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1.IntroductionOver the last decades, Raman spectroscopy has been actively applied to cancer diagnosis due to its capability to detect a slight variation of chemical composition in biological tissue, caused by malignant transformation. Previous studies have shown that Raman spectroscopy can discriminate between normal and cancerous tissue in various tissues, such as cervix,1–3 skin,4–7 breast,8,9 and gastrointestinal tract.10–13 However, Raman spectroscopy has suffered from strong fluorescence background in biological applications. In addition, the subtle spectral differences between normal and disease tissues make it difficult to analyze the Raman spectra. To overcome those issues, many researchers have proposed the hardware- and/or software-based methods, such as surface-enhanced Raman scattering2,14 and data preprocessing.15,16 While the suggestions for improving the quality of Raman spectra received the most attention in previous studies, a multimodal approach, which combines Raman spectroscopy with other methods, was also of interest to researchers.17–19 Because the malignant transformation of tissues leads to the change in metabolism and optical characteristics as well as in the chemical composition of the tissues, it is expected that we could improve the accuracy and reliability of cancer diagnosis by merging the tissue state data obtained from multimodal methods. For example, Ashok et al.17 reported that both sensitivity of 0.89 and specificity of 0.77 were improved to 0.94 when combining Raman spectroscopy and optical coherence tomography. Lim et al.18 found that a combination of three fiber-optic-based optical spectroscopy modalities of diffuse optical spectroscopy, laser-induced fluorescence spectroscopy, and Raman spectroscopy showed enhanced performance for in vivo noninvasive diagnosis of melanoma and nonmelanoma skin cancer. Kenny et al.19 demonstrated the potential of multimodal spectra imaging based on autofluorescence imaging and Raman microspectroscopy for realizing fast diagnosis of tumors at the surface of large surgical resections with no tissue preparation, such as sectioning and staining. Commonly, it has been known that tumor microenvironment is hypoxic and acidic owing to the chaotic and heterogeneous microvascular structure of solid tumors.20 The pH level of the extracellular matrix around cancer cells has been reported to be in the range of 5.5 to 6.5.21,22 Negrini et al.22 revealed that the pH difference in tissue is attributed to an insufficient vasculature to remove the acidic byproducts of increased anaerobic cellular activity of the rapidly proliferating tumor cells, resulting in lower extracellular pH of tumors compared to contiguous tissues. Therefore, tissue pH level can provide useful and complementary information about cellular metabolism of the tissue in cancer diagnosis using Raman spectroscopy. In this study, we intend to present the dual-modal approach for breast cancer diagnosis based on Raman spectroscopy and optical pH sensing. The chemical and metabolic variations in normal and cancerous breast tissue samples are measured using fiber-optic-based Raman and pH probes, respectively. For dual-modal approach, the Raman data are combined with the pH sensing data. All measured Raman data and combined data are used to perform the classification analysis with principal component linear discriminant analysis (PC-LDA) followed by leave-one-out cross validation (LOOCV). From the results of the sensitivity and specificity obtained from the classification analysis, it is demonstrated that the dual-modal approach improves the classification capability and has the potential for more accurate breast cancer detection. 2.Materials and Methods2.1.Sample PreparationThis study was approved by the Ethics Committee of Kyung Hee University Medical Center (KMC IRB 2016-04-103-003) and all participants signed an informed consent. Twenty breast tissue samples were collected from five participants during breast surgery. Ten samples were from the malignant tumor mass (cancer core area) and the others were from the safety margin outside of the tumor mass. Histological analysis of each sample was performed by expert pathologists and its result was used as gold standard to evaluate the performance of the proposed dual-modal cancer detection. All samples were snap frozen in liquid nitrogen after the collection and stored at to keep their metabolic content and chemical composition as in vivo state.13,23 Just before Raman and optical pH sensing experiments, each sample was thawed for about 10 min at room temperature. The size of each sample was about . 2.2.Raman SpectroscopyThe Raman lensed fiber-optic probe24 (Raman probe, EmVision LLC) was used to obtain the Raman spectra from the breast tissue samples as shown in Fig. 1. The Raman probe consists of one central excitation fiber and seven Raman signal collection fibers, which have a low hydroxyl (OH) content, core diameter and 0.22 NA. For the sample end of the Raman probe, a bandpass filter and a donut-shaped longpass filter are positioned in front of the central excitation fiber and the seven Raman signal collection fibers, respectively, to remove the excitation source signal and pass the Stokes Raman signal. The excitation source of 785 nm (I0785MM0350MF, Innovative Photonic Solutions) is delivered on the sample surface with the laser power of 200 mW through the central excitation fiber. Then, the Raman scattering signal reflected from the sample surface is collected and delivered through the seven Raman signal collection fibers and detected by a Czerny–Turner spectrograph (SR-303i-A, Andor Technology) with a low dark current deep-depletion CCD (iVac, Andor Technology). For Raman experiments, each thawed sample was laid on a slide glass surrounded by aluminum foil. The strong and broad fluorescence signal of a slide glass caused by a 785-nm source is prevented by aluminum foil because of its infrared opacity.25 In addition, aluminum foil yields a very low and featureless spectral background, which enables the acquisition of high-quality Raman spectra from biological samples.25 Twenty Raman spectra from two different positions were measured for each breast tissue sample. All Raman spectra were acquired in the range of 600 to with the spectral resolution of and the acquisition time of 1 s. 2.3.Optical pH SensingTo optically measure the pH variation between normal and cancerous samples, a fiber-optic-based pH probe was made by the layer-by-layer electrostatic self-assembly technique.26 3-Amino-7-dimethylamino-2-methylphenazine hydrochloride, commonly known as neutral red (NR), and poly(acrylic acid) (PAA, ) were used as the cationic chemical and anionic polyelectrolyte, respectively, for the fabrication of the nanostructured sensitive films. Ten millimolar solutions of the two chemicals was prepared using deionized water. Then, the pH of the solutions was adjusted to pH 4.2 by adding a few drops of NaOH or HCl to achieve the strong and stable electrostatic interactions between the two chemicals.27 All chemicals were purchased from Sigma–Aldrich Inc. and used without further purification. A multimode plastic-clad silica-core fiber (FT200EMT, Thorlabs Inc., core diameter, cladding diameter, 0.39 NA) was used to fabricate the pH probe. About 1-cm part of the optical fiber cladding was chemically removed with acetone prior to the polymeric coating fabrication. The exposed part was first immersed into 1 M KOH solution for 10 min to acquire negative charge at the surface of the optical fiber core and then was rinsed in deionized water. Afterward, the exposed part was immersed into the 10 mM NR solution for 2 min to fabricate the cationic layer and rinsed in deionized water for 1 min. After the exposed part was immersed into 10 mM PAA solution for 2 min to fabricate the anionic layer and rinsed again in deionized water for 1 min. From this sequence, the bilayer of NR/PAA was fabricated at the exposed part of the optical fiber. In this study, the sequence was repeated 15 times. The transmission characteristics of the fabricated pH probe were investigated in the range of 640 to 760 nm using the standard buffer solutions of pH values 6, 7, and 8. To obtain the transmission spectra of Fig. 2(a), whenever each standard pH solution was dropped onto the surface of the exposed part of the fiber-optic-based pH probe (pH-sensitive region), the transmission spectra at pH values 6, 7, and 8 were measured by the spectrograph with CCD used in Raman experiment (refer to Fig. 3). The observed variation trend of the transmission spectra according to pH level is consistent with earlier study.28 Figure 2(b) shows the calibration curve of the pH probe between pH values 6 and 8, which was obtained using the integrated transmission intensity values, areas under the transmission spectral curves of Fig. 2(a). After the calibration of the pH probe, the transmission spectra of the normal and cancerous breast tissue samples were also measured immediately after Raman experiments. Because Raman probe and pH probe differed in spot size and shape (Raman probe: 0.3-mm diameter, pH probe: ), the exact registration between Raman and pH measurement spots was not possible. Instead, the measurement spots of the transmission spectra overlapped with those of the Raman spectra. As shown in Fig. 3, each tissue sample was laid on the pH-sensitive region. Then, a white light (Fiber-Lite DC950, Dolan-Jenner) passed through the pH-sensitive region and the transmission spectra varying according to the pH levels of the tissue samples were measured. During the pH experiments, the pH-sensitive region was fixed onto a slide glass to avoid its undesired bending. Twenty transmission spectra from two different positions were measured for each breast tissue sample. All transmission spectra were acquired in the range of 640 to 760 nm with the spectral resolution of 0.08 nm and the acquisition time of 1 s. 2.4.Multivariate Statistical AnalysisAfter the measurements of Raman spectra from the breast tissue samples, the instrument and CCD noise spectra, which were measured without the samples were simply subtracted from the raw Raman spectra of the samples. The noise-corrected Raman spectra were smoothed by the Savitzky–Golay digital filter with smoothing width of 9 and degree of 3 followed by baselining using improved modified multipolynomial fitting.13,15 To remove the spectral variations by the fluctuations of excitation source, environment, and/or sample conditions, which are not related to the actual differences in the samples, the baseline-corrected Raman spectra were normalized by the vector normalization technique,29 where each of the Raman intensities corresponding to a Raman shift is divided by the Euclidean norm. For a dual-modal approach in multivariate statistical analysis, each normalized Raman spectrum was combined with each transmission spectrum obtained from the same sample. The combined spectra (pH-Raman spectra) have the wavelength range of 640 to 760 nm for the transmission spectra and 824 to 914 nm for the Raman spectra. The 400 normalized Raman spectra (200 from cancerous samples and 200 from normal samples) were analyzed to evaluate the classification capability of only Raman spectroscopy. Whereas the 400 pH-Raman spectra (also 200 from cancerous samples and 200 from normal samples) were analyzed for the performance evaluation of the proposed dual-modal cancer detection based on optical pH sensing and Raman spectroscopy. PC-LDA was employed for the classification analysis on only Raman spectra and the pH-Raman spectra. LOOCV was used for evaluating the performance of the classification technique. All analyses were implemented using R program version 3.3.2. 3.Results and DiscussionFigure 4(a) shows the normalized and averaged Raman spectra for the normal and cancerous breast tissue samples. Each Raman spectrum represents the average (solid and dashed lines) and standard deviation (filled areas) calculated from 200 Raman spectra. The spectral profile is consistent with earlier studies, for example, phenylalanine ring breathing (), phospholipids (), amide III in proteins (), deformation in lipids (1305 and ), amide I in proteins (), and carbonyl stretch ().30–33 There exists spectral regions where the classification between normal and cancerous samples is possible with the naked eye. For the Raman spectra of the cancerous samples, it is observed that significant decrease in the normalized Raman intensity takes place in most of the spectral regions. In particular, the peak intensity at , usually due to fat content,33 ceases to exist in the cancerous sample case. Also, the peak intensities at 1305 and assigned to vibrational modes of lipids30–33 show much greater decrease than those at 1270 and assigned to vibrational modes of proteins.30–33 That is to say that the intensity ratio of lipid to protein content is decreased for the cancerous sample case. On the other hand, the peak intensity at , usually related to phenylalanine32,33 which is essential amino acid of proteins, is stronger in the cancerous sample than in the normal one. The observed differences in Raman spectra between normal and cancerous samples can be thus understood to imply that normal breast tissue predominantly contains lipids, whereas cancerous breast tissue mostly contains proteins, which agrees with earlier study.30,32,33 Figure 4(b) shows the average (solid and dashed lines) and standard deviation (filled areas) of transmission spectra () obtained from the normal and cancerous breast tissue samples. For the whole transmission spectral region, it is observed that the average transmission intensities of normal samples are stronger than those of cancerous samples. These observations can be explained through the absorbance change of NR/PAA bilayer at varying pH level. Goicoechea et al.28 reported that the absorbance of NR/PAA bilayer decreases as the pH level is raised within the wavelength range from 600 to 800 nm. This, in other words, means that the transmission intensity by NR/PAA bilayer increases with increasing pH level. Therefore, from Fig. 4(b), it is confidently expected that the pH level of normal breast tissue samples is higher than that of cancerous ones. The integrated transmission intensity values of normal and cancerous samples were and , respectively. Using the equation of pH calibration curve of Fig. 2(b), the pH levels of normal and cancerous samples were estimated to be about and , respectively, which corresponds to the well-known fact that the pH level of cancerous tissues is lower than that of normal tissues and lies within the pH range from 5.5 to 6.5.20–22 Principal component analysis (PCA) was used to reduce the high dimensionality in the spectral data of the normal and cancerous samples. Figure 5 shows the cluster plot of PCA scores on the principal components (PCs) of normal and cancerous samples in Raman-only and pH-Raman spectral analysis. The first, second, and third PCs in Raman-only spectral analysis accounted for 82.7%, 2.6%, and 2.1% of the total variance, respectively, whereas those in pH-Raman spectral analysis were 73.5%, 7.4%, and 4.7%. In Fig. 5, it seems that PCA can successfully separate the cluster groups between normal and cancerous samples regardless of the use of pH data. To more accurately assess the classification capability between the Raman-only and pH-Raman detection method, PC-LDA followed by LOOCV was used. The number of PCs is determined using two selection criteria: scree plot test and cumulative percentage variance.34 Figure 6 shows the scree plot of the eigenvalues (variances) along the PC number in Raman-only and pH-Raman spectral analysis. The scree plot test searches for a knee point in the plot curve where the optimal number of PCs reached.34 From the Raman-only curve in Fig. 6, the third PC can be selected as a knee point for Raman-only spectral analysis. On the contrary, for pH-Raman spectral analysis, it is difficult to determine the knee point due to the smooth curve. In cumulative percentage variance, the optimal number of PCs is determined using a user-defined threshold value of cumulative percentage of the variance (usually 90% to 99% of the variance).34 In this study, 90% was used as the threshold value. When the number of PCs was 5 (PC 1 to 5), the cumulative percentage of the variance was 90.5% and 90.4% for Raman-only and pH-Raman spectral analysis, respectively. Therefore, the PC 1 to 5 was used to perform classification analysis using PC-LDA with LOOCV. The results of multivariate statistical analysis using the PC 1 to 5 are represented in Table 1. The confusion matrix shows the tabular data for predicted class versus actual class of normal and cancerous samples in Raman-only, pH-only, and pH-Raman spectral analysis. The results of sensitivity , true positive rate, for Raman-only and pH-Raman spectral analyses are equal to 1. On the other hand, the specificity , true negative rate, are improved from 0.91 to 0.98 for pH-Raman case. Enhanced specificity quantitatively presents the potential of dual-modal cancer detection using fiber-optic-based Raman and pH probes for accurate diagnosis. Table 1Confusion matrix of Raman-only, pH-only, and pH-Raman spectral analysis.
Note: TP, true positive; TN, true negative; FP, false positive; and FN, false negative. 4.ConclusionFrom the experimental study of measuring the Raman spectra and pH levels of normal and cancerous breast tissue samples, it was found that both Raman spectra with chemical information and transmission spectra with pH information are useful in classifying normal and cancerous samples. When the dual-modal method based on Raman spectroscopy and optical pH sensing and multivariate statistical analysis work together, it is demonstrated that classification between normal and cancerous breast tissue samples was significantly improved. More specifically, multivariate statistical analysis using PC-LDA followed by LOOCV showed an enhanced specificity for breast cancer diagnosis. The suggested approach supports the potential practical applications of a pH-Raman-based detection method for breast cancer diagnosis. AcknowledgmentsThis work was supported by the National Research Foundation of Korea (NRF) grant funded by the Korean Government (2015M2A2A7A03043177 and 2017R1A2B4012428). ReferencesE. Vargis et al.,
“Effect of normal variations on disease classification of Raman spectra from cervical tissue,”
Analyst, 136
(14), 2981
–2987
(2011). http://dx.doi.org/10.1039/c0an01020k ANLYAG 0365-4885 Google Scholar
S. Feng et al.,
“Blood plasma surface-enhanced Raman spectroscopy for non-invasive optical detection of cervical cancer,”
Analyst, 138
(14), 3967
–3974
(2013). http://dx.doi.org/10.1039/c3an36890d ANLYAG 0365-4885 Google Scholar
R. Shaikh et al.,
“In vivo Raman spectroscopy of human uterine cervix: exploring the utility of vagina as an internal control,”
J. Biomed. Opt., 19
(8), 087001
(2014). http://dx.doi.org/10.1117/1.JBO.19.8.087001 JBOPFO 1083-3668 Google Scholar
M. Gniadecka et al.,
“Melanoma diagnosis by Raman spectroscopy and neural networks: structure alterations in proteins and lipids in intact cancer tissue,”
J. Invest. Dermatol., 122
(2), 443
–449
(2004). http://dx.doi.org/10.1046/j.0022-202X.2004.22208.x JIDEAE 0022-202X Google Scholar
C. A. Lieber et al.,
“Raman microspectroscopy for skin cancer detection in vitro,”
J. Biomed. Opt., 13
(2), 024013
(2008). http://dx.doi.org/10.1117/1.2899155 JBOPFO 1083-3668 Google Scholar
H. Lui et al.,
“Real-time Raman spectroscopy for in vivo skin cancer diagnosis,”
Cancer Res., 72
(10), 2491
–2500
(2012). http://dx.doi.org/10.1158/0008-5472.CAN-11-4061 CNREA8 0008-5472 Google Scholar
I. P. Santos et al.,
“Raman spectroscopic characterization of melanoma and benign melanocytic lesions suspected of melanoma using high-wavenumber Raman spectroscopy,”
Anal. Chem., 88
(15), 7683
–7688
(2016). http://dx.doi.org/10.1021/acs.analchem.6b01592 ANCHAM 0003-2700 Google Scholar
H. Abramczyk et al.,
“Raman imaging in biochemical and biomedical applications. Diagnosis and treatment of breast cancer,”
Chem. Rev., 113
(8), 5766
–5781
(2013). http://dx.doi.org/10.1021/cr300147r CHREAY 0009-2665 Google Scholar
B. Brozek-Pluska et al.,
“Raman spectroscopy and imaging: applications in human breast cancer diagnosis,”
Analyst, 137
(16), 3773
–3780
(2012). http://dx.doi.org/10.1039/c2an16179f ANLYAG 0365-4885 Google Scholar
H. Krishna et al.,
“In vivo Raman spectroscopy for detection of oral neoplasia: a pilot clinical study,”
J. Biophotonics, 7
(9), 690
–702
(2014). http://dx.doi.org/10.1002/jbio.v7.9 Google Scholar
M. S. Bergholt et al.,
“Fiberoptic confocal Raman spectroscopy for real-time in vivo diagnosis of dysplasia in Barrett’s esophagus,”
Gastroenterology, 146
(1), 27
–32
(2014). http://dx.doi.org/10.1053/j.gastro.2013.11.002 GASTAB 0016-5085 Google Scholar
J. Wang et al.,
“Comparative study of the endoscope-based bevelled and volume fiber-optic Raman probes for optical diagnosis of gastric dysplasia in vivo at endoscopy,”
Anal. Bioanal. Chem., 407
(27), 8303
–8310
(2015). http://dx.doi.org/10.1007/s00216-015-8727-x ABCNBP 1618-2642 Google Scholar
J. Addis et al.,
“Raman spectroscopy of endoscopic colonic biopsies from patients with ulcerative colitis to identify mucosal inflammation and healing,”
Biomed. Opt. Express, 7
(5), 2022
–2035
(2016). http://dx.doi.org/10.1364/BOE.7.002022 BOEICL 2156-7085 Google Scholar
R. Buividas et al.,
“Statistically quantified measurement of an Alzheimer’s marker by surface-enhanced Raman scattering,”
J. Biophotonics, 8
(7), 567
–574
(2015). http://dx.doi.org/10.1002/jbio.201400017 Google Scholar
J. Zhao et al.,
“Automated autofluorescence background subtraction algorithm for biomedical Raman spectroscopy,”
Appl. Spectrosc., 61
(11), 1225
–1232
(2007). http://dx.doi.org/10.1366/000370207782597003 APSPA4 0003-7028 Google Scholar
S. Guo et al.,
“Optimization of Raman-spectrum baseline correction in biological application,”
Analyst, 141
(8), 2396
–2404
(2016). http://dx.doi.org/10.1039/C6AN00041J ANLYAG 0365-4885 Google Scholar
P. C. Ashok et al.,
“Multi-modal approach using Raman spectroscopy and optical coherence tomography for the discrimination of colonic adenocarcinoma from normal colon,”
Biomed. Opt. Express, 4
(10), 2179
–2186
(2013). http://dx.doi.org/10.1364/BOE.4.002179 BOEICL 2156-7085 Google Scholar
L. Lim et al.,
“Clinical study of noninvasive in vivo melanoma and nonmelanoma skin cancers using multimodal spectral diagnosis,”
J. Biomed. Opt., 19
(11), 117003
(2014). http://dx.doi.org/10.1117/1.JBO.19.11.117003 JBOPFO 1083-3668 Google Scholar
K. Kenny et al.,
“Integrated Raman microscopy and auto-fluorescence imaging for fast tumour diagnosis during cancer surgery,”
in Optical Tomography and Spectroscopy,
(2016). Google Scholar
P. A. Schornack et al.,
“Contributions of cell metabolism and diffusion to the acidic pH of tumors,”
Neoplasia, 5
(2), 135
–145
(2003). http://dx.doi.org/10.1016/S1476-5586(03)80005-2 Google Scholar
R. A. Gatenby et al.,
“Why do cancers have high aerobic glycolysis,”
Nat. Rev. Cancer, 4
(11), 891
–899
(2004). http://dx.doi.org/10.1038/nrc1478 NRCAC4 1474-175X Google Scholar
R. Negrini et al.,
“pH-responsive lyotropic liquid crystals and their potential therapeutic role in cancer treatment,”
Chem. Commun., 51
(30), 6671
–6674
(2015). http://dx.doi.org/10.1039/C4CC10274F Google Scholar
C. M. Monoranu et al.,
“pH measurement as quality control on human post mortem brain tissue: a study of the BrainNet Europe consortium,”
Neuropathol. Appl. Neurobiol., 35
(3), 329
–337
(2009). http://dx.doi.org/10.1111/nan.2009.35.issue-3 NANEDL 1365-2990 Google Scholar
M. Agenant et al.,
“Clinical superficial Raman probe aimed for epithelial tumor detection: phantom model results,”
Biomed. Opt. Express, 5
(4), 1203
–1216
(2014). http://dx.doi.org/10.1364/BOE.5.001203 BOEICL 2156-7085 Google Scholar
L. Cui et al.,
“Aluminium foil as a potential substrate for ATR-FTIR, transflection FTIR or Raman spectrochemical analysis of biological specimens,”
Anal. Methods, 8
(3), 481
–487
(2016). http://dx.doi.org/10.1039/C5AY02638E AMNEGX 1759-9679 Google Scholar
G. Decher,
“Fuzzy nanoassemblies: toward layered polymeric multicomposites,”
Science, 277
(5330), 1232
–1237
(1997). http://dx.doi.org/10.1126/science.277.5330.1232 SCIEAS 0036-8075 Google Scholar
J. Hodak et al.,
“Layer-by-layer self-assembly of glucose oxidase with a poly(allylamine)ferrocene redox mediator,”
Langmuir, 13
(10), 2708
–2716
(1997). http://dx.doi.org/10.1021/la962014h LANGD5 0743-7463 Google Scholar
J. Goicoechea et al.,
“Optical fiber pH sensors based on layer-by-layer electrostatic self-assembled neutral red,”
Sens. Actuator B Chem., 132
(1), 305
–311
(2008). http://dx.doi.org/10.1016/j.snb.2008.01.056 Google Scholar
R. Gautam et al.,
“Review of multidimensional data processing approaches for Raman and infrared spectroscopy,”
EPJ Tech. Instrum., 2
(1), 1
–38
(2015). http://dx.doi.org/10.1140/epjti/s40485-015-0018-6 Google Scholar
M. V. P. Chowdary et al.,
“Discrimination of normal, benign, and malignant breast tissues by Raman spectroscopy,”
Biopolymers, 83
(5), 556
–569
(2006). http://dx.doi.org/10.1002/(ISSN)1097-0282 BIPMAA 0006-3525 Google Scholar
S. K. Majumder et al.,
“Comparison of autofluorescence, diffuse reflectance, and Raman spectroscopy for breast tissue discrimination,”
J. Biomed. Opt., 13
(5), 054009
(2008). http://dx.doi.org/10.1117/1.2975962 JBOPFO 1083-3668 Google Scholar
M. D. Keller et al.,
“Spatially offset Raman spectroscopy of layered soft tissues,”
Opt. Lett., 34
(7), 926
–928
(2009). http://dx.doi.org/10.1364/OL.34.000926 OPLEDP 0146-9592 Google Scholar
M. D. Keller et al.,
“Development of a spatially offset Raman spectroscopy probe for breast tumor surgical margin evaluation,”
J. Biomed. Opt., 16
(7), 077006
(2011). http://dx.doi.org/10.1117/1.3600708 JBOPFO 1083-3668 Google Scholar
E. Ly et al.,
“Combination of FTIR spectral imaging and chemometrics for tumour detection from paraffin-embedded biopsies,”
Analyst, 133
(2), 197
–205
(2008). http://dx.doi.org/10.1039/B715924B ANLYAG 0365-4885 Google Scholar
BiographySoogeun Kim received his MS and PhD degrees in mechatronics from Gwangju Institute of Science and Technology in 2007 and 2015, respectively. He is a research professor at Kyung Hee University, Republic of Korea. His research interests focus on laser–tissue interaction phenomena and their applications, and ongoing research includes Raman spectroscopy for cancer detection, fiber-optic-based Raman spectroscopy, and spectrum data analysis by neural networks. Seung Ho Lee received his MS degree in biomedical engineering from the Department of Medical Engineering, Kyung Hee University, in 2013. Since 2013, he has studied biomechatronics and biosensors with biomedical engineering on a doctorate path in the Department of Medical Engineering, College of Medicine at Kyung Hee University. Sun Young Min received her BS degree in medicine from Chungnam National University in 2003 and her MS and PhD degrees in medicine from Kyung Hee University in 2008 and 2011, respectively. She is an assistant professor at Kyung Hee University. Her current research interests include breast cancer, cancer pathology, and convergence technology research. She is a member of the Korean Breast Cancer Society. Kyung Min Byun received his BS and MS degrees from the School of Electrical Engineering, Seoul National University, Seoul, Republic of Korea, and his PhD from Seoul National University in 2007. From July 2007 to February 2008, he worked as a visiting scientist in the Department of Biomedical Engineering, Cornell University, Ithaca, New York. Currently, he is working as an associate professor in the Department of Biomedical Engineering, Kyung Hee University, Yongin, Republic of Korea. His main research activities are theoretical and experimental studies on high-sensitivity plasmonic biosensors with metallic nanostructures, Raman spectroscopy, and minimally invasive neuromodulation technique based on optical and ultrasound stimulation. Soo Yeol Lee received his MS and PhD degrees in electronics engineering from Korea Advanced Institute of Science and Technology, Seoul, Republic of Korea, in 1985 and 1989, respectively. He was in the Department of Biomedical Engineering, Konkuk University, Republic of Korea, from 1992 to 1999. In 1999, he joined the Department of Biomedical Engineering, Kyung Hee University, where he is currently the director of the Functional and Metabolic Imaging Research Center. His current research interests include MRI, CT, elastography, and medical image/signal processing. |