[1] P. Bailey, H. Cushing, “A classification of the tumors of the glioma group on a histogenetic basis with a correlated study of prognosis,” J. B. Lippincott Co., Philadelphia (1926).

[2] J. W. Kernohan, R. Mabon, “A simplified classification of the gliomas,” Proc. Staff Meetings, Mayo Clinic (1949).

[3] N. Ringertz, “Grading of gliomas,” APMIS 27, 51-64 (1950).

[4] D. N. Louis, H. Ohgaki, O. D. Wiestler, W. K. Cavenee, P. C. Burger, A. Jouvet, B. W. Scheithauer, P. Kleihues, “The 2007 WHO classification of tumours of the central nervous system,” Acta Neuropathol. 114, 97-109 (2007).

[5] K. R. Lamborn, W. K. A. Yung, S. M. Chang, P. Y. Wen, T. F. Cloughesy, L. M. DeAngelis, H. I. Robins, F. S. Lieberman, H. A. Fine, K. L. Fink, L. Junck, L. Abrey, M. R. Gilbert, M. Mehta, J. G. Kuhn, K. D. Aldape, J. Hibberts, P. M. Peterson, M. D. Prados, N. A. B. T. Consortium, “Progression-free survival: An important end point in evaluating therapy for recurrent high-grade gliomas,” Neuro-Oncol. 10, 162-170 (2008).

[6] W. Stummer, J.-C. Tonn, H. M. Mehdorn, U. Nestler, K. Franz, C. Goetz, A. Bink, U. Pichlmeier, “Counterbalancing risks and gains from extended resections in malignant glioma surgery: A supplemental analysis from the randomized 5-aminolevulinic acid glioma resection study: Clinical article,” J. Neurosurg. 114, 613-623 (2011).

[7] I.-F. Talos, K. H. Zou, L. Ohno-Machado, J. G. Bhagwat, R. Kikinis, P. M. Black, F. A. Jolesz, “Supratentorial low-grade glioma resectability: Statistical predictive analysis based on anatomic MR features and tumor characteristics 1,” Radiology 239, 506-513 (2006).

[8] I. Pence, A. Mahadevan-Jansen, “Clinical instrumentation and applications of Raman spectroscopy,” Chem. Soc. Rev. 45, 1958-1979 (2016).

[9] C. V. Raman, K. S. Krishnan, “A new type of secondary radiation,” Nature 121, 501-502 (1928).

[10] H. Abdi, L. J. Williams, “Principal component analysis,” Wiley Interdiscip. Rev. Comput. Stat. 2, 433-459 (2010).

[11] K. Varmuza, P. Filzmoser, Introduction to Multivariate Statistical Analysis in Chemometrics, CRC Press (2009).

[12] H. J. Butler, L. Ashton, B. Bird, G. Cinque, K. Curtis, J. Dorney, K. Esmonde-White, N. J. Fullwood, B. Gardner, P. L. Martin-Hirsch, “Using Raman spectroscopy to characterize biological materials,” Nat. Protoc. 11, 664-687 (2016).

[13] K. Tashibu, “Analysis of water content in rat brain using Raman spectroscopy,” No to Shinkei = Brain and Nerve 42, 999-1004 (1990).

[14] T. Kitajima, K. Tashibu, S. Tani, A. Mizuno, N. Nakamura, “Analysis of water content in young rats brain edema by Raman spectroscopy,” No to Shinkei = Brain and Nerve 45, 519-524 (1993).

[15] A. Mizuno, T. Hayashi, K. Tashibu, S. Maraishi, K. Kawauchi, Y. Ozaki, “Near-infrared FT-Raman spectra of the rat brain tissues,” Neurosci. Lett. 141, 47-52 (1992).

[16] A. Mizuno, H. Kitajima, K. Kawauchi, S. Muraishi, Y. Ozaki, “Near-infrared Fourier transform Raman spectroscopic study of human brain tissues and tumours,” J. Raman Spectrosc. 25, 25-29 (1994).

[17] N. Amharref, A. Beljebbar, S. Dukic, L. Venteo, L. Schneider, M. Pluot, M. Manfait, “Discriminating healthy from tumor and necrosis tissue in rat brain tissue samples by Raman spectral imaging,” Biochim. Biophys. Acta Biomembr. 1768, 2605-2615 (2007).

[18] S. Koljenovic, T. Bakker Schut, R. Wolthuis, A. Vincent, G. Hendriks-Hagevi, L. Santos, J. Kros, G. Puppels, “Raman spectroscopic characterization of porcine brain tissue using a single fiber-optic probe,” Anal. Chem. 79, 557-564 (2007).

[19] C. Krafft, M. Kirsch, C. Beleites, G. Schackert, R. Salzer, “Methodology for fiber-optic Raman mapping and FTIR imaging of metastases in mouse brains,” Anal. Bioanal. Chem. 389, 1133-1142 (2007).

[20] M. Kirsch, G. Schackert, R. Salzer, C. Krafft, “Raman spectroscopic imaging for in vivo detection of cerebral brain metastases,” Anal. Bioanal. Chem. 398, 1707-1713 (2010).

[21] A. Beljebbar, S. Dukic, N. Amharref, M. Manfait, “Ex vivo and in vivo diagnosis of C6 glioblastoma development by Raman spectroscopy coupled to a microprobe,” Anal. Bioanal. Chem. 398, 477-487 (2010).

[22] K. Tanahashi, A. Natsume, F. Ohka, H. Momota, A. Kato, K. Motomura, N. Watabe, S. Muraishi, H. Nakahara, Y. Saito, I. Takeuchi, T. Wakabayashi, “Assessment of tumor cells in a mouse model of diffuse infiltrative glioma by Raman spectroscopy,” BioMed. Res. Int. 2014, 860241 (2014).

[23] S. Koljenovic, L. Choo-Smith, T. C. Bakker Schut, J. M. Kros, H. J. van den Berge, G. J. Puppels, “Discriminating vital tumor from necrotic tissue in human glioblastoma samples by Raman microspectroscopy,” Microsc. Microana. 8, 444-445 (2002).

[24] C. Krafft, L. Neudert, T. Simat, R. Salzer, “Near infrared Raman spectra of human brain lipids,” Spectrochim. Acta A, Mole. Biomole. Spectrosc. 61, 1529-1535 (2005).

[25] C. Krafft, S. B. Sobottka, G. Schackert, R. Salzer, “Near infrared Raman spectroscopic mapping of native brain tissue and intracranial tumors,” Analyst 130, 1070-1077 (2005).

[26] S. Koljenovic, T. B. Schut, R. D. Wolthuis, B. De Jong, L. Santos, P. J. Caspers, J. M. Kros, G. J. Puppels, “Tissue characterization using high wave number Raman spectroscopy,” J. Biomed. Opt. 10, 031116-03111611 (2005).

[27] M. Kohler, S. Machill, R. Salzer, C. Krafft, “Characterization of lipid extracts from brain tissue and tumors using Raman spectroscopy and mass spectrometry,” Analy. Bioanal. Chem. 393, 1513-1520 (2009).

[28] R. Rabah, R. Weber, G. K. Serhatkulu, A. Cao, H. Dai, A. Pandya, R. Naik, G. Auner, J. Poulik, M. Klein, “Diagnosis of neuroblastoma and ganglioneuroma using Raman spectroscopy,” J. Pediatr. Surg. 43, 171-176 (2008).

[29] H. Wills, R. Kast, C. Stewart, R. Rabah, A. Pandya, J. Poulik, G. Auner, M. D. Klein, “Raman spectroscopy detects and distinguishes neuroblastoma and related tissues in fresh and (banked) frozen specimens,” J. Pediatr. Surg. 44, 386-391 (2009).

[30] D. G. Leslie, R. E. Kast, J. M. Poulik, R. Rabah, S. Sood, G. W. Auner, M. D. Klein, “Identification of pediatric brain neoplasms using Raman spectroscopy,” Pediatr. Neurosurg. 48, 109-117 (2012).

[31] K. Gajjar, L. D. Heppenstall, W. Pang, K. M. Ashton, J. Trevisan, I. I. Patel, V. Llabjani, H. F. Stringfellow, P. L. Martin-Hirsch, T. Dawson, F. L. Martin, “Diagnostic segregation of human brain tumours using Fourier-transform infrared and/or Raman spectroscopy coupled with discriminant analysis,” Anal. Methods: Adv. Methods Appl. 5, 89-102 (2012).

[32] R. P. Aguiar, L. Silveira Jr, E. T. Falcao, M. T. T. Pacheco, R. A. Zangaro, C. A. Pasqualucci, “Discriminating neoplastic and normal brain tissues in vitro through Raman spectroscopy: A principal components analysis classification model,” Photomed. Laser Surg. 31, 595-604 (2013).

[33] C. Beleites, K. Geiger, M. Kirsch, S. B. Sobottka, G. Schackert, R. Salzer, “Raman spectroscopic grading of astrocytoma tissues: Using soft reference information,” Anal. Bioanal. Chem. 400, 2801-2816 (2011).

[34] S. N. Kalkanis, R. E. Kast, M. L. Rosenblum, T. Mikkelsen, S. M. Yurgelevic, K. M. Nelson, A. Raghunathan, L. M. Poisson, G. W. Auner, “Raman spectroscopy to distinguish grey matter, necrosis, and glioblastoma multiforme in frozen tissue sections,” J. Neuro-oncol. 116, 477 (2014).

[35] R. E. Kast, G. W. Auner, M. L. Rosenblum, T. Mikkelsen, S. M. Yurgelevic, A. Raghunathan, L. M. Poisson, S. N. Kalkanis, “Raman molecular imaging of brain frozen tissue sections,” J. Neuro-oncol. 120, 55 (2014).

[36] R. Kast, G. Auner, S. Yurgelevic, B. Broadbent, A. Raghunathan, L. M. Poisson, T. Mikkelsen, M. L. Rosenblum, S. N. Kalkanis, “Identification of regions of normal grey matter and white matter from pathologic glioblastoma and necrosis in frozen sections using Raman imaging,” J. Neuro-oncol. 125, 287 (2015).

[37] T. Liu, C. Chen, X. Shi, C. Liu, “Evaluation of Raman spectra of human brain tumor tissue using the learning vector quantization neural network,” Laser Phys. 26, 055606 (2016).

[38] R. Stables, G. Clemens, H. J. Butler, K. M. Ashton, A. Brodbelt, T. P. Dawson, L. M. Fullwood, M. D. Jenkinson, M. J. Baker, “Feature driven classification of Raman spectra for real-time spectral brain tumour diagnosis using sound,” Analyst 142, 98-109 (2017).

[39] N. Sanai, M.-Y. Polley, M. W. McDermott, A. T. Parsa, M. S. Berger, “An extent of resection threshold for newly diagnosed glioblastomas,” J. Neurosurg. 115, 3-8 (2011).

[40] J. Desroches, M. Jermyn, K. Mok, C. Lemieux-Leduc, J. Mercier, K. St-Arnaud, K. Urmey, M.-C. Guiot, E. Marple, K. Petrecca, “Characterization of a Raman spectroscopy probe system for intraoperative brain tissue classification,” Biomed. Opt. Express 6, 2380-2397 (2015).

[41] M. Jermyn, K. Mok, J. Mercier, J. Desroches, J. Pichette, K. Saint-Arnaud, L. Bernstein, M.-C. Guiot, K. Petrecca, F. Leblond, “Intraoperative brain cancer detection with Raman spectroscopy in humans,” Sci. Transl. Med. 7, 274ra19-274ra19 (2015).

[42] M. Jermyn, J. Desroches, J. Mercier, M.-A. Tremblay, K. St-Arnaud, M.-C. Guiot, K. Petrecca, F. Leblond, “Neural networks improve brain cancer detection with Raman spectroscopy in the presence of operating room light artifacts,” J. Biomed. Opt. 21, 094002-094002 (2016).

[43] M. Jermyn, J. Desroches, J. Mercier, K. St-Arnaud, M.-C. Guiot, F. Leblond, K. Petrecca, “Raman spectroscopy detects distant invasive brain cancer cells centimeters beyond MRI capability in humans,” Biomed. Opt. Express 7, 5129-5137 (2016).

[44] J. Desroches, M. Jermyn, M. Pinto, F. Picot, M.-A. Tremblay, S. Obaid, M.-C. Guiot, K. Petrecca, C. B. Wilson, F. Leblond, “High wavenumber Raman spectroscopy to improve diagnostic yield of brain needle biopsies, ” in Optics in the Life Sciences Congress, Optical Society of America, San Diego, California (2017).

[45] O. Uckermann, R. Galli, S. Tamosaityte, E. Leipnitz, K. D. Geiger, G. Schackert, E. Koch, G. Steiner, M. Kirsch, “Label-free delineation of brain tumors by coherent anti-Stokes Raman scattering microscopy in an orthotopic mouse model and human glioblastoma,” PLoS One 9, e107115 (2014).

[46] M. Ji, D. A. Orringer, C. W. Freudiger, Sci. Transl. Med. 5, 201ra119 (2013).

[47] J. N. Bentley, M. Ji, X. S. Xie, D. A. Orringer, “Real-time image guidance for brain tumor surgery through stimulated Raman scattering microscopy,” Expert Rev. Anticancer Ther. 14, 359-361 (2014).

[48] R. Galli, O. Uckermann, A. Temme, E. Leipnitz, M. Meinhardt, E. Koch, G. Schackert, G. Steiner, M. Kirsch, “Assessing the efficacy of coherent anti-Stokes Raman scattering microscopy for the detection of infiltrating glioblastoma in fresh brain samples,” J. Biophoton. 10, 404-414 (2017).

[49] M. Ji, S. Lewis, S. Camelo-Piragua, S. H. Ramkissoon, M. Snuderl, S. Venneti, A. Fisher-Hubbard, M. Garrard, D. Fu, A. C. Wang, “Detection of human brain tumor infiltration with quantitative stimulated Raman scattering microscopy,” Sci. Transl. Med. 7, 309ra163-309ra163 (2015).

[50] S. Lewis, D. Orringer, “Detection of brain tumors using stimulated Raman scattering microscopy,” Deep Imaging in Tissue and Biomedical Materials: Using Linear and Nonlinear Optical Methods, CRC Press 413 (2017). ISBN: 1351797395, 9781351797399.

[51] Y. Zhou, C.-H. Liu, Y. Pu, G. Cheng, X. Yu, L. Zhou, D. Lin, K. Zhu, R. R. Alfano, “Resonance Raman Spectroscopy of human brain metastasis of lung cancer analyzed by blind source separation,” in Proc. SPIE Proceedings Volume 10051, Neural Imaging and Sensing; 100511I (2017), doi: 10.1117/12.2254465.