1. Accurate identification of breast cancer margins in microenvironments of ex-vivo basal and luminal breast cancer tissues using Raman spectroscopy
- Author
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Kenneth V. Honn, Cameron W. Werner, Changhe Huang, Rachel E. Kast, John Shanley, S. Kiran Koya, Krishna Rao Maddipati, Sally Yurgelevic, Gregory W. Auner, Michelle Brusatori, and Mark E. Sherman
- Subjects
0301 basic medicine ,Physiology ,medicine.medical_treatment ,H&E stain ,Connective tissue ,Adipose tissue ,Breast Neoplasms ,030204 cardiovascular system & hematology ,Spectrum Analysis, Raman ,Biochemistry ,03 medical and health sciences ,symbols.namesake ,Deep Learning ,0302 clinical medicine ,Breast cancer ,Tumor Microenvironment ,medicine ,Breast-conserving surgery ,Humans ,Pharmacology ,Receiver operating characteristic ,Chemistry ,Cell Biology ,medicine.disease ,030104 developmental biology ,medicine.anatomical_structure ,symbols ,Female ,Raman spectroscopy ,Ex vivo ,Biomedical engineering - Abstract
Better knowledge of the breast tumor microenvironment is required for surgical resection and understanding the processes of tumor development. Raman spectroscopy is a promising tool that can assist in uncovering the molecular basis of disease and provide quantifiable molecular information for diagnosis and treatment evaluation. In this work, eighty-eight frozen breast tissue sections, including forty-four normal and forty-four tumor sections, were mapped in their entirety using a 250-μm-square measurement grid. Two or more smaller regions of interest within each tissue were additionally mapped using a 25 μm-square step size. A deep learning algorithm, convolutional neural network (CNN), was developed to distinguish histopathologic features with-in individual and across multiple tissue sections. Cancerous breast tissue were discriminated from normal breast tissue with 90 % accuracy, 88.8 % sensitivity and 90.8 % specificity with an excellent Area Under the Receiver Operator Curve (AUROC) of 0.96. Features that contributed significantly to the model were identified and used to generate RGB images of the tissue sections. For each grid point (pixel) on a Raman map, color was assigned to intensities at frequencies of 1002 cm−1 (Phenylalanine), 869 cm−1 (Proline, C C stretching of hydroxyproline-collagen assignment, single bond stretching vibrations for the amino acids proline, valine and polysaccharides) and 1309 cm−1 (CH3/CH2 twisting or bending mode of lipids). The Raman images clearly associate with hematoxylin and eosin stained tissue sections and allow clear visualization of boundaries between normal adipose, connective tissue and tumor. We demonstrated that this simple imaging technique allows high-resolution, straightforward molecular interpretation of Raman images. Raman spectroscopy provides rapid, label-free imaging of microscopic features with high accuracy. This method has application as laboratory tool and can assist with intraoperative tissue assessment during Breast Conserving surgery. more...
- Published
- 2020
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