Your search keyword '"Matthew R. Kole"' showing total 3 results

1. Discrete frequency infrared microspectroscopy and imaging with a tunable quantum cascade laser

Author

Rohith Reddy, Matthew V. Schulmerich, Rohit Bhargava, Matthew R. Kole, and Matthew K. Gelber

Subjects

Microscope, business.industry, Infrared, Mercury Compounds, Bolometer, Detector, Electric Conductivity, Equipment Design, Laser, Article, Analytical Chemistry, law.invention, chemistry.chemical_compound, Optics, chemistry, law, Discrete frequency domain, Spectroscopy, Fourier Transform Infrared, Cadmium Compounds, Image Processing, Computer-Assisted, Optoelectronics, Mercury cadmium telluride, Lasers, Semiconductor, business, Quantum cascade laser

Abstract

Fourier-transform infrared imaging (FT-IR) is a well-established modality but requires the acquisition of a spectrum over a large bandwidth, even in cases where only a few spectral features may be of interest. Discrete frequency infrared (DF-IR) methods are now emerging in which a small number of measurements may provide all the analytical information needed. The DF-IR approach is enabled by the development of new sources integrating frequency selection, in particular of tunable, narrow-bandwidth sources with enough power at each wavelength to successfully make absorption measurements. Here, we describe a DF-IR imaging microscope that uses an external cavity quantum cascade laser (QCL) as a source. We present two configurations, one with an uncooled bolometer as a detector and another with a liquid nitrogen cooled Mercury Cadmium Telluride (MCT) detector and compare their performance to a commercial FT-IR imaging instrument. We examine the consequences of the coherent properties of the beam with respect to imaging and compare these observations to simulations. Additionally, we demonstrate that the use of a tunable laser source represents a distinct advantage over broadband sources when using a small aperture (narrower than the wavelength of light) to perform high-quality point mapping. The two advances highlight the potential application areas for these emerging sources in IR microscopy and imaging.

Published

2012

2. Biomedical tissue phantoms with controlled geometric and optical properties for Raman spectroscopy and tomography

Author

Michael D. Morris, Francis W. L. Esmonde-White, Blake J. Roessler, Matthew R. Kole, Karen A. Esmonde-White, and Steven A. Goldstein

Subjects

Models, Anatomic, Optical fiber, Analytical chemistry, Spectrum Analysis, Raman, Biochemistry, Light scattering, Imaging phantom, Article, Analytical Chemistry, law.invention, symbols.namesake, law, Electrochemistry, Environmental Chemistry, Animals, Fiber Optic Technology, Humans, Computer Simulation, Spectroscopy, Leg, Phantoms, Imaging, Delamination, technology, industry, and agriculture, Wrist, Biomedical tissue, equipment and supplies, Rats, body regions, symbols, Tomography, Raman spectroscopy, Tomography, X-Ray Computed, Biomedical engineering

Abstract

To support the translation of Raman spectroscopy into clinical applications, synthetic models are needed to accurately test, optimize and validate prototype fiber optic instrumentation. Synthetic models (also called tissue phantoms) are widely used for developing and testing optical instrumentation for diffuse reflectance, fluorescence, and Raman spectroscopies. While existing tissue phantoms accurately model tissue optical scattering and absorption, they do not typically model the anatomic shapes and chemical composition of tissue. Because Raman spectroscopy is sensitive to molecular composition, Raman tissue phantoms should also approximate the bulk tissue composition. We describe the fabrication and characterization of tissue phantoms for Raman tomography and spectroscopy. These phantoms have controlled chemical and optical properties, and also multilayer morphologies which approximate the appropriate anatomic shapes. Tissue phantoms were fabricated to support on-going Raman studies by simulating the human wrist and rat leg. Surface meshes (triangle patch models) were generated from computed tomography (CT) images of a human arm and rat leg. Rapid prototyping was used to print mold templates with complex geometric patterns. Plastic casting techniques used for movie special effects were adapted to fabricate molds from the rapid prototypes, and finally to cast multilayer gelatin tissue phantoms. The gelatin base was enriched with additives to model the approximate chemistry and optical properties of individual tissue layers. Additional studies were performed to determine optimal casting conditions, phantom stability, layer delamination and chemical diffusion between layers. Recovery of diffuse reflectance and Raman spectra in tissue phantoms varied with probe placement. These phantoms enable optimization of probe placement for human or rat studies. These multilayer tissue phantoms with complex geometries are shown to be stable, with minimal layer delamination and chemical diffusion.

Published

2011

3. Repeated freeze-thawing of bone tissue affects Raman bone quality measurements

Author

John David P. McElderry, Matthew R. Kole, and Michael D. Morris

Subjects

Male, Pathology, medicine.medical_specialty, Time Factors, Bone density, Proline, Biomedical Engineering, Bone tissue, Spectrum Analysis, Raman, Bone and Bones, Biomaterials, Crystallinity, symbols.namesake, Mice, Fresh Tissue, Bone Density, Freezing, medicine, Animals, Femur, Special Section on Hard-Tissue Optics and Related Methods, Bone mineral, Chemistry, Reproducibility of Results, Amides, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Mice, Inbred C57BL, medicine.anatomical_structure, Biophysics, symbols, Cortical bone, Raman microscope, Tissue Preservation, Raman spectroscopy

Abstract

The ability to probe fresh tissue is a key feature to biomedical Raman spectroscopy. However, it is unclear how Raman spectra of calcified tissues are affected by freezing. In this study, six transverse sections of femoral cortical bone were subjected to multiple freeze/thaw cycles and probed using a custom Raman microscope. Significant decreases were observed in the amide I and amide III bands starting after two freeze thaw cycles. Raman band intensities arising from proline residues of frozen tissue appeared consistent with fresh tissue after four cycles. Crystallinity values of bone mineral diminished slightly with freezing and were noticeable after only one freezing. Mineral carbonate levels did not deviate significantly with freezing and thawing. The authors recommend freezing and thawing bone tissue only once to maintain accurate results.

Published

2011