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1. Fasudil and viscosity of gelatin promote hepatic differentiation by regulating organelles in human umbilical cord matrix-mesenchymal stem cells

Author

Jiwan Choi, Seoon Kang, Hye-In An, Chae-Eun Kim, Sanghwa Lee, Chan-Gi Pack, Young-In Yoon, Hana Jin, Yong-Pil Cho, Chong Jai Kim, Jung-Man Namgoong, Jun Ki Kim, and Eunyoung Tak

Subjects
Human umbilical cord matrix-mesenchymal stem cells, Gelatin viscosity, ROCK inhibitor, Fasudil, Hepatic differentiation, Mitochondria activation, Medicine (General), R5-920, Biochemistry, QD415-436
Abstract

Abstract Background Human mesenchymal stem cells originating from umbilical cord matrix are a promising therapeutic resource, and their differentiated cells are spotlighted as a tissue regeneration treatment. However, there are limitations to the medical use of differentiated cells from human umbilical cord matrix-mesenchymal stem cells (hUCM-MSCs), such as efficient differentiation methods. Methods To effectively differentiate hUCM-MSCs into hepatocyte-like cells (HLCs), we used the ROCK inhibitor, fasudil, which is known to induce endoderm formation, and gelatin, which provides extracellular matrix to the differentiated cells. To estimate a differentiation efficiency of early stage according to combination of gelatin and fasudil, transcription analysis was conducted. Moreover, to demonstrate that organelle states affect differentiation, we performed transcription, tomographic, and mitochondrial function analysis at each stage of hepatic differentiation. Finally, we evaluated hepatocyte function based on the expression of mRNA and protein, secretion of albumin, and activity of CYP3A4 in mature HLCs. Results Fasudil induced endoderm-related genes (GATA4, SOX17, and FOXA2) in hUCM-MSCs, and it also induced lipid droplets (LDs) inside the differentiated cells. However, the excessive induction of LDs caused by fasudil inhibited mitochondrial function and prevented differentiation into hepatoblasts. To prevent the excessive LDs formation, we used gelatin as a coating material. When hUCM-MSCs were induced into hepatoblasts with fasudil on high-viscosity (1%) gelatin-coated dishes, hepatoblast-related genes (AFP and HNF4A) showed significant upregulation on high-viscosity gelatin-coated dishes compared to those treated with low-viscosity (0.1%) gelatin. Moreover, other germline cell fates, such as ectoderm and mesoderm, were repressed under these conditions. In addition, LDs abundance was also reduced, whereas mitochondrial function was increased. On the other hand, unlike early stage of the differentiation, low viscosity gelatin was more effective in generating mature HLCs. In this condition, the accumulation of LDs was inhibited in the cells, and mitochondria were activated. Consequently, HLCs originated from hUCM-MSCs were genetically and functionally more matured in low-viscosity gelatin. Conclusions This study demonstrated an effective method for differentiating hUCM-MSCs into hepatic cells using fasudil and gelatin of varying viscosities. Moreover, we suggest that efficient hepatic differentiation and the function of hepatic cells differentiated from hUCM-MSCs depend not only on genetic changes but also on the regulation of organelle states.

Published
2024
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2. Wall Shear Stress (WSS) Analysis in Atherosclerosis in Partial Ligated Apolipoprotein E Knockout Mouse Model through Computational Fluid Dynamics (CFD)

Author

Minju Cho, Joon Seup Hwang, Kyeong Ryeol Kim, and Jun Ki Kim

Subjects
atherosclerosis, plaque formation, computational fluid dynamics (CFD), wall shear stress (WSS), ApoE-KO mice, standard deviation, Biology (General), QH301-705.5, Chemistry, QD1-999
Abstract

Atherosclerosis involves an inflammatory response due to plaque formation within the arteries, which can lead to ischemic stroke and heart disease. It is one of the leading causes of death worldwide, with various contributing factors such as hyperlipidemia, hypertension, obesity, diabetes, and smoking. Wall shear stress (WSS) is also known as a contributing factor of the formation of atherosclerotic plaques. Since the causes of atherosclerosis cannot be attributed to a single factor, clearly understanding the mechanisms and causes of its occurrence is crucial for preventing the disease and developing effective treatment strategies. To better understand atherosclerosis and define the correlation between various contributing factors, computational fluid dynamics (CFD) analysis is primarily used. CFD simulates WSS, the frictional force caused by blood flow on the vessel wall with various hemodynamic changes. Using apolipoprotein E knockout (ApoE-KO) mice subjected to partial ligation and a high-fat diet at 1-week, 2-week, and 4-week intervals as an atherosclerosis model, CFD analysis was conducted along with the reconstruction of carotid artery blood flow via magnetic resonance imaging (MRI) and compared to the inflammatory factors and pathological staining. In this experiment, a comparative analysis of the effects of high WSS and low WSS was conducted by comparing the standard deviation of time-averaged wall shear stress (TAWSS) at each point within the vessel wall. As a novel approach, the standard deviation of TAWSS within the vessel was analyzed with the staining results and pathological features. Since the onset of atherosclerosis cannot be explained by a single factor, the aim was to find the correlation between the thickness of atherosclerotic plaques and inflammatory factors through standard deviation analysis. As a result, the gap between low WSS and high WSS widened as the interval between weeks in the atherosclerosis mouse model increased. This finding not only linked the occurrence of atherosclerosis to WSS differences but also provided a connection to the causes of vulnerable plaques.

Published
2024
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3. Label‐free atherosclerosis diagnosis through a blood drop of apolipoprotein E knockout mouse model using surface‐enhanced Raman spectroscopy validated by machine learning algorithm

Author

Sanghwa Lee, Miyeon Jue, Minju Cho, Kwanhee Lee, Bjorn Paulson, Hanjoong Jo, Joon Seon Song, Soo‐Jin Kang, and Jun Ki Kim

Subjects
ApoE KO mouse, atherosclerosis, nano‐sized biomarker, principal component analysis, surface‐enhanced Raman spectroscopy, Chemical engineering, TP155-156, Biotechnology, TP248.13-248.65, Therapeutics. Pharmacology, RM1-950
Abstract

Abstract The direct preventative detection of flow‐induced atherosclerosis remains a significant challenge, impeding the development of early treatments and prevention measures. This study proposes a method for diagnosing atherosclerosis in the carotid artery using nanometer biomarker measurements through surface‐enhanced Raman spectroscopy (SERS) from single‐drop blood samples. Atherosclerotic acceleration is induced in apolipoprotein E knockout mice which underwent a partial carotid ligation and were fed a high‐fat diet to rapidly induce disturbed flow‐induced atherosclerosis in the left common carotid artery while using the unligated, contralateral right carotid artery as control. The progressive atherosclerosis development of the left carotid artery was verified by micro‐magnetic resonance imaging (micro‐MRI) and histology in comparison to the right carotid artery. Single‐drop blood samples are deposited on chips of gold‐coated ZnO nanorods grown on silicon wafers that filter the nanometer markers and provide strong SERS signals. A diagnostic classifier was established based on principal component analysis (PCA), which separates the resultant spectra into the atherosclerotic and control groups. Scoring based on the principal components enabled the classification of samples into control, mild, and severe atherosclerotic disease. The PCA‐based analysis was validated against an independent test sample and compared against the PCA‐PLS‐DA machine learning algorithm which is known for applicability to Raman diagnosis. The accuracy of the PCA modification‐based diagnostic criteria was 94.5%, and that of the machine learning algorithm 97.5%. Using a mouse model, this study demonstrates that diagnosing and classifying the severity of atherosclerosis is possible using a single blood drop, SERS technology, and machine learning algorithm, indicating the detectability of biomarkers and vascular factors in the blood which correlate with the early stages of atherosclerosis development.

Published
2023
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4. Smartphone-Based Rigid Endoscopy Device with Hemodynamic Response Imaging and Laser Speckle Contrast Imaging

Author

Youngkyu Kim, Woo June Choi, Jeongmin Oh, Kwanhee Lee, and Jun Ki Kim

Subjects
point-of-care, smartphone, laser speckle contrast imaging, hemodynamic response imaging, animal model of ischemia, Biotechnology, TP248.13-248.65
Abstract

Modern smartphones have been employed as key elements in point-of-care (POC) devices due to remarkable advances in their form factor, computing, and display performances. Recently, we reported a combination of the smartphone with a handheld endoscope using laser speckle contrast imaging (LSCI), suggesting potential for functional POC endoscopy. Here, we extended our work to develop a smartphone-combined multifunctional handheld endoscope using dual-wavelength LSCI. Dual-wavelength LSCI is used to monitor the changes in dynamic blood flow as well as changes in the concentration of oxygenated (HbO2), deoxygenated (Hbr), and total hemoglobin (HbT). The smartphone in the device performs fast acquisition and computation of the raw LSCI data to map the blood perfusion parameters. The flow imaging performance of the proposed device was tested with a tissue-like flow phantom, exhibiting a speckle flow index map representing the blood perfusion. Furthermore, the device was employed to assess the blood perfusion status from an exteriorized intestine model of rat in vivo during and after local ischemia, showing that blood flow and HbO2 gradually decreased in the ischemic region whereas hyperemia and excess increases in HbO2 were observed in the same region right after reperfusion. The results indicate that the combination of LSCI with smartphone endoscopy delivers a valuable platform for better understanding of the functional hemodynamic changes in the vasculatures of the internal organs, which may benefit POC testing for diagnosis and treatment of vascular diseases.

Published
2023
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5. Fabry–Perot Interferometric Fiber-Optic Sensor for Rapid and Accurate Thrombus Detection

Author

Marjan Ghasemi, Jeongmin Oh, Sunghoon Jeong, Mingyu Lee, Saeed Bohlooli Darian, Kyunghwan Oh, and Jun Ki Kim

Subjects
thrombus detection, fiber optic sensor, fabry perot interferometer, biological sensing, Biotechnology, TP248.13-248.65
Abstract

We present a fiber-optic sensor based on the principles of a Fabry–Perot interferometer (FPI), which promptly, sensitively, and precisely detects blood clot formation. This sensor has two types of sensor tips; the first was crafted by splicing a tapered fiber into a single-mode fiber (SMF), where fine-tuning was achieved by adjusting the tapered diameter and length. The second type is an ultra-compact blood FPI situated on the core of a single-mode fiber. The sensor performance was evaluated via clot-formation-indicating spectrum shifts induced by the varied quantities of a thrombin reagent introduced into the blood. The most remarkable spectral sensitivity of the micro-tip fiber type was approximately 7 nm/μL, with a power sensitivity of 4.1 dB/μL, obtained with a taper fiber diameter and length of 55 and 300 μm, respectively. For the SMF type, spectral sensitivity was observed to be 8.7 nm/μL, with an optical power sensitivity of 0.4 dB/μL. This pioneering fiber-optic thrombosis sensor has the potential for in situ applications, healthcare, medical monitoring, harsh environments, and chemical and biological sensing. The study underscores the scope of optical technology in thrombus detection, establishing a platform for future medical research and application.

Published
2023
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6. Spectral Multiplexing of Fluorescent Endoscopy for Simultaneous Imaging with Multiple Fluorophores and Multiple Fields of View

Author

Bjorn Paulson, Saeed Bohlooli Darian, Youngkyu Kim, Jeongmin Oh, Marjan Ghasemi, Kwanhee Lee, and Jun Ki Kim

Subjects
microendoscopy, multichannel, attachable endoscope system, spectral multiplexing, dual endoscope, lens relay, Biotechnology, TP248.13-248.65
Abstract

Complex clinical procedures and small-animal research procedures can benefit from dual-site imaging provided by multiple endoscopic devices. Here, an endoscopic system is proposed which enables multiple fluorescence microendoscopes to be spectrally multiplexed on a single microscope base, enabling light sources and optical relays to be shared between endoscopes. The presented system is characterized for resolution using USAF-1951 resolution test charts and for modulation transfer function using the slanted edge method. Imaging is demonstrated both directly and with microendoscopes attached. Imaging of phantoms was demonstrated by targeting USAF charts and fiber tissues dyed for FITC and Texas Red fluorescence. Afterwards, simultaneous liver and kidney imaging was demonstrated in mice expressing mitochondrial Dendra2 and injected with Texas Red-dextran. The results indicate that the system achieves high channel isolation and submicron and subcellular resolution, with resolution limited by the endoscopic probe and by physiological movement during endoscopic imaging. Multi-channel microendoscopy provides a potentially low-cost means of simultaneous multiple endoscopic imaging during biological experiments, resulting in reduced animal harm and potentially increasing insight into temporal connections between connected biological systems.

Published
2022
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7. A Wi-Fi–Based Mask-Type Laryngoscope for Telediagnosis During the COVID-19 Pandemic: Instrument Validation Study

Author

Youngjin Moon, Jaeho Hyun, Jeongmin Oh, Kwanhee Lee, Yoon Se Lee, and Jun Ki Kim

Subjects
Computer applications to medicine. Medical informatics, R858-859.7, Public aspects of medicine, RA1-1270
Abstract

BackgroundOwing to the COVID-19 pandemic, social distancing has become mandatory. Wireless endoscopy in contactless examinations promises to protect health care workers and reduce viral spread. ObjectiveThis study aimed to introduce a contactless endoscopic diagnosis system using a wireless endoscope resembling a mask. MethodsThe Wi-Fi–based contactless mask endoscopy system comprises a disposable endoscope and a controller. First, the effective force applied by the tip during insertion was evaluated in a simple transoral model consisting of a force sensor on a simulated oropharynx wall. Second, the delay in video streaming was evaluated by comparing the frame rate and delays between a movement and its image over direct and Wi-Fi connections. Third, the system was applied to a detailed laryngopharyngeal tract phantom. ResultsThe smartphone-controlled wireless endoscopy system was successfully evaluated. The mean, maximum, and minimum collision forces against the wall of the transoral model were 296 mN (30 gf), 363 mN (37 gf), and 235 mN (24 gf), respectively. The delay resulting from the wireless connection was 0.72 seconds. Using the phantom, an inexperienced user took around 1 minute to orient the endoscope to a desired area via the app. ConclusionsDevice articulation does not pose a significant risk of laryngopharyngeal wall penetration, and latency does not significantly impede its use. Contactless wireless video streaming was successful within the access point range regardless of the presence of walls. The mask endoscope can be controlled and articulated wirelessly, minimizing contact between patients and device operators. By minimizing contact, the device can protect health care workers from infectious viruses like the coronavirus.

Published
2021
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8. A Portable Smartphone-Based Laryngoscope System for High-Speed Vocal Cord Imaging of Patients With Throat Disorders: Instrument Validation Study

Author

Youngkyu Kim, Jeongmin Oh, Seung-Ho Choi, Ahra Jung, June-Goo Lee, Yoon Se Lee, and Jun Ki Kim

Subjects
Information technology, T58.5-58.64, Public aspects of medicine, RA1-1270
Abstract

BackgroundCurrently, high-speed digital imaging (HSDI), especially endoscopic HSDI, is routinely used for the diagnosis of vocal cord disorders. However, endoscopic HSDI devices are usually large and costly, which limits access to patients in underdeveloped countries and in regions with inadequate medical infrastructure. Modern smartphones have sufficient functionality to process the complex calculations that are required for processing high-resolution images and videos with a high frame rate. Recently, several attempts have been made to integrate medical endoscopes with smartphones to make them more accessible to people in underdeveloped countries. ObjectiveThis study aims to develop a smartphone adaptor for endoscopes, which enables smartphone-based vocal cord imaging, to demonstrate the feasibility of performing high-speed vocal cord imaging via the high-speed imaging functions of a high-performance smartphone camera, and to determine the acceptability of the smartphone-based high-speed vocal cord imaging system for clinical applications in developing countries. MethodsA customized smartphone adaptor optical relay was designed for clinical endoscopy using selective laser melting–based 3D printing. A standard laryngoscope was attached to the smartphone adaptor to acquire high-speed vocal cord endoscopic images. Only existing basic functions of the smartphone camera were used for HSDI of the vocal cords. Extracted still frames were observed for qualitative glottal volume and shape. For image processing, segmented glottal and vocal cord areas were calculated from whole HSDI frames to characterize the amplitude of the vibrations on each side of the glottis, including the frequency, edge length, glottal areas, base cord, and lateral phase differences over the acquisition time. The device was incorporated into a preclinical videokymography diagnosis routine to compare functionality. ResultsSmartphone-based HSDI with the smartphone-endoscope adaptor could achieve 940 frames per second and a resolution of 1280 by 720 frames, which corresponds to the detection of 3 to 8 frames per vocal cycle at double the spatial resolution of existing devices. The device was used to image the vocal cords of 4 volunteers: 1 healthy individual and 3 patients with vocal cord paralysis, chronic laryngitis, or vocal cord polyps. The resultant image stacks were sufficient for most diagnostic purposes. The cost of the device including the smartphone was lower than that of existing HSDI devices. The image processing and analytics demonstrated the successful calculation of relevant diagnostic variables from the acquired images. Patients with vocal pathologies were easily differentiable in the quantitative data. ConclusionsA smartphone-based HSDI endoscope system can function as a point-of-care clinical diagnostic device. The resulting analysis is of higher quality than that accessible by videostroboscopy and promises comparable quality and greater accessibility than HSDI. In particular, this system is suitable for use as an accessible diagnostic tool in underdeveloped areas with inadequate medical service infrastructure.

Published
2021
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9. Multi-Spectral Fluorescence Imaging of Colon Dysplasia In Vivo Using a Multi-Spectral Endoscopy System

Author

Sang Mun Bae, Dong-Jun Bae, Eun-Ju Do, Gyungseok Oh, Su Woong Yoo, Gil-Je Lee, Ji Soo Chae, Youngkuk Yun, Sungjee Kim, Ki Hean Kim, Euiheon Chung, Jun Ki Kim, Sung Wook Hwang, Sang Hyoung Park, Dong-Hoon Yang, Byong Duk Ye, Jeong-Sik Byeon, Suk-Kyun Yang, Jinmyoung Joo, Sang-Yeob Kim, and Seung-Jae Myung

Subjects
Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Abstract

BACKGROUND AND STUDY AIM: To develop a molecular imaging endoscopic system that eliminates tissue autofluorescence and distinguishes multiple fluorescent markers specifically on the cancerous lesions. METHODS: Newly developed multi-spectral fluorescence endoscope device has the potential to eliminate signal interference due to autofluorescence and multiplex fluorophores in fluorescent probes. The multiplexing capability of the multi-spectral endoscope device was demonstrated in the phantom studies and multi-spectral imaging with endoscopy and macroscopy was performed to analyze fluorescence signals after administration of fluorescent probe that targets cancer in the colon. Because of the limitations in the clinical application using rigid-type small animal endoscope, we developed a flexible channel insert-type fluorescence endoscope, which was validated on the colonoscopy of dummy and porcine model. RESULTS: We measured multiple fluorescent signals simultaneously, and the fluorescence spectra were unmixed to separate the fluorescent signals of each probe, in which multiple fluorescent probes clearly revealed spectral deconvolution at the specific targeting area in the mouse colon. The positive area of fluorescence signal for each probe over the whole polyp was segmented with analyzing software, and showed distinctive patterns and significantly distinguishable values: 0.46 ± 0.04, 0.39 ± 0.08 and 0.73 ± 0.12 for HMRG, CET-553 and TRA-675 probes, respectively. The spectral unmixing was finally demonstrated in the dummy and porcine model, corroborating the targeted multi-spectral fluorescence imaging of colon dysplasia. CONCLUSION: The multi-spectral endoscopy system may allow endoscopists to clearly identify cancerous lesion that has different patterns of various target expression using multiple fluorescent probes.

Published
2019
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10. Fluorescence-Based Microendoscopic Sensing System for Minimally Invasive In Vivo Bladder Cancer Diagnosis

Author

Sanghwa Lee, Jeongmin Oh, Minju Cho, and Jun Ki Kim

Subjects
5-aminolevulinic acid, bladder cancer, ferrochelatase staining, microendoscopy, minimally invasive diagnosis, protoporphyrin IX, Biotechnology, TP248.13-248.65
Abstract

Bladder cancer is commonly diagnosed by evaluating the tissue morphology through cystoscopy, and tumor resection is used as the primary treatment approach. However, these methods are limited by lesion site specificity and resection margin, and can thereby fail to detect cancer lesions at early stages. Nevertheless, rapid diagnosis without biopsy may be possible through fluorescence sensing. Herein, we describe a minimally invasive imaging system capable of sensing even small tumors through a 1.2 mm diameter flexible fiber bundle microprobe. We demonstrate that this new device can be used for the early diagnosis of bladder cancer in rats. Bladder cancer was induced in rats using the carcinogen N-butyl-N-(4-hydroxybutyl)nitrosamine (BBN), and a togglable filter capable of PpIX fluorescence sensing was installed in the microendoscopic system. Following 5-aminolevulinic acid administration, tissue in the early stages of bladder cancer was successfully identified with fluorescence detection and confirmed with hematoxylin/eosin and ferrochelatase staining. Although the time required for BBN to induce bladder cancer varied between 3 and 4 weeks among the rats, the microendoscopic system allowed the minimally invasive follow-up on cancer development.

Published
2022
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11. Compact Smartphone-Based Laser Speckle Contrast Imaging Endoscope Device for Point-of-Care Blood Flow Monitoring

Author

Youngkyu Kim, Woo June Choi, Jungmin Oh, and Jun Ki Kim

Subjects
endoscopy, point of care, smartphone, laser speckle contrast imaging, blood flow, Biotechnology, TP248.13-248.65
Abstract

Laser speckle contrast imaging (LSCI) is a powerful visualization tool for quantifying blood flow in tissues, providing simplicity of configuration, ease of use, and intuitive results. With recent advancements, smartphone and camera technologies are suitable for the development of smartphone-based LSCI applications for point-of-care (POC) diagnosis. A smartphone-based portable LSCI endoscope system was validated for POC diagnosis of vascular disorders. The endoscope consisted of compact LED and laser illumination, imaging optics, and a flexible fiberscope assembled in a 3D-printed hand-held cartridge for access to body cavities and organs. A smartphone’s rear camera was mounted thereto, enabling endoscopy, LSCI image acquisition, and processing. Blood flow imaging was calibrated in a perfused tissue phantom consisting of a microparticle solution pumped at known rates through tissue-mimicking gel and validated in a live rat model of BBN-induced bladder cancer. Raw LSCI images successfully visualized phantom flow: speckle flow index showed linearity with the pump flow rate. In the rat model, healthy and cancerous bladders were distinguishable in structure and vasculature. The smartphone-based low-cost portable mobile endoscope for monitoring blood flow and perfusion shows promise for preclinical applications and may be suitable for primary diagnosis at home or as a cost-effective POC testing assay.

Published
2022
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12. One-pot sequential synthesis of tetrasubstituted thiophenes via sulfur ylide-like intermediates

Author

Jun Ki Kim, Hwan Jung Lim, Kyung Chae Jeong, and Seong Jun Park

Subjects
5-(heterocyclic)thiophenes, one-pot sequential synthesis, sulfur ylide, tetrasubstituted thiophene, Science, Organic chemistry, QD241-441
Abstract

Herein, we describe a novel approach for the practical synthesis of tetrasubstituted thiophenes 8. The developed method was particularly used for the facile preparation of thienyl heterocycles 8. The mechanism for this reaction is based on the formation of a sulfur ylide-like intermediate. It was clearly suggested by (i) the intramolecular cyclization of ketene N,S-acetals 7 to the corresponding thiophenes 8, (ii) 1H NMR studies of Meldrum’s acid-substituted aminothioacetals 9, and (iii) substitution studies of the methoxy group on Meldrum’s acid containing N,S-acetals 9b. Notably, in terms of structural effects on the reactivity and stability of sulfur ylide-like intermediates, 2-pyridyl substituted compound 7a exhibited superior properties over those of others.

Published
2018
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13. Mobility of Nucleostemin in Live Cells Is Specifically Related to Transcription Inhibition by Actinomycin D and GTP-Binding Motif

Author

Chan-Gi Pack, Keehoon Jung, Bjorn Paulson, and Jun Ki Kim

Subjects
fluorescence correlation spectroscopy, diffusion coefficient, nucleostemin, nuclear diffusion, ActD, DRB, Biology (General), QH301-705.5, Chemistry, QD1-999
Abstract

In vertebrates, nucleostemin (NS) is an important marker of proliferation in several types of stem and cancer cells, and it can also interact with the tumor-suppressing transcription factor p53. In the present study, the intra-nuclear diffusional dynamics of native NS tagged with GFP and two GFP-tagged NS mutants with deleted guanosine triphosphate (GTP)-binding domains were analyzed by fluorescence correlation spectroscopy. Free and slow binding diffusion coefficients were evaluated, either under normal culture conditions or under treatment with specific cellular proliferation inhibitors actinomycin D (ActD), 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB), or trichostatin A (TSA). When treated with ActD, the fractional ratio of the slow diffusion was significantly decreased in the nucleoplasm. The decrease was proportional to ActD treatment duration. In contrast, DRB or TSA treatment did not affect NS diffusion. Interestingly, it was also found that the rate of diffusion of two NS mutants increased significantly even under normal conditions. These results suggest that the mobility of NS in the nucleoplasm is related to the initiation of DNA or RNA replication, and that the GTP-binding motif is also related to the large change of mobility.

Published
2021
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14. Poly(A)+ Sensing of Hybridization-Sensitive Fluorescent Oligonucleotide Probe Characterized by Fluorescence Correlation Methods

Author

Bjorn Paulson, Yeonhee Shin, Akimitsu Okamoto, Yeon-Mok Oh, Jun Ki Kim, and Chan-Gi Pack

Subjects
exciton-controlled hybridization-sensitive oligonucleotide probe, fluorescence correlation spectroscopy, dual-color fluorescence cross-correlation spectroscopy, poly(A) tail, mRNA, Biology (General), QH301-705.5, Chemistry, QD1-999
Abstract

Ribonucleic acid (RNA) plays an important role in many cellular processes. Thus, visualizing and quantifying the molecular dynamics of RNA directly in living cells is essential to uncovering their role in RNA metabolism. Among the wide variety of fluorescent probes available for RNA visualization, exciton-controlled hybridization-sensitive fluorescent oligonucleotide (ECHO) probes are useful because of their low fluorescence background. In this study, we apply fluorescence correlation methods to ECHO probes targeting the poly(A) tail of mRNA. In this way, we demonstrate not only the visualization but also the quantification of the interaction between the probe and the target, as well as of the change in the fluorescence brightness and the diffusion coefficient caused by the binding. In particular, the uptake of ECHO probes to detect mRNA is demonstrated in HeLa cells. These results are expected to provide new insights that help us better understand the metabolism of intracellular mRNA.

Published
2021
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15. Improved efficacy and in vivo cellular properties of human embryonic stem cell derivative in a preclinical model of bladder pain syndrome

Author

Aram Kim, Hwan Yeul Yu, Jisun Lim, Chae-Min Ryu, Yong Hwan Kim, Jinbeom Heo, Ju-Young Han, Seungun Lee, Yoon Sung Bae, Jae Young Kim, Dong-Jun Bae, Sang-Yeob Kim, Byeong-Joo Noh, Ki-Sung Hong, Ji-Yeon Han, Sang Wook Lee, Miho Song, Hyung-Min Chung, Jun Ki Kim, Dong-Myung Shin, and Myung-Soo Choo

Subjects
Medicine, Science
Abstract

Abstract Interstitial cystitis/bladder pain syndrome (IC/BPS) is an intractable disease characterized by severe pelvic pain and urinary frequency. Mesenchymal stem cell (MSC) therapy is a promising approach to treat incurable IC/BPS. Here, we show greater therapeutic efficacy of human embryonic stem cell (hESC)-derived multipotent stem cells (M-MSCs) than adult bone-marrow (BM)-derived counterparts for treating IC/BPS and also monitor long-term safety and in vivo properties of transplanted M-MSCs in living animals. Controlled hESC differentiation and isolation procedures resulted in pure M-MSCs displaying typical MSC behavior. In a hydrochloric-acid instillation-induced IC/BPS animal model, a single local injection of M-MSCs ameliorated bladder symptoms of IC/BPS with superior efficacy compared to BM-derived MSCs in ameliorating bladder voiding function and histological injuries including urothelium denudation, mast-cell infiltration, tissue fibrosis, apoptosis, and visceral hypersensitivity. Little adverse outcomes such as abnormal growth, tumorigenesis, or immune-mediated transplant rejection were observed over 12-months post-injection. Intravital confocal fluorescence imaging tracked the persistence of the transplanted cells over 6-months in living animals. The infused M-MSCs differentiated into multiple cell types and gradually integrated into vascular-like structures. The present study provides the first evidence for improved therapeutic efficacy, long-term safety, and in vivo distribution and cellular properties of hESC derivatives in preclinical models of IC/BPS.

Published
2017
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16. Variably Sized and Multi-Colored Silica-Nanoparticles Characterized by Fluorescence Correlation Methods for Cellular Dynamics

Author

Chan-Gi Pack, Bjorn Paulson, Yeonhee Shin, Min Kyo Jung, Jun Sung Kim, and Jun Ki Kim

Subjects
fluorescence correlation method, silica-based fluorescent nanoparticle, TEM, dual-colored nanoparticle, cobalt ferrite silica nanoparticle, hydrodynamic diameter, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85
Abstract

Controlling the uptake of nanoparticles into cells so as to balance therapeutic effects with toxicity is an essential unsolved problem in the development of nanomedicine technologies. From this point of view, it is useful to use standard nanoparticles to quantitatively evaluate the physical properties of the nanoparticles in solution and in cells, and to analyze the intracellular dynamic motion and distribution of these nanoparticles at a single-particle level. In this study, standard nanoparticles are developed based on a variant silica-based nanoparticle incorporating fluorescein isothiocyanate (FITC) or/and rhodamine B isothiocyanate (RITC) with a variety of accessible diameters and a matching fluorescent cobalt ferrite core-shell structure (Fe2O4/SiO2). The physical and optical properties of the nanoparticles in vitro are fully evaluated with the complementary methods of dynamic light scattering, electron microscopy, and two fluorescence correlation methods. In addition, cell uptake of dual-colored and core/shell nanoparticles via endocytosis in live HeLa cells is detected by fluorescence correlation spectroscopy and electron microscopy, indicating the suitability of the nanoparticles as standards for further studies of intracellular dynamics with multi-modal methods.

Published
2020
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17. SERS Effect on Spin-Coated Seeding of Tilted Au-ZnO Nanorods for Low-Cost Diagnosis

Author

Miyeon Jue, Chan-Gi Pack, Seakhee Oh, Bjorn Paulson, Kwanhee Lee, and Jun Ki Kim

Subjects
ZnO nanorods, Raman spectroscopy, finite element method, optical diagnosis, label-free diagnosis, surface-enhanced Raman spectroscopy, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85
Abstract

Uniformly parallel Au-coated ZnO nanorods have previously been shown to amplify local Raman signals, providing increased sensitivity to disease markers in the detection of inflammation and cancer. However, practical and cost-effective fabrication methods of substrates for surface-enhanced Raman spectroscopy (SERS) fail to produce highly uniform surfaces. Here, the feasibility of Raman enhancement on less-uniform substrates is assessed. ZnO nanorod structures were fabricated by hydrothermal synthesis, starting from spin-coated seed substrates. Following analysis, the nanostructures were coated with Au to create stochastically variant substrates. The non-uniformity of the fabricated Au-coated ZnO nanorod structures is confirmed morphologically by FE-SEM and structurally by X-ray diffraction, and characterized by the angular distributions of the nanorods. Monte Carlo finite element method simulations matching the measured angular distributions and separations predicted only moderate increases in the overall Raman enhancement with increasing uniformity. Highly variant substrates exhibited approximately 76% of the Raman enhancement of more uniform substrates in simulations and experiments. The findings suggest that, although highly inhomogeneous Au-coated ZnO nanorod substrates may not attain the same Raman enhancement as more uniform substrates, the relaxation of fabrication tolerances may be economically viable.

Published
2020
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18. Mean-Subtraction Method for De-Shadowing of Tail Artifacts in Cerebral OCTA Images: A Proof of Concept

Author

Woo June Choi, Bjorn Paulson, Sungwook Yu, Ruikang K. Wang, and Jun Ki Kim

Subjects
optical coherence tomography, OCT angiography, tail artifact, mean-subtraction, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85
Abstract

When imaging brain vasculature with optical coherence tomography angiography (OCTA), volumetric analysis of cortical vascular networks in OCTA datasets is frequently challenging due to the presence of artifacts, which appear as multiple-scattering tails beneath superficial large vessels in OCTA images. These tails shadow underlying small vessels, making the assessment of vascular morphology in the deep cortex difficult. In this work, we introduce an image processing technique based on mean subtraction of the depth profile that can effectively reduce these tails to better reveal small hidden vessels compared to the current tail removal approach. With the improved vascular image quality, we demonstrate that this simple method can provide better visualization of three-dimensional vascular network topology for quantitative cerebrovascular studies.

Published
2020
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19. The Therapeutic Effect of Human Embryonic Stem Cell-Derived Multipotent Mesenchymal Stem Cells on Chemical-Induced Cystitis in Rats

Author

Sang Wook Lee, Chae-Min Ryu, Jung-Hyun Shin, Daeheon Choi, Aram Kim, Hwan Yeul Yu, Ju-Young Han, Hye-Yeon Lee, Jisun Lim, Yong Hwan Kim, Jinbeom Heo, Seungun Lee, Hyein Ju, Sujin Kim, Ki-Sung Hong, Ji-Yeon Han, Miho Song, Hyung-Min Chung, Jun Ki Kim, Dong-Myung Shin, and Myung-Soo Choo

Subjects
Cystitis, Fibrosis, Ketamine, Multipotent stem cells, Pelvic pain, Diseases of the genitourinary system. Urology, RC870-923
Abstract

Purpose To evaluate the therapeutic effect of human embryonic stem cell (hESC)-derived multipotent mesenchymal stem cells (M-MSCs) on ketamine-induced cystitis (KC) in rats. Methods To induce KC, 10-week-old female rats were injected with 25-mg/kg ketamine hydrochloride twice weekly for 12 weeks. In the sham group, phosphate buffered saline (PBS) was injected instead of ketamine. One week after the final injection of ketamine, the indicated doses (0.25, 0.5, and 1×106 cells) of M-MSCs (KC+M-MSC group) or PBS vehicle (KC group) were directly injected into the bladder wall. One week after M-MSC injection, the therapeutic outcomes were evaluated via cystometry, histological analyses, and measurement of gene expression. Next, we compared the efficacy of M-MSCs at a low dose (1×105 cells) to that of an identical dose of adult bone marrow (BM)-derived MSCs. Results Rats in the KC group exhibited increased voiding frequency and reduced bladder capacity compared to rats of the sham group. However, these parameters recovered after transplantation of M-MSCs at all doses tested. KC bladders exhibited markedly increased mast cell infiltration, apoptosis, and tissue fibrosis. Administration of M-MSCs significantly reversed these characteristic histological alterations. Gene expression analyses indicated that several genes associated with tissue fibrosis were markedly upregulated in KC bladders. However the expression of these genes was significantly suppressed by the administration of M-MSCs. Importantly, M-MSCs ameliorated bladder deterioration in KC rats after injection of a low dose (1×105) of cells, at which point BM-derived MSCs did not substantially improve bladder function. Conclusions This study demonstrates for the first time the therapeutic efficacy of hESC-derived M-MSCs on KC in rats. M-MSCs restored bladder function more effectively than did BM-derived MSCs, protecting against abnormal changes including mast cell infiltration, apoptosis and fibrotic damage.

Published
2018
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20. Mitotic Chromosomes in Live Cells Characterized Using High-Speed and Label-Free Optical Diffraction Tomography

Author

Tae-Keun Kim, Byong-Wook Lee, Fumihiko Fujii, Kee-Hang Lee, Sanghwa Lee, YongKeun Park, Jun Ki Kim, Sang-Wook Lee, and Chan-Gi Pack

Subjects
optical diffraction tomography, fluorescence correlation spectroscopy, mitosis, chromosome, refractive index, cellular viscosity, diffusion coefficient, osmotic stress, Cytology, QH573-671
Abstract

The cell nucleus is a three-dimensional, dynamic organelle organized into subnuclear compartments such as chromatin and nucleoli. The structure and function of these compartments are maintained by diffusion and interactions between related factors as well as by dynamic and structural changes. Recent studies using fluorescent microscopic techniques suggest that protein factors can access and are freely mobile in heterochromatin and in mitotic chromosomes, despite their densely packed structure. However, the physicochemical properties of the chromosome during cell division are not fully understood. In the present study, characteristic properties such as the refractive index (RI), volume of the mitotic chromosomes, and diffusion coefficient (D) of fluorescent probes inside the chromosome were quantified using an approach combining label-free optical diffraction tomography with complementary confocal laser-scanning microscopy and fluorescence correlation spectroscopy. Variations in these parameters correlated with osmotic conditions, suggesting that changes in RI are consistent with those of the diffusion coefficient for mitotic chromosomes and cytosol. Serial RI tomography images of chromosomes in live cells during mitosis were compared with three-dimensional confocal micrographs to demonstrate that compaction and decompaction of chromosomes induced by osmotic change were characterized by linked changes in chromosome RI, volume, and the mobilities of fluorescent proteins.

Published
2019
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21. Physicochemical Properties of Nucleoli in Live Cells Analyzed by Label-Free Optical Diffraction Tomography

Author

Tae-Keun Kim, Byong-Wook Lee, Fumihiko Fujii, Jun Ki Kim, and Chan-Gi Pack

Subjects
optical diffraction tomography, fluorescence correlation spectroscopy, nucleolus, refractive index, volume, diffusion coefficient, liquid-liquid phase separation, Cytology, QH573-671
Abstract

The cell nucleus is three-dimensionally and dynamically organized by nuclear components with high molecular density, such as chromatin and nuclear bodies. The structure and functions of these components are represented by the diffusion and interaction of related factors. Recent studies suggest that the nucleolus can be assessed using various protein probes, as the probes are highly mobile in this organelle, although it is known that they have a densely packed structure. However, physicochemical properties of the nucleolus itself, such as molecular density and volume when cellular conditions are changed, are not yet fully understood. In this study, physical parameters such as the refractive index (RI) and volume of the nucleoli in addition to the diffusion coefficient (D) of fluorescent probe protein inside the nucleolus are quantified and compared by combining label-free optical diffraction tomography (ODT) with confocal laser scanning microscopy (CLSM)-based fluorescence correlation spectroscopy (FCS). 3D evaluation of RI values and corresponding RI images of nucleoli in live HeLa cells successfully demonstrated varying various physiological conditions. Our complimentary method suggests that physical property of the nucleolus in live cell is sensitive to ATP depletion and transcriptional inhibition, while it is insensitive to hyper osmotic pressure when compared with the cytoplasm and nucleoplasm. The result demonstrates that the nucleolus has unique physicochemical properties when compared with other cellular components.

Published
2019
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22. Optimization of ZnO Nanorod-Based Surface Enhanced Raman Scattering Substrates for Bio-Applications

Author

Miyeon Jue, Sanghwa Lee, Bjorn Paulson, Jung-Man Namgoong, Hwan Yeul Yu, Gwanho Kim, Sangmin Jeon, Dong-Myung Shin, Myung-Soo Choo, Jinmyoung Joo, Youngjin Moon, Chan-Gi Pack, and Jun Ki Kim

Subjects
gold coated thickness, ZnO nanorods, surface enhancement Raman spectroscopy (SERS), Au coated SERS, bladder disease detection, Chemistry, QD1-999
Abstract

Nanorods based on ZnO for surface enhanced Raman spectroscopy are promising for the non-invasive and rapid detection of biomarkers and diagnosis of disease. However, optimization of nanorod and coating parameters is essential to their practical application. With the goal of establishing a baseline for early detection in biological applications, gold-coated ZnO nanorods were grown and coated to form porous structures. Prior to gold deposition, the grown nanorods were 30–50 nm in diameter and 500–600 nm in length. Gold coatings were grown on the nanorod structure to a series of thicknesses between 100 and 300 nm. A gold coating of 200 nm was found to optimize the Rhodamine B model analyte signal, while performance for rat urine depended on the biomarkers to be detected. These results establish design guidelines for future use of Au-ZnO nanorods in the study and early diagnosis of inflammatory diseases.

Published
2019
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23. Diagnosis in a Preclinical Model of Bladder Pain Syndrome Using a Au/ZnO Nanorod-based SERS Substrate

Author

Sanghwa Lee, Jung-Man Namgoong, Hwan Yeul Yu, Miyeon Jue, Gwanho Kim, Sangmin Jeon, Dong-Myung Shin, Myung-Soo Choo, Jinmyoung Joo, Chan-Gi Pack, and Jun Ki Kim

Subjects
interstitial cystitis/bladder pain syndrome (IC/BPS), ZnO nanorods, surface enhancement Raman spectroscopy (SERS), principal component analysis (PCA), Chemistry, QD1-999
Abstract

To evaluate the feasibility of ZnO nanorod-based surface enhanced Raman scattering (SERS) diagnostics for disease models, particularly for interstitial cystitis/bladder pain syndrome (IC/BPS), ZnO-based SERS sensing chips were developed and applied to an animal disease model. ZnO nanorods were grown to form nano-sized porous structures and coated with gold to facilitate size-selective biomarker detection. Raman spectra were acquired on a surface enhanced Raman substrate from the urine in a rat model of IC/BPS and analyzed using a statistical analysis method called principal component analysis (PCA). The nanorods grown after the ZnO seed deposition were 30 to 50 nm in diameter and 500 to 600 nm in length. A volume of gold corresponding to a thin film thickness of 100 nm was deposited on the grown nanorod structure. Raman spectroscopic signals were measured in the scattered region for nanometer biomarker detection to indicate IC/BPS. The Raman peaks for the control group and IC/BPS group are observed at 641, 683, 723, 873, 1002, 1030, and 1355 cm−1, which corresponded to various bonding types and compounds. The PCA results are plotted in 2D and 3D. The Raman signals and statistical analyses obtained from the nano-sized biomarkers of intractable inflammatory diseases demonstrate the possibility of an early diagnosis.

Published
2019
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24. Minimizing Motion Artifacts in Intravital Microscopy Using the Sedative Effect of Dexmedetomidine

Author

Youngkyu Kim, Minju Cho, Bjorn Paulson, Sung-Hoon Kim, and Jun Ki Kim

Subjects
Instrumentation
Abstract

Among intravital imaging instruments, the intravital two-photon fluorescence excitation microscope has the advantage of enabling real-time 3D fluorescence imaging deep into cells and tissues, with reduced photobleaching and photodamage compared with conventional intravital confocal microscopes. However, excessive motion of organs due to involuntary movement such as breathing may result in out-of-focus images and severe fluorescence intensity fluctuations, which hinder meaningful imaging and analysis. The clinically approved alpha-2 adrenergic receptor agonist dexmedetomidine was administered to mice during two-photon fluorescence intravital imaging to alleviate this problem. As dexmedetomidine blocks the release of the neurotransmitter norepinephrine, pain is suppressed, blood pressure is reduced, and a sedation effect is observed. By tracking the quality of focus and stability of detected fluorescence in two-photon fluorescence images of fluorescein isothiocyanate-sensitized liver vasculature in vivo, we demonstrated that intravascular dexmedetomidine can reduce fluorescence fluctuations caused by respiration on a timescale of minutes in mice, improving image quality and resolution. The results indicate that short-term dexmedetomidine treatment is suitable for reducing involuntary motion in preclinical intravital imaging studies. This method may be applicable to other animal models.

Published
2022

25. Supplemental figures 1-3 / Tables 1 and 2 from Urokinase Exerts Antimetastatic Effects by Dissociating Clusters of Circulating Tumor Cells

Author

Seok Hyun Yun, Kwon-Ha Yoon, Pilhan Kim, Yun Jung Yang, Jun Ki Kim, and Jin Woo Choi

Abstract

Supplementary Figure 1. Specific infection of Telomescan Supplementary Figure 2. Validity of the number of CTCs in the peritumoral regions Supplementary Figure 3. Comparison of the tumorigenic and metastatic properties of GFP- and RFP-expressing 4T1 cells Supplementary Table 1. Isolated nodules categorized into 3 groups Supplementary Table 2. Mice injected with a mixture of GFP- and RFP-positive

Published
2023

28. Data from Urokinase Exerts Antimetastatic Effects by Dissociating Clusters of Circulating Tumor Cells

Author

Seok Hyun Yun, Kwon-Ha Yoon, Pilhan Kim, Yun Jung Yang, Jun Ki Kim, and Jin Woo Choi

Abstract

Clusters of circulating tumor cells (CTC) exhibit more robust metastatic properties than single CTC. Thus, understanding the distinct behaviors of CTC clusters and how CTC clustering is regulated may offer new insights into how to limit metastasis. In this study, we utilized an in vivo confocal system to observe the clustering behavior of CTC in real time, finding that the number of clusters increased proportionally with the growth of the primary tumor. Our experiments also indicated that the flow rate of the CTC clusters in blood vessels was relatively slower than single CTC due to increased vessel wall adhesion. Depending on disease stage, 5% to 10% of total CTC in circulation were in clusters, with this proportion increasing to >24% within lung metastases examined. Notably, in the 4T1 mouse model of breast cancer metastasis, we found that injecting host animals with urokinase-type plasminogen activator, a clinical thrombolytic agent, was effective at preventing the assembly of CTC clusters and prolonging overall host survival by approximately 20% relative to control animals. Our results suggest a tractable approach to limit metastasis by suppressing the formation or stability of CTC clusters circulating in the blood of cancer patients. Cancer Res; 75(21); 4474–82. ©2015 AACR.

Published
2023

35. Image Correlation-Based Method to Assess Ciliary Beat Frequency in Human Airway Organoids

Author

Chang Hoon Lee, Jun Ki Kim, Jung Ki Yoon, Jae Joon Yim, Woo June Choi, Bjorn Paulson, and Jong Il Kim

Subjects
Digital image correlation, Radiological and Ultrasound Technology, Computer science, Respiratory System, Video microscopy, Human airway, Signal, Computer Science Applications, Organoids, Region of interest, Organoid, Motile cilium, Humans, Cilia, Electrical and Electronic Engineering, Ciliary beating, Software, Biomedical engineering
Abstract

Ciliary movements within the human airway are essential for maintaining a clean lung environment. Motile cilia have a characteristic ciliary beat frequency (CBF). However, CBF measurement with current video microscopic techniques can be error-prone due to the use of the single-point Fourier transformation, which is often biased for ciliary measurements. Herein, we describe a new video microscopy technique that harnesses a metric of motion-contrast imaging and image correlation for CBF analysis. It can provide objective and selective CBF measurements for individual motile cilia and generate CBF maps for the imaged area. The measurement performance of our methodology was validated with in vitro human airway organoid models that simulated an actual human airway epithelium. The CBF determined for the region of interest (ROI) was equal to that obtained with manual counting. The signal redundancy problem of conventional methods was not observed. Moreover, the obtained CBF measurements were robust to optical focal shifts, and exhibited spatial heterogeneity and temperature dependence. This technique can be used to evaluate ciliary movement in respiratory tracts and determine whether it is non-synchronous or aperiodic in patients. Therefore, our observations suggest that the proposed method can be clinically adapted as a screening tool to diagnose ciliopathies.

Published
2022

37. Prediction of Curing Time/Shear Strength of Non-Conductive Adhesives Using a Neural Network Model

Author

Kyung-Eun Min, Jae-Won Jang, Jun-Ki Kim, Sung Yi, and Cheolhee Kim

Subjects
Fluid Flow and Transfer Processes, neural network, prediction, optimization, non-conductive adhesives, formulation, Process Chemistry and Technology, General Engineering, General Materials Science, Instrumentation, Computer Science Applications
Abstract

Electronic packaging has been developed with high resolution and fine interconnection pitches. Non-conductive adhesives (NCAs) have been growing with the increase of I/O pad count and density, along with fine pad bond pitch interconnections. Prediction and optimization of NCA characteristics are inherently complicated due to various and extensive materials composing NCAs. In this study, a framework predicting the curing time and shear strength of an NCA is established by a neural network model. NCA formulations with 4 resins, 3 hardeners, 8 catalysts, and a coupling agent were selected from in-house experiments, and an artificial neural network (ANN) with one dense layer with 3 nodes was trained using 65 data points. Model accuracy was improved by 28.9–35.2% compared with the reference, and the trained model was also verified through third-party reference data. Prediction of NCA properties and optimization of NCA formulations for mass production were demonstrated by using the trained ANN model. This paper provides a framework for ANN-based NCA design and confirmed the feasibility of ANN modeling, even with a small dataset.

Published
2022
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40. Synthesis and Electrochemical Performance of Microporous Hollow Carbon from Milkweed Pappus as Cathode Material of Lithium-Sulfur Batteries

Author

Jun-Ki Kim, Yunju Choi, Euh Duck Jeong, Sei-Jin Lee, Hyun Gyu Kim, Jae Min Chung, Jeom-Soo Kim, Sun-Young Lee, and Jong-Seong Bae

Subjects
General Chemical Engineering, General Materials Science, milkweed pappus, microporous hollow carbon, lithium–sulfur batteries
Abstract

Microtube-like porous carbon (MPC) and tube-like porous carbon–sulfur (MPC-S) composites were synthesized by carbonizing milkweed pappus with sulfur, and they were used as cathodes for lithium–sulfur batteries. The morphology and uniformity of these materials were characterized using X-ray powder diffraction, Raman spectroscopy, scanning electron microscopy, transmission electron microscopy with an energy-dispersive X-ray analyzer, thermogravimetric analysis, and X-ray photoelectron spectrometry. The electrochemical performance of the MPC-S cathodes was measured using the charge/discharge cycling performance, C rate, and AC impedance. The composite cathodes with 93.8 wt.% sulfur exhibited a stable specific capacity of 743 mAh g−1 after 200 cycles at a 0.5 C.

Published
2022

42. Biomass-garlic-peel-derived porous carbon framework as a sulfur host for lithium-sulfur batteries

Author

Sun-Young Lee, Euh Duck Jeong, Yunju Choi, Jun-Ki Kim, Jong Seong Bae, and Sei-Jin Lee

Subjects
Chemistry, General Chemical Engineering, chemistry.chemical_element, 02 engineering and technology, Conductivity, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, Sulfur, 0104 chemical sciences, chemistry.chemical_compound, Chemical engineering, Specific surface area, Lithium, 0210 nano-technology, Mesoporous material, Carbon, Polysulfide
Abstract

Porous carbon materials were synthesized using biomass waste garlic-peels by two methods, precarbonization (GPC) and hydrothermal treatment (GPC/HT), in a pretreatment procedure. Brunauer–Emmett–Teller tests indicated that the surface area and total pore volume (at P/Po) of the GPC/HT are 4220 m2 g−1 and 2.02 cm3 g−1, higher than those of the GPC (2290 m2 g−1 and 1.02 cm3 g−1). The GPC/HT-S with a sulfur content of 87.6 wt.% exhibited a higher initial specific capacity (1087 mA h g−1 at 0.1 C) and better cycle retention (72.2% after 400 cycles at 0.5 C) than those of the GPC-S (65.3%). Optimized sulfur content was investigated to overcome the problems for shuttle phenomenon and low conductivity. Among the investigated samples (sulfur content of 65.3, 87.6, and 95.1 wt.%), the GPC/HT-S with 87.6 wt.% exhibited the best electrochemical performance. The enhanced electrochemical performance is attributed to the improved specific surface area of the GPC/HT and proper sulfur loading content, which effectively facilitated the intimate contact between sulfur and conductive carbon matrix and physically confined lithium polysulfide intermediates. The result in this work is important for using low cost and mesoporous bio-waste carbon as carbon framework for sulfur encapsulating in Li-S batteries.

Published
2021

43. Automated counting of cerebral penetrating vessels using optical coherence tomography images of a mouse brain in vivo

Author

Woo June Choi, Yuandong Li, Ruikang K. Wang, and Jun Ki Kim

Subjects
Stroke, Disease Models, Animal, Mice, Animals, Brain, Retinal Vessels, General Medicine, Tomography, Optical Coherence, Capillaries
Abstract

Penetrating blood vessels emanating from cortical surface vasculature and lying deep in the cortex are essential vascular conduits for the shuttling of blood from superficial pial vessels to the capillary beds in parenchyma for the nourishment of neuronal brain tissues. Locating and counting the penetrating vessels is beneficial for the quantification of a course of ischemia in blood occlusive events such as stroke. This paper seeks to demonstrate and validate a method for automated penetrating vessel counting that uses optical coherence tomography (OCT).This paper proposes an OCT method that effectively identifies and grades the cortical penetrating vessels in perfusion. The key to the proposed method is the harnessing of vascular features found in the penetrating vessels, which are distinctive from those of other vessels. In particular, with an increase in the light attenuation and flow turbulence, the contrast in the mean projection of the OCT datacube decreases, whereas that in the maximum projection of the Doppler frequency variance datacube increases. By multiplying the inversion of the former with the latter, its binary thresholding is sufficient to highlight the penetrating vessels and allows for their counting over the projection image.A computational method that leverages the decrease in mean OCT projection intensity and the increase in Doppler frequency variance at the penetrating vessel is developed. It successfully identifies and counts penetrating vessels with a high accuracy of over 87%. The penetrating vessel density is observed to be significantly reduced in the mouse model of focal ischemic stroke.The OCT analysis is effective for counting penetrating blood vessels in mice brains and may be applied to the rapid diagnosis and treatment of stroke in stroke models of small animals.

Published
2022

44. Compact Smartphone-Based Laser Speckle Contrast Imaging Endoscope Device for Point-of-Care Blood Flow Monitoring: Instrument Validation Study (Preprint)

Author

Youngkyu Kim, Woo June Choi, Jungmin Oh, and Jun Ki Kim

Abstract

BACKGROUND Laser speckle contrast imaging (LSCI) is widely accepted as a powerful visualization tool for quantifying blood flow in tissues. The benefits of this technology include simplicity of configuration, ease of use, and intuitive results. With significant advancements in smartphone and camera technologies, recent attempts have been made to develop a smartphone-based LSCI application that can be used as a Point-Of-Care (POC) device to examine vascular disorders in situ. OBJECTIVE A novel smartphone-based portable LSCI endoscope device was developed and validated to perform endoscopic POC testing for the diagnosis of vascular disorders in vivo. METHODS Device implementation: The flexible endoscope consisted of compact light sources (white LED and green laser), imaging optics, and a flexible fiberscope assembled in a 3D printed hand-held cartridge for access and illumination of the cavity organs in the body. The rear camera of the smartphone was mounted on an endoscope for endoscopy and LSCI image acquisition and processing. Tissue-mimicking phantom flow experiment: A 2.5% microparticle mixture was injected into a light-transparent silicon tube with inner-diameter 1.0 mm, submerged in a tissue-mimicking gel to mimic blood flow in tissue. It was then pumped at a constant flow rate (0.023–0.094 ml/min) using a syringe pump. The perfused phantom was imaged using the prototype endoscopic device. In vivo small animal experiment: Healthy Sprague–Dawley rats (n=2) and 0.05% BBN-induced bladder cancer rat models (n=3) were intravenously anesthetized. Their bladders were emptied by rinsing the inner sidewalls with a PBS solution. The probe tip of the endoscope device was used to gain access to the bladder sidewall via the urinary tract for examination. RESULTS Blood flow phantom experiment: Tissue phantom blood flow was visualized using raw laser speckle images of the developed endoscope device. The flow was quantified as a speckle flow index (SFI), which showed linearity with the preset pump flow rate. In vivo small animal experiment: The bladders of healthy and cancerous rats were distinguishable in structure and vasculature. CONCLUSIONS The low-cost portable mobile endoscope device for monitoring blood flow and perfusion changes using a smartphone can be beneficial as a primary diagnostic tool for patients at home and as a cost-effective POC testing assay.

Published
2022

46. The Impact of Legislative Budgeting Power on Fiscal Soundness

Author

강경표 ( Kyung-pyo Kang ) and 김준기 ( Jun-ki Kim )

Subjects
General Earth and Planetary Sciences, General Environmental Science
Abstract

본 논문은 재정민주주의가 의회에 재정과 관련한 권한을 강화하는 것으로 인식되는 상황에서 과연 재정민주주의가 재정건전성 측면에서 어떠한 결과를 초래하는지 살펴보기 위한 것이다. 이를 위해 광역 지방의회의 예산과정에서 사후적(ex-post)으로 표출된 예산내용 및 결과에 초점을 맞춰 강도를 측정하고, 계층분석적 의사결정기법(AHP)에 근거한 가중치로 합산하여 지수화하였다. 이와 함께 분석의 정확성을 위해 동태 선형 패널 모형에 기초하여 고정효과 분석과 함께 시스템 일반화적률법(System GMM)을 이용하여 의회예산권한지수가 재정건전성에 미치는 영향을 추정하였다. 회귀분석 결과, 의회예산권한지수가 높아질수록 통합재정수지비율과 채무증가율이 악화되는 등 의회예산권한의 강화는 재정건전성에 부정적인 영향을 미치는 것으로 나타났다. 이는 의회의 예산권한 강화가 예산과정에서의 조정 메커니즘을 약화시킴으로써 재정건전성을 악화시킬 가능성이 있음을 나타내는 바, 재정준칙, 재정분권, 투명성 제고 등을 통해 조정 메커니즘을 강화시킬 필요가 있음을 시사한다.

Published
2020

47. Mobility of Nucleostemin in Live Cells Is Specifically Related to Transcription Inhibition by Actinomycin D and GTP-Binding Motif

Author

Jun Ki Kim, Keehoon Jung, Chan-Gi Pack, and Bjorn Paulson

Subjects
0301 basic medicine, Transcription, Genetic, GTP', QH301-705.5, Mutant, fluorescence correlation spectroscopy, Guanosine triphosphate, Article, Catalysis, Inorganic Chemistry, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, GTP-Binding Proteins, Transcription (biology), medicine, Humans, Physical and Theoretical Chemistry, diffusion coefficient, Biology (General), TSA, Molecular Biology, Transcription factor, QD1-999, Spectroscopy, Nucleic Acid Synthesis Inhibitors, Cell Nucleus, Nucleoplasm, Organic Chemistry, Nuclear Proteins, General Medicine, ActD, Computer Science Applications, Cell biology, DRB, Chemistry, 030104 developmental biology, Trichostatin A, nuclear diffusion, chemistry, 030220 oncology & carcinogenesis, Dactinomycin, Guanosine Triphosphate, nucleostemin, DNA, HeLa Cells, medicine.drug
Abstract

In vertebrates, nucleostemin (NS) is an important marker of proliferation in several types of stem and cancer cells, and it can also interact with the tumor-suppressing transcription factor p53. In the present study, the intra-nuclear diffusional dynamics of native NS tagged with GFP and two GFP-tagged NS mutants with deleted guanosine triphosphate (GTP)-binding domains were analyzed by fluorescence correlation spectroscopy. Free and slow binding diffusion coefficients were evaluated, either under normal culture conditions or under treatment with specific cellular proliferation inhibitors actinomycin D (ActD), 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB), or trichostatin A (TSA). When treated with ActD, the fractional ratio of the slow diffusion was significantly decreased in the nucleoplasm. The decrease was proportional to ActD treatment duration. In contrast, DRB or TSA treatment did not affect NS diffusion. Interestingly, it was also found that the rate of diffusion of two NS mutants increased significantly even under normal conditions. These results suggest that the mobility of NS in the nucleoplasm is related to the initiation of DNA or RNA replication, and that the GTP-binding motif is also related to the large change of mobility.

Published
2021

48. Multimodal Imaging of Laser Speckle Contrast Imaging Combined With Mosaic Filter-Based Hyperspectral Imaging for Precise Surgical Guidance

Author

Youngkyu Kim, Jun Ki Kim, Jaepyeong Cha, Sanghwa Lee, and Jung-Man Namgoong

Subjects
business.industry, Optical Imaging, Biomedical Engineering, Hemodynamics, Hyperspectral imaging, Perfusion scanning, Blood flow, Hyperspectral Imaging, Multimodal Imaging, Rats, Transplantation, Speckle pattern, Laser Speckle Contrast Imaging, Oxygen Saturation, Medicine, Animals, business, Perfusion, Oxygen saturation (medicine), Biomedical engineering
Abstract

Objective: To enable a real-time surgical guidance system that simultaneously monitors blood vessel perfusion, oxygen saturation, thrombosis, and tissue recovery by combining multiple optical imaging techniques into a single system: visible imaging, mosaic filter-based snapshot hyperspectral imaging (HSI), and laser speckle contrast imaging (LSCI). Methods: The multimodal optical imaging system was demonstrated by clamping blood vessels in the small intestines of rats to create areas of restricted blood flow. Subsequent tissue damage and regeneration were monitored during procedures. Using LSCI, vessel perfusion was measured, revealing the biological activity and survival of organ tissues. Blood oxygen saturation was monitored using HSI in the near-infrared region. Principal component analysis was used over the spectral dimension to identify an HSI wavelength combination optimized for hemodynamic biomarker visualization. HSI and LSCI were complimentary, identifying thrombus generation and tissue recovery, which was not possible in either modality alone. Results and Conclusion: By analyzing multimodal tissue information from visible imaging, LSCI perfusion imaging, and HSI, a recovery prognosis could be determined based on the blood supply to the organ. The unique combination of the complementary imaging techniques into a single surgical microscope holds promise for improving the real-time determination of blood supply and tissue prognosis during surgery. Significance: Precise real-time monitoring for vascular anomalies promises to reduce the risk of organ damage in precise surgical operations such as tissue resection and transplantation. In addition, the convergence of label-free imaging technologies removes delays associated with the injection and diffusion of vascular monitoring dyes.

Published
2021

49. A Wi-Fi–Based Mask-Type Laryngoscope for Telediagnosis During the COVID-19 Pandemic: Instrument Validation Study (Preprint)

Author

Youngjin Moon, Jaeho Hyun, Jeongmin Oh, Kwanhee Lee, Yoon Se Lee, and Jun Ki Kim

Abstract

BACKGROUND Owing to the COVID-19 pandemic, social distancing has become mandatory. Wireless endoscopy in contactless examinations promises to protect health care workers and reduce viral spread. OBJECTIVE This study aimed to introduce a contactless endoscopic diagnosis system using a wireless endoscope resembling a mask. METHODS The Wi-Fi–based contactless mask endoscopy system comprises a disposable endoscope and a controller. First, the effective force applied by the tip during insertion was evaluated in a simple transoral model consisting of a force sensor on a simulated oropharynx wall. Second, the delay in video streaming was evaluated by comparing the frame rate and delays between a movement and its image over direct and Wi-Fi connections. Third, the system was applied to a detailed laryngopharyngeal tract phantom. RESULTS The smartphone-controlled wireless endoscopy system was successfully evaluated. The mean, maximum, and minimum collision forces against the wall of the transoral model were 296 mN (30 gf), 363 mN (37 gf), and 235 mN (24 gf), respectively. The delay resulting from the wireless connection was 0.72 seconds. Using the phantom, an inexperienced user took around 1 minute to orient the endoscope to a desired area via the app. CONCLUSIONS Device articulation does not pose a significant risk of laryngopharyngeal wall penetration, and latency does not significantly impede its use. Contactless wireless video streaming was successful within the access point range regardless of the presence of walls. The mask endoscope can be controlled and articulated wirelessly, minimizing contact between patients and device operators. By minimizing contact, the device can protect health care workers from infectious viruses like the coronavirus. CLINICALTRIAL

Published
2021

50. A Portable Smartphone-Based Laryngoscope System for High-Speed Vocal Cord Imaging of Patients With Throat Disorders: Instrument Validation Study

Author

June-Goo Lee, Ahra Jung, Seung-Ho Choi, Jeongmin Oh, Yoon Se Lee, Jun Ki Kim, and Youngkyu Kim

Subjects
Glottis, Computer science, high-speed imaging, otorhinolaryngology, Health Informatics, Image processing, Vocal Cords, Information technology, Videokymography, Laryngoscopes, Vocal Cord Polyp, smartphone, 01 natural sciences, head and neck, 03 medical and health sciences, 0302 clinical medicine, throat, medicine, Humans, Computer vision, Vocal cord paralysis, 030223 otorhinolaryngology, Image resolution, Original Paper, mobile phone, business.industry, 010401 analytical chemistry, Digital imaging, Kymography, endoscope, low-cost device, Frame rate, medicine.disease, T58.5-58.64, 0104 chemical sciences, medicine.anatomical_structure, mHealth, Pharynx, Artificial intelligence, Public aspects of medicine, RA1-1270, business, vocal cord
Abstract

Background Currently, high-speed digital imaging (HSDI), especially endoscopic HSDI, is routinely used for the diagnosis of vocal cord disorders. However, endoscopic HSDI devices are usually large and costly, which limits access to patients in underdeveloped countries and in regions with inadequate medical infrastructure. Modern smartphones have sufficient functionality to process the complex calculations that are required for processing high-resolution images and videos with a high frame rate. Recently, several attempts have been made to integrate medical endoscopes with smartphones to make them more accessible to people in underdeveloped countries. Objective This study aims to develop a smartphone adaptor for endoscopes, which enables smartphone-based vocal cord imaging, to demonstrate the feasibility of performing high-speed vocal cord imaging via the high-speed imaging functions of a high-performance smartphone camera, and to determine the acceptability of the smartphone-based high-speed vocal cord imaging system for clinical applications in developing countries. Methods A customized smartphone adaptor optical relay was designed for clinical endoscopy using selective laser melting–based 3D printing. A standard laryngoscope was attached to the smartphone adaptor to acquire high-speed vocal cord endoscopic images. Only existing basic functions of the smartphone camera were used for HSDI of the vocal cords. Extracted still frames were observed for qualitative glottal volume and shape. For image processing, segmented glottal and vocal cord areas were calculated from whole HSDI frames to characterize the amplitude of the vibrations on each side of the glottis, including the frequency, edge length, glottal areas, base cord, and lateral phase differences over the acquisition time. The device was incorporated into a preclinical videokymography diagnosis routine to compare functionality. Results Smartphone-based HSDI with the smartphone-endoscope adaptor could achieve 940 frames per second and a resolution of 1280 by 720 frames, which corresponds to the detection of 3 to 8 frames per vocal cycle at double the spatial resolution of existing devices. The device was used to image the vocal cords of 4 volunteers: 1 healthy individual and 3 patients with vocal cord paralysis, chronic laryngitis, or vocal cord polyps. The resultant image stacks were sufficient for most diagnostic purposes. The cost of the device including the smartphone was lower than that of existing HSDI devices. The image processing and analytics demonstrated the successful calculation of relevant diagnostic variables from the acquired images. Patients with vocal pathologies were easily differentiable in the quantitative data. Conclusions A smartphone-based HSDI endoscope system can function as a point-of-care clinical diagnostic device. The resulting analysis is of higher quality than that accessible by videostroboscopy and promises comparable quality and greater accessibility than HSDI. In particular, this system is suitable for use as an accessible diagnostic tool in underdeveloped areas with inadequate medical service infrastructure.

Published
2021

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