also demonstrate that the SS-OCT probe has potential applications in arthritis studies. In addition to benefiting from the non-contact and non-invasive imaging capability, this MEMS-based SS-OCT microscope may have good potential applications in the dermatology of burn and cosmetic surgery.
It is worth considering that our proposed handheld MEMS-based microscope still has some limitations and needs further improvements. The relatively small size of the MEMS mirror plate may cause some optical loss and decreased penetration depth, while limiting the size of the spot irradiated will also lead to insufficient imaging resolution. Although an MEMS can achieve scanning with safe and low voltages, the scanning angle and the performance of resistance to vibration and drop damage still need to be improved. In the future, it is important to develop or use innovative MEMS scanners with a larger scanning angle and better anti-fall characteristics. We also need to optimize the internal design of the handheld microscope to improve the lateral resolution, FOV and imaging stability. The design of a user-friendly handheld appearance should also be considered to make it more practical and useful.
5. Conclusions
In summary, we developed a miniaturized electrothermal MEMS-based SS-OCT microscope probe, which has the characteristics of small size, light weight, high resolution and fast imaging speed. We carried out both in vitro biological specimen imaging and in vivo human skin imaging experiments. The imaging results showed that the microscope has the potential to examine biological tissue structures in human skin. Our proposed MEMS-based handheld SS-OCT microscope has a simple structure, which is more lightweight and portable to use. Within the probe, the scanning voltage of the MEMS mirror is also safer and more reliable than that of the existing benchtop or galvanoscope-based imaging terminals. In the future, we need to optimize the key scanning components of the MEMS probe to achieve a better imaging performance, such as higher resolution, larger FOV, a more user-friendly design and more comfortable use. We will also add more functional modules inside the system, combined with other imaging modes such as photoacoustic microscopy or confocal fluorescence microscopy, to obtain richer structural and functional information. These new techniques can be used for the diagnosis and treatment of clinic dermatoid diseases of scar hyperplasia, melanoma, pemphigus, acne, and psoriasis, among others. Meanwhile, we will also continue to use the proposed SS-OCT probe to carry out more profound biological application research to study some developmental processes and mechanisms of diseases.
Author Contributions
Five authors specify their individual contributions to this research article. Conceptualization, H.X.; methodology, H.X. and Q.C.; software, H.Z. and H.W.; validation, Q.C. and T.Q.; formal analysis, Q.C.; investigation, T.Q.; data curation, Q.C.; writing—original draft preparation, Q.C.; writing—review and editing, H.X. and Hui Zhao; visualization, Q.C.; project administration, H.X.; funding acquisition, Q.C. and H.Z. All authors have read and agreed to the published version of the manuscript.
Funding
This research was funded by the China Postdoctoral Science Foundation, grant number 2022M720439, and the Foshan Technology Innovation Team Project, grant number 2018IT100252.
Data Availability Statement
All the data and codes used to derive the findings of this study are available from the corresponding author upon reasonable request.
Conflicts of Interest
Authors, Hui Zhao and Huikai Xie were employed by the company The LightVision Technologies Inc. Ltd. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
References
- Wang, M.; Luo, Y.; Wang, T.; Wan, C.; Pan, L.; Pan, S.; He, K.; Neo, A.; Chen, X. Artificial Skin Perception. Adv. Mater. 2021, 33, 2003014. [Google Scholar] [CrossRef] [PubMed]
- Douzinas, E.E. Biochemical structural and physical changes in aging human skin, and their relationship. Biogerontology 2022, 23, 275–288. [Google Scholar]
- Yu, R.; Zhang, H.L.; Guo, B.L. The cerebral microcirculation is protected during experimental hemorrhagic shock. Nanomicro. Lett. 2022, 14, 1. [Google Scholar]
- Waszczuk, L.; Ogien, J.; Perrot, J.L.; Dubois, A. Co-localized line-field confocal optical coherence tomography and confocal Raman microspectroscopy for three-dimensional high-resolution morphological and molecular characterization of skin tissues ex vivo. Biomed. Opt. Express 2022, 13, 2467–2487. [Google Scholar] [CrossRef]
- Polańska, A.; Bowszyc-Dmochowska, M.; Olek-Hrab, K.; Adamski, Z.; Żaba, R.; Dańczak-Pazdrowska, A. High-frequency ultrasonography a new quantitative method in evaluation of skin lymphomas—First comparative study in relation to histopathology. Ski. Res. Technol. 2019, 25, 720–724. [Google Scholar] [CrossRef]
- Westerhoff, K.; Mccarthy, W.H.; Menzies, S.W. Increase in the sensitivity for melanoma diagnosis by primary care physicians using skin surface microscopy. Br. J. Dermatol. 2008, 143, 1016–1020. [Google Scholar] [CrossRef]
- Lazaridis, A.; Triantafyllou, A.; Dipla, K.; Dolgyras, P.; Koletsos, N.; Anyfanti, P.; Aslanidis, S.; Douma, S.; Gkaliagkousi, E. Skin microvascular function, as assessed with laser speckle contrast imaging, is impaired in untreated essential and masked hypertension. Hypertens. Res. 2022, 45, 445–454. [Google Scholar] [CrossRef]
- Matsumoto, Y.; Asao, Y.; Yoshikawa, A.; Sekiguchi, H.; Takada, M.; Furu, M.; Saito, S.; Kataoka, M.; Abe, H.; Yagi, T.; et al. Label-free photoacoustic imaging of human palmar vessels: A structural morphological analysis. Sci. Rep. 2018, 8, 786. [Google Scholar] [CrossRef]
- Dong, Y.L.; Xia, Q.; Yu, T.T.; Zhu, J.T.; Zhu, D. Transmissive-detected laser speckle contrast imaging for blood flow monitoring in thick tissue: From Monte Carlo simulation to experimental demonstration. Light. Sci. Appl. 2021, 10, 241. [Google Scholar]
- Wang, Z.; Yang, F.; Ma, H.; Cheng, Z.; Zhang, W.; Xiong, K.; Shen, T.; Yang, S. Bifocal 532/1064 nm alternately illuminated photoacoustic microscopy for capturing deep vascular morphology in human skin. J. Eur. Acad. Dermatol. Venereol. 2022, 36, 51–59. [Google Scholar] [CrossRef]
- Ma, H.G.; Cheng, Z.W.; Wang, Z.Y.; Zhang, W.; Yang, S. Switchable optical and acoustic resolution photoacoustic dermoscope dedicated into in vivo biopsy-like of human skin. Appl. Phys. Lett. 2020, 116, 073703. [Google Scholar] [CrossRef]
- Zhang, W.Y.; Ma, H.G.; Cheng, Z.W.; Wang, Z.; Zhang, L.; Yang, S. Miniaturized photoacoustic probe for in vivo imaging of subcutaneous microvessels within human skin. Quant. Imaging Med. Surg. 2019, 9, 807–814. [Google Scholar] [CrossRef] [PubMed]
- Chizari, A.; Schaap, M.J.; Knop, T.; Boink, Y.E.; Seyger, M.M.; Steenbergen, W. V Handheld versus mounted laser speckle contrast perfusion imaging demonstrated in psoriasis lesions. Sci. Rep. 2021, 11, 16646. [Google Scholar] [CrossRef] [PubMed]
- Chen, Z.; Rank, E.; Meiburger, K.M.; Sinz, C.; Hodul, A.; Zhang, E.; Hoover, E.; Minneman, M.; Ensher, J.; Beard, P.C.; et al. Non-invasive multimodal optical coherence and photoacoustic tomography for human skin imaging. Sci. Rep. 2017, 7, 17975. [Google Scholar] [CrossRef] [PubMed]
- Ahn, J.; Kim, J.Y.; Choi, W.; Kim, C. High-resolution functional photoacoustic monitoring of vascular dynamics in human fingers. Photoacoustics 2021, 23, 100282. [Google Scholar] [CrossRef] [PubMed]
- Welzel, J.; Schuh, S. Optical coherence tomography for skin pathologies. Ophthalmologe 2018, 115, 524–527. [Google Scholar] [CrossRef]
- Huang, D.; Swanson, E.A.; Lin, C.P.; Schuman, J.S.; Stinson, W.G.; Chang, W.; Hee, M.R.; Flotte, T.; Gregory, K.; Puliafito, C.A.; et al. Optical coherence tomography. Science 1991, 254, 1178–1181. [Google Scholar] [CrossRef]
- Wojtkowski, M.; Leitgeb, R.; Kowalczyk, A.; Bajraszewski, T.; Fercher, A.F. In vivo human retinal imaging by Fourier domain optical coherence tomography. J. Biomed. Opt. 2002, 7, 457–463. [Google Scholar] [CrossRef]
- Deegan, A.J.; Lu, J.; Sharma, R.; Mandell, S.P.; Wang, R.K. Imaging human skin autograft integration with optical coherence tomography. Quant. Imaging Med. Surg. 2021, 11, 784–796. [Google Scholar] [CrossRef]
- Adabi, S.S.; Hosseinzadeh, M.; Noei, S.; Conforto, S.; Daveluy, S.; Clayton, A.; Mehregan, D.; Nasiriavanaki, M. Universal in vivo Textural Model for Human Skin based on Optical Coherence Tomograms. Sci. Rep. 2017, 7, 17912. [Google Scholar] [CrossRef]
- Ghosh, B.; Mandal, M.; Mitra, P.; Chatterjee, J. Attenuation corrected-optical coherence tomography for quantitative assessment of skin wound healing and scar morphology. J. Biophotonics 2020, 14, e202000357. [Google Scholar] [CrossRef] [PubMed]
- Jian, Y.; Lee, S.; Ju, M.; Heisler, M.; Ding, W.; Zawadzki, R.J.; Bonora, S.; Sarunic, M.V. Lens-based wavefront sensorless adaptive optics swept source OCT. Sci. Rep. 2016, 6, 27620. [Google Scholar] [CrossRef] [PubMed]
- Britten, A.; Matten, P.; Weiss, J.; Niederleithner, M.; Roodaki, H.; Sorg, B.; Hecker-Denschlag, N.; Drexler, W.; Leitgeb, R.A.; Schmoll, T. Surgical microscope integrated MHz SS-OCT with live volumetric visualization. Biomed. Opt. Express 2023, 14, 846–865. [Google Scholar] [CrossRef] [PubMed]
- Lee, C.K.; Tsai, M.T.; Chang, F.Y.; Yang, C.-H.; Shen, S.-C.; Yuan, O.; Yang, C.-H. Evaluation of Moisture-Related Attenuation Coefficient and Water Diffusion Velocity in Human Skin Using Optical Coherence Tomography. Sensors 2013, 13, 4041–4050. [Google Scholar] [CrossRef] [PubMed]
- He, Q.H.; Liu, T.; Wang, R.K. Handheld swept-source optical coherence tomography guided by smartphone-enabled wide-field autofluorescence photography for imaging facial sebaceous glands. Opt. Lett. 2020, 45, 5704–5707. [Google Scholar] [CrossRef] [PubMed]
- Lu, C.D.; Kraus, M.F.; Potsaid, B.; Liu, J.J.; Choi, W.; Jayaraman, V.; Cable, A.E.; Hornegger, J.; Duker, J.S.; Fujimoto, J.G. Handheld ultrahigh speed swept source optical coherence tomography instrument using a MEMS scanning mirror. Biomed. Opt. Express 2014, 5, 293–311. [Google Scholar] [CrossRef] [PubMed]
- Sancho-Durá, J.; Zinoviev, K.; Lloret-Soler, J.; Rubio-Guviernau, J.L.; Margallo-Balbás, E.; Drexler, W. Handheld multi-modal imaging for point-of-care skin diagnosis based on akinetic integrated optics optical coherence tomography. J. Biophotonics 2018, 11, e201800193. [Google Scholar] [CrossRef] [PubMed]
- Chen, Q.; Guo, H.; Jin, T.; Qi, W.; Xie, H.; Xi, L. Ultracompact high-resolution photoacoustic microscopy. Opt. Lett. 2018, 43, 1615–1618. [Google Scholar] [CrossRef]
- Qin, W.; Chen, Q.; Xi, L. A handheld microscope integrating photoacoustic microscopy and optical coherence tomography. Biomed. Opt. Express 2018, 9, 2205–2213. [Google Scholar] [CrossRef]
- Gorecki, C.; Bargie, S. MEMS scanning mirrors for optical coherence tomography. Photonics 2020, 8, 6. [Google Scholar] [CrossRef]
- Jia, K.M.; Pal, S.; Xie, H.K. An Electrothermal Tip–Tilt–Piston Micromirror Based on Folded Dual S-Shaped Bimorphs. J. Microelectromechanical Syst. 2009, 18, 1004–1015. [Google Scholar]
- Zhang, X.Y. Robust Electrothermally Actuated Scanners for Fiberoptic Endoscopic Imaging and Wide-Angle Optics; ProQuest LLC: Ann Arbor, MI, USA, 2018; p. 10987163. [Google Scholar]
- Chen, W.; You, J.; Gu, X.; Du, C.; Pan, Y. High-speed swept source optical coherence Doppler tomography for deep brain microvascular imaging. Sci. Rep. 2016, 6, 38786. [Google Scholar] [CrossRef] [PubMed]
- Lee, C.O.; Zhang, X.; Yuan, N.; Tang, S.; Chen, L.J.; Cheung, C.Y.; Yam, J.C. Comparison of choroidal thickness measurements between spectral domain optical coherence tomography and swept source optical coherence tomography in children. Sci. Rep. 2021, 11, 13749. [Google Scholar] [CrossRef] [PubMed]
- Baran, U.; Qin, W.; Qi, X.; Kalkan, G.; Wang, R.K. OCT-based label-free in vivo lymphangiography within human skin and areola. Sci. Rep. 2016, 6, 21122. [Google Scholar] [CrossRef]
- Shimada, Y.; Burrow, M.F.; Araki, K.; Zhou, Y.; Hosaka, K.; Sadr, A.; Yoshiyama, M.; Miyazaki, T.; Sumi, Y.; Tagami, J. 3D imaging of proximal caries in posterior teeth using optical coherence tomography. Sci. Rep. 2020, 10, 15754. [Google Scholar] [CrossRef]
- Tsai, M.T.; Chen, Y.; Lee, C.Y.; Huang, B.-H.; Trung, N.H.; Lee, Y.-J.; Wang, Y.-L. Noninvasive structural and microvascular anatomy of oral mucosae using handheld optical coherence tomography. Biomed. Opt. Express 2017, 8, 5001–5012. [Google Scholar] [CrossRef]
- Park, H.C.; Zhang, X.; Yuan, W.; Zhou, L.; Xie, H.; Li, X. Ultralow-voltage electrothermal MEMS based fiber-optic scanning probe for forward-viewing endoscopic OCT. Opt. Lett. 2019, 44, 2232–2235. [Google Scholar] [CrossRef]
Figure 1.
The schematic of the SS-OCT system and the inside structure of the imaging probe. SMF, Signal-Mode Fiber; PC, Polarization Controller; CL, Collimator; RM, Reflector Mirror; APD, Avalanche Photodiode; DL, Doublet Lens; PF, Polymer Film; S, Sample.
Figure 1.
The schematic of the SS-OCT system and the inside structure of the imaging probe. SMF, Signal-Mode Fiber; PC, Polarization Controller; CL, Collimator; RM, Reflector Mirror; APD, Avalanche Photodiode; DL, Doublet Lens; PF, Polymer Film; S, Sample.
Figure 2.
Photograph of MEMS and its performance testing. (a) Photograph of the MEMS under optical microscopy. (b) The testing optical deflection angle and driver voltage curve of MEMS. (c) The scanning range of the MEMS under different optical deflection angles.
Figure 2.
Photograph of MEMS and its performance testing. (a) Photograph of the MEMS under optical microscopy. (b) The testing optical deflection angle and driver voltage curve of MEMS. (c) The scanning range of the MEMS under different optical deflection angles.
Figure 3.
Photograph of the handheld SS-OCT probe and its imaging testing including imaging resolution, penetration depth and FOV. (a) Photograph of the imaging probe. (b) Using the microscope to image the known resolution plate. (c) The imaging result of the biological cover glass sheet stack, with a known thickness of each glass sheet. (d) The imaging result of a custom mask plate with known photolithography patterns for FOV calculation.
Figure 3.
Photograph of the handheld SS-OCT probe and its imaging testing including imaging resolution, penetration depth and FOV. (a) Photograph of the imaging probe. (b) Using the microscope to image the known resolution plate. (c) The imaging result of the biological cover glass sheet stack, with a known thickness of each glass sheet. (d) The imaging result of a custom mask plate with known photolithography patterns for FOV calculation.
Figure 4.
Using the SS-OCT microscope to observe the microstructure of biological specimens like leaves and dragonfly. (a,b) The sparse and dense vein structure of two strains of leaves. (c) The wing structure of a specimen of dragonfly and an enlarged view of a localized dragonfly wing marked with a yellow dash box.
Figure 4.
Using the SS-OCT microscope to observe the microstructure of biological specimens like leaves and dragonfly. (a,b) The sparse and dense vein structure of two strains of leaves. (c) The wing structure of a specimen of dragonfly and an enlarged view of a localized dragonfly wing marked with a yellow dash box.
Figure 5.
Photographs and corresponding SS-OCT imaging results of a fingernail (a), finger joint (b), and inner wrist skin (c). (a-1) The observation of a fingernail under biological microscopy. (a-2,a-3) The 3D visualization and x-z section view of the fingernail structure via SS-OCT imaging. (b-1) The observation of a finger joint under biological microscopy. (b-2,b-3) The 3D visualization and x-z section view of the skin structure in figure joints via SS-OCT imaging. (c-1) The observation of a volunteers’ inner arm wrist under biological microscopy. (c-2,c-3) The 3D visualization and x-z section view of the localized scalded skin on a volunteer’s inner wrist.
Figure 5.
Photographs and corresponding SS-OCT imaging results of a fingernail (a), finger joint (b), and inner wrist skin (c). (a-1) The observation of a fingernail under biological microscopy. (a-2,a-3) The 3D visualization and x-z section view of the fingernail structure via SS-OCT imaging. (b-1) The observation of a finger joint under biological microscopy. (b-2,b-3) The 3D visualization and x-z section view of the skin structure in figure joints via SS-OCT imaging. (c-1) The observation of a volunteers’ inner arm wrist under biological microscopy. (c-2,c-3) The 3D visualization and x-z section view of the localized scalded skin on a volunteer’s inner wrist.
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content. |
© 2023 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Share and Cite
MDPI and ACS Style
Chen, Q.; Zhao, H.; Qi, T.; Wang, H.; Xie, H. A Miniaturized Electrothermal-MEMS-Based Optical Coherence Tomography (OCT) Handheld Microscope. Photonics 2024, 11, 17. https://0-doi-org.brum.beds.ac.uk/10.3390/photonics11010017
AMA Style
Chen Q, Zhao H, Qi T, Wang H, Xie H. A Miniaturized Electrothermal-MEMS-Based Optical Coherence Tomography (OCT) Handheld Microscope. Photonics. 2024; 11(1):17. https://0-doi-org.brum.beds.ac.uk/10.3390/photonics11010017
Chicago/Turabian StyleChen, Qian, Hui Zhao, Tingxiang Qi, Hua Wang, and Huikai Xie. 2024. "A Miniaturized Electrothermal-MEMS-Based Optical Coherence Tomography (OCT) Handheld Microscope" Photonics 11, no. 1: 17. https://0-doi-org.brum.beds.ac.uk/10.3390/photonics11010017
Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.
