Showing total 12 results

1. Spatial frequency domain imager based on a compact multiaperture camera: testing and feasibility for noninvasive burn severity assessment

Author

Anthony J. Durkin, Jun Tanida, Adrien Ponticorvo, Rebecca A. Rowland, Keiichiro Kagawa, and Gordon T. Kennedy

Subjects

Paper, Materials science, genetic structures, compound eye, Multispectral image, Biomedical Engineering, Bioengineering, Optical Physics, Imaging phantom, Phantoms, law.invention, Imaging, Biomaterials, Mice, Optics, Band-pass filter, law, Opthalmology and Optometry, multispectral imaging, Animals, diffuse optics, Skin, CMOS sensor, thin observational module by bound optics, business.industry, Phantoms, Imaging, Optical Imaging, Compound eye, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Rats, Lens (optics), Wavelength, burn wounds, spatial frequency domain imaging, Feasibility Studies, Spatial frequency, sense organs, business, Burns

Abstract

Significance: Spatial frequency domain imaging (SFDI) is a wide-field imaging technique that provides quantitative maps of tissue optical properties. We describe a compact SFDI imager that employs a multispectral compound-eye camera. This design enables simultaneous image acquisition at multiple wavelengths. Such a device has potential for application for quantitative evaluation of superficial tissues by nonspecialists in low-resource settings. Aim: The aim of this work was to develop a compact SFDI imager for widefield imaging of in-vivo tissue optical properties and verify its ability to measure optical properties of tissue-simulating phantoms and in a preclinical model of burn wounds. Approach: This compound-eye imager was constructed using a CMOS sensor subdivided into multiple regions, each having a bandpass filter and objective lens. The ability of the instrument to image optical properties was compared with (1) a commercial SFDI imager and (2) a laboratory-based system. Initial validation of ability to accurately characterize optical properties was performed using a tissue-simulating optical phantom. It was then applied to an established murine model of thermal contact burn severity. In-vivo measurements of the optical properties of rat skin were performed before and after the application of burns. Histology was used to verify burn severity. Results: Measurements of the tissue-simulating phantom optical properties made using the compound-eye imager agree with measurements made using the two comparison SFDI devices. For the murine burn model, the burns showed a decrease in the reduced scattering coefficient at all measurement wavelengths compared with preburn measurements at the same locations. This is consistent with previously reported changes in scattering that occur in full-thickness burns. Conclusion: We demonstrate the potential for SFDI to be translated into compact form factor using a compound-eye camera that is capable of obtaining multiple wavelengths channels simultaneously.

Published

2021

2. Comparison of different spectral cameras for image-guided organ transplantation

Author

Anna Hilsmann, Richard Mühle, Wenke Markgraf, Peter Eisert, Eric L. Wisotzky, and Hagen Malberg

Subjects

Diagnostic Imaging, Paper, image-guided surgery, Swine, hyperspectral imaging, Computer science, Multispectral image, Biomedical Engineering, Imaging, Biomaterials, symbols.namesake, blood analysis, multispectral imaging, organ analysis, Animals, Computer vision, Ground truth, business.industry, Hyperspectral imaging, Usability, Organ Transplantation, Atomic and Molecular Physics, and Optics, Pearson product-moment correlation coefficient, Electronic, Optical and Magnetic Materials, Transplantation, Image-guided surgery, spectral camera comparison, symbols, Snapshot (computer storage), Artificial intelligence, business

Abstract

Significance: Hyperspectral and multispectral imaging (HMSI) in medical applications provides information about the physiology, morphology, and composition of tissues and organs. The use of these technologies enables the evaluation of biological objects and can potentially be applied as an objective assessment tool for medical professionals. Aim: Our study investigates HMSI systems for their usability in medical applications. Approach: Four HMSI systems (one hyperspectral pushbroom camera and three multispectral snapshot cameras) were examined and a spectrometer was used as a reference system, which was initially validated with a standardized color chart. The spectral accuracy of the cameras reproducing chemical properties of different biological objects (porcine blood, physiological porcine tissue, and pathological porcine tissue) was analyzed using the Pearson correlation coefficient. Results: All the HMSI cameras examined were able to provide the characteristic spectral properties of blood and tissues. A pushbroom camera and two snapshot systems achieve Pearson coefficients of at least 0.97 compared to the ground truth, indicating a very high positive correlation. Only one snapshot camera performs moderately to high positive correlation (0.59 to 0.85). Conclusion: The knowledge of the suitability of HMSI cameras for accurate measurement of chemical properties of biological objects offers a good opportunity for the selection of the optimal imaging tool for specific medical applications, such as organ transplantation.

Published

2021

3. Estimation of skin microcirculatory hemoglobinoxygen saturation and red blood cell tissue fractionusing a multispectral snapshot imaging system : a validation study

Author

Marcus Larsson, E. Göran Salerud, Maria Ewerlöf, and Tomas Strömberg

Subjects

Paper, Erythrocytes, Multispectral image, Medical Engineering, Biomedical Engineering, chemistry.chemical_element, Fraction (chemistry), 01 natural sciences, Oxygen, Microcirculation, Imaging, diffuse reflectance spectroscopy, Monte Carlo simulations, 010309 optics, Biomaterials, Hemoglobins, 0103 physical sciences, Linear regression, medicine, multispectral imaging, Humans, Medicinteknik, Skin, skin microcirculation, Chemistry, hemoglobin oxygen saturation, Arterial occlusion, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, RBC tissue fraction, Red blood cell, medicine.anatomical_structure, Snapshot (computer storage), Biomedical engineering

Abstract

Significance: Hemoglobin oxygen saturation and red blood cell (RBC) tissue fraction are important parameters when assessing microvascular status. Functional information can be attained using temporally resolved measurements performed during stimulus–response protocols. Pointwise assessments can currently be conducted with probe-based systems. However, snapshot multispectral imaging (MSI) can be used for spatial–temporal measurements. Aim: To validate if hemoglobin oxygen saturation and RBC tissue fraction can be quantified using a snapshot MSI system and an inverse Monte Carlo algorithm. Approach: Skin tissue measurements from the MSI system were compared to those from a validated probe-based system during arterial and venous occlusion provocation on 24 subjects in the wavelength interval 450 to 650 nm, to evaluate a wide range of hemoglobin oxygen saturation and RBC tissue fraction levels. Results: Arterial occlusion results show a mean linear regression R2 = 0.958 for hemoglobin oxygen saturation. Comparing relative RBC tissue fraction during venous occlusion results in R2 = 0.925. The MSI system shows larger dynamic changes than the reference system, which might be explained by a deeper sampling including more capacitance vessels. Conclusions: The snapshot MSI system estimates hemoglobin oxygen saturation and RBC tissue fraction in skin microcirculation showing a high correlation (R2 > 0.9 in most subjects) with those measured by the reference method. Funding: Swedens Innovation Agency VINNOVA via the programs Swelife and MedTech4Health [2017-01435, 2019-01522]; CENIIT research organization within Linkoping University [11.02]

Published

2021

4. Multispectral tissue mapping: developing a concept for the optical evaluation of liver disease

Author

Crispin Schneider, Kurinchi Selvan Gurusamy, Daniil I. Nikitichev, Brian R. Davidson, Wenfeng Xia, and Adrien E. Desjardins

Subjects

Paper, Pixel, hyperspectral imaging, business.industry, Multispectral image, Biomedical Applications in Molecular, Structural, and Functional Imaging, Hyperspectral imaging, Cancer, False color, false color imaging, medicine.disease, 030218 nuclear medicine & medical imaging, Metastasis, liver cancer, liver steatosis, 03 medical and health sciences, Liver disease, 0302 clinical medicine, 030220 oncology & carcinogenesis, multispectral imaging, Medicine, Radiology, Nuclear Medicine and imaging, business, Liver cancer, Biomedical engineering

Abstract

Purpose: Alterations in the optical absorption behavior of liver tissue secondary to pathological processes can be evaluated by multispectral analysis, which is increasingly being explored as an imaging adjunct for use in liver surgery. Current methods are either invasive or have a limited wavelength spectrum, which restricts utility. This proof of concept study describes the development of a multispectral imaging (MSI) method called multispectral tissue mapping (MTM) that addresses these issues. Approach: The imaging system consists of a tunable excitation light source and a near-infrared camera. Following the development stage, proof of concept experiments are carried out where absorption spectra from colorectal cancer liver metastasis (CRLM), hepatocellular carcinoma (HCC), and liver steatosis specimen are acquired and compared to controls. Absorption spectra are compared to histopathology examination as the current gold standard for tissue assessment. Generalized linear mixed modeling is employed to compare absorption characteristics of individual pixels and to select wavelengths for false color image processing with the aim of visually enhancing cancer tissue. Results: Analysis of individual pixels revealed distinct absorption spectra therefore suggesting that MTM is possible. A prominent absorption peak at 1210 nm was found in lipid-rich animal tissues and steatotic liver specimen. Liver cancer tissue had a heterogeneous appearance on MSI. Subsequent statistical analysis suggests that measuring changes in absorption behavior may be a feasible method to estimate the pixel-based probability of cancer being present. In CRLM, this was observed throughout 1100 to 1700 nm, whereas in HCC it was concentrated around 1140 and 1430 nm. False color image processing visibly enhances contrast between cancer and normal liver tissues. Conclusions: The system’s ability to enable no-touch MSI at 1100 to 1700 nm was demonstrated. Preliminary data suggest that MTM warrants further exploration as a potential imaging tool for the detection of liver cancer during surgery.

Published

2020

5. Validation of two techniques for intraoperative hyperspectral human tissue determination

Author

Eric L. Wisotzky, Benjamin Kossack, Philipp Arens, Anna Hilsmann, Peter Eisert, and Florian C. Uecker

Subjects

Paper, Image-Guided Procedures, Robotic Interventions, and Modeling, hyperspectral imaging, Multispectral image, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, human soft tissue, Color chart, multispectral imaging, Medicine, Radiology, Nuclear Medicine and imaging, Computer vision, Optical filter, filter-wheel setup, Ground truth, business.industry, Hyperspectral imaging, Usability, snapshot camera, Digital microscope, calibration, Visualization, tissue analysis, 030220 oncology & carcinogenesis, Artificial intelligence, business

Abstract

Purpose: Hyperspectral imaging (HSI) is a non-contact optical imaging technique with the potential to serve as an intraoperative computer-aided diagnostic tool. Our work analyzes the optical properties of visible structures in the surgical field for automatic tissue categorization. Approach: Building an HSI-based computer-aided tissue analysis system requires accurate ground truth and validation of optical soft tissue properties as these show large variability. We introduce and validate two different hyperspectral intraoperative imaging setups and their use for the analysis of optical tissue properties. First, we present an improved multispectral filter-wheel setup integrated into a fully digital microscope. Second, we present a novel setup of two hyperspectral snapshot cameras for intraoperative usage. Both setups are operating in the spectral range of 400 up to 975 nm. They are calibrated and validated using the same database and calibration set. Results: For validation, a color chart with 18 well-defined color spectra in the visual range is analyzed. Thus the results acquired with both settings become transferable and comparable to each other as well as between different interventions. On patient data of two different otorhinolaryngology procedures, we analyze the optical behaviors of different soft tissues and show a visualization of such different spectral information. Conclusion: The introduced calibration pipeline for different HSI setups allows comparison between all acquired spectral information. Clinical in vivo data underline the potential of HSI as an intraoperative diagnostic tool and the clinical usability of both introduced setups. Thereby, we demonstrate their feasibility for the in vivo analysis and categorization of different human soft tissues.

Published

2020

6. Point-of-care, multispectral, smartphone-based dermascopes for dermal lesion screening and erythema monitoring

Author

Bofan Song, Rongguang Liang, Melody Maarouf, Vivian Y. Shi, and Ross D. Uthoff

Subjects

Paper, Erythema, Point-of-Care Systems, Multispectral image, Biomedical Engineering, Image classifier, Image processing, dermatoscopy, Imaging, Biomaterials, Lesion, Digital image processing, medicine, multispectral imaging, Image Processing, Computer-Assisted, Humans, Computer vision, Point of care, Skin, Dermatoscopy, medicine.diagnostic_test, business.industry, smartphone imaging, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, mHealth, Artificial intelligence, Smartphone, medicine.symptom, dermoscopy, business

Abstract

Significance: The rates of melanoma and nonmelanoma skin cancer are rising across the globe. Due to a shortage of board-certified dermatologists, the burden of dermal lesion screening and erythema monitoring has fallen to primary care physicians (PCPs). An adjunctive device for lesion screening and erythema monitoring would be beneficial because PCPs are not typically extensively trained in dermatological care. Aim: We aim to examine the feasibility of using a smartphone-camera-based dermascope and a USB-camera-based dermascope utilizing polarized white-light imaging (PWLI) and polarized multispectral imaging (PMSI) to map dermal chromophores and erythema. Approach: Two dermascopes integrating LED-based PWLI and PMSI with both a smartphone-based camera and a USB-connected camera were developed to capture images of dermal lesions and erythema. Image processing algorithms were implemented to provide chromophore concentrations and redness measures. Results: PWLI images were successfully converted to an alternate colorspace for erythema measures, and the spectral bandwidth of the PMSI LED illumination was sufficient for mapping of deoxyhemoglobin, oxyhemoglobin, and melanin chromophores. Both types of dermascopes were able to achieve similar relative concentration results. Conclusion: Chromophore mapping and erythema monitoring are feasible with PWLI and PMSI using LED illumination and smartphone-based cameras. These systems can provide a simpler, more portable geometry and reduce device costs compared with interference-filter-based or spectrometer-based clinical-grade systems. Future research should include a rigorous clinical trial to collect longitudinal data and a large enough dataset to train and implement a machine learning-based image classifier.

Published

2020

7. Handheld multispectral imager for quantitative skin assessment in low-resource settings

Author

Hanna Jonasson, Rolf B. Saager, Luigi Belcastro, and Tomas Strömberg

Subjects

Diagnostic Imaging, Paper, skin, Materials science, low-resource settings, Multispectral image, Medical Engineering, Biomedical Engineering, phantoms, 01 natural sciences, law.invention, Digital micromirror device, 010309 optics, Biomaterials, Hemoglobins, Optics, multispectral imaging, spatial frequency domain imaging, digital micromirror device, law, 0103 physical sciences, Calibration, Special Series on Wearable, Implantable, Mobile, and Remote Biomedical Optics and Photonics, Medicinteknik, CMOS sensor, business.industry, Phantoms, Imaging, Spectrum Analysis, Spectral bands, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Projector, RGB color model, Spatial frequency, business

Abstract

Significance: Spatial frequency domain imaging (SFDI) is a quantitative imaging method to measure absorption and scattering of tissue, from which several chromophore concentrations (e.g., oxy-/deoxy-/meth-hemoglobin, melanin, and carotenoids) can be calculated. Employing a method to extract additional spectral bands from RGB components (that we named cross-channels), we designed a handheld SFDI device to account for these pigments, using low-cost, consumer-grade components for its implementation and characterization. Aim: With only three broad spectral bands (red, green, blue, or RGB), consumer-grade devices are often too limited. We present a methodology to increase the number of spectral bands in SFDI devices that use RGB components without hardware modification. Approach: We developed a compact low-cost RGB spectral imager using a color CMOS camera and LED-based mini projector. The components’ spectral properties were characterized and additional cross-channel bands were calculated. An alternative characterization procedure was also developed that makes use of low-cost equipment, and its results were compared. The device performance was evaluated by measurements on tissue-simulating optical phantoms and in-vivo tissue. The measurements were compared with another quantitative spectroscopy method: spatial frequency domain spectroscopy (SFDS). Results: Out of six possible cross-channel bands, two were evaluated to be suitable for our application and were fully characterized (520 ± 20 nm; 556 ± 18 nm). The other four cross-channels presented a too low signal-to-noise ratio for this implementation. In estimating the optical properties of optical phantoms, the SFDI data have a strong linear correlation with the SFDS data (R2 = 0.987, RMSE = 0.006 for μa, R2 = 0.994, RMSE = 0.078 for μs′). Conclusions: We extracted two additional spectral bands from a commercial RGB system at no cost. There was good agreement between our device and the research-grade SFDS system. The alternative characterization procedure we have presented allowed us to measure the spectral features of the system with an accuracy comparable to standard laboratory equipment. Funding agencies: Knut and Alice Wallenberg FoundationKnut & Alice Wallenberg Foundation

Published

2020

8. Fast visible and extended nearinfrared multispectral fundus camera

Author

Meritxell Vilaseca, Carlos Mateo, Francisco J. Burgos-Fernández, Fernando Díaz-Doutón, Tommaso Alterini, Laura González, Universitat Politècnica de Catalunya. Doctorat en Enginyeria Òptica, Universitat Politècnica de Catalunya. Centre de Desenvolupament de Sensors, Instrumentació i Sistemes, Universitat Politècnica de Catalunya. Departament d'Òptica i Optometria, and Universitat Politècnica de Catalunya. GREO - Grup de Recerca en Enginyeria Òptica

Subjects

Paper, retina, Materials science, genetic structures, Fundus Oculi, Multispectral image, Flashlight, Biomedical Engineering, Fundus (eye), Imatges -- Processament, 01 natural sciences, Retina, Imaging, 010309 optics, Biomaterials, Multispectral imaging, Fons de l'ull, Optics, Image processing, 0103 physical sciences, Image Processing, Computer-Assisted, multispectral imaging, medicine, Humans, fundus camera, Fundus camera, Spectroscopy, Near-Infrared, Retinal pigment epithelium, Pixel, business.industry, Near-infrared spectroscopy, Equipment Design, Spectral bands, Atomic and Molecular Physics, and Optics, eye diseases, Electronic, Optical and Magnetic Materials, medicine.anatomical_structure, Ciències de la visió [Àrees temàtiques de la UPC], sense organs, business

Abstract

We present a multispectral fundus camera that performs fast imaging of the ocular posterior pole in the visible and near-infrared (400 to 1300 nm) wavelengths through 15 spectral bands, using a flashlight source made of light-emitting diodes, and CMOS and InGaAs cameras. We investigate the potential of this system for visualizing occult and overlapping structures of the retina in the unexplored wavelength range beyond 900 nm, in which radiation can penetrate deeper into the tissue. Reflectance values at each pixel are also retrieved from the acquired images in the analyzed spectral range. The available spectroscopic information and the visualization of retinal structures, specifically the choroidal vasculature and drusen-induced retinal pigment epithelium degeneration, which are hardly visible in conventional color fundus images, underline the clinical potential of this system as a new tool for ophthalmic diagnosis.

Published

2019

9. Spatial frequency domain imaging: a quantitative, noninvasive tool for in vivo monitoring of burn wound and skin graft healing

Author

Melissa L. Baldado, Anthony J. Durkin, Adrien Ponticorvo, Rebecca A. Rowland, Andrew C. Kowalczewski, Robert J. Christy, Randolph Stone, Jeffrey H. Chen, Nicole P. Bernal, and Gordon T. Kennedy

Subjects

Paper, Scattering coefficient, Graft healing, Swine, Biomedical Engineering, Transplants, Context (language use), 01 natural sciences, 010309 optics, Biomaterials, burns, In vivo, 0103 physical sciences, multispectral imaging, Image Processing, Computer-Assisted, Medicine, Animals, diffuse optics, Skin, Wound Healing, Burn wound, graft viability, integumentary system, business.industry, Optical Imaging, Skin Transplantation, Domain imaging, Atomic and Molecular Physics, and Optics, 3. Good health, Electronic, Optical and Magnetic Materials, spatial frequency domain imaging, Special Section on Spatial Frequency Domain Imaging, Female, sense organs, business, Wound healing, Preclinical imaging, Biomedical engineering

Abstract

There is a need for noninvasive, quantitative methods to characterize wound healing in the context of longitudinal investigations related to regenerative medicine. Such tools have the potential to inform the assessment of wound status and healing progression and aid the development of new treatments. We employed spatial frequency domain imaging (SFDI) to characterize the changes in optical properties of tissue during wound healing progression in a porcine model of split-thickness skin grafts and also in a model of burn wound healing with no graft intervention. Changes in the reduced scattering coefficient measured using SFDI correlated with structural changes reported by histology of biopsies taken concurrently. SFDI was able to measure spatial inhomogeneity in the wounds and predicted heterogeneous healing. In addition, we were able to visualize differences in healing rate, depending on whether a wound was debrided and grafted, versus not debrided and left to heal without intervention apart from topical burn wound care. Changes in the concentration of oxy- and deoxyhemoglobin were also quantified, giving insight into hemodynamic changes during healing.

Published

2019

10. Multispectral imaging of cortical vascular and hemodynamic responses to a shock wave: observation of spreading depolarization and oxygen supply-demand mismatch

Author

Wataru Okuda, Shunichi Sato, Satoko Kawauchi, Hiroshi Nawashiro, and Izumi Nishidate

Subjects

Paper, Male, medicine.medical_specialty, Traumatic brain injury, Biomedical Engineering, Hemodynamics, chemistry.chemical_element, Brain damage, 01 natural sciences, Oxygen, light scattering, Constriction, 010309 optics, Biomaterials, Rats, Sprague-Dawley, Blast Injuries, Internal medicine, Cortex (anatomy), 0103 physical sciences, Brain Injuries, Traumatic, medicine, multispectral imaging, cortical spreading depolarization, Animals, General, Cerebral Cortex, Chemistry, Cortical Spreading Depression, Optical Imaging, Hyperoxemia, Depolarization, medicine.disease, diffuse reflectance, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Rats, medicine.anatomical_structure, blast-induced mild traumatic brain injury, Cardiology, medicine.symptom

Abstract

Blast-induced traumatic brain injury has been a recent major concern in neurotraumatology. However, its pathophysiology and mechanism are not understood partly due to insufficient information on the brain pathophysiology during/immediately after shock wave exposure. We transcranially applied a laser-induced shock wave (LISW, ∼19 Pa·s) to the left frontal region in a rat and performed multispectral imaging of the ipsilateral cortex through a cranial window (n=4). For the spectral data obtained, we conducted multiple regression analysis aided by Monte Carlo simulation to evaluate vascular diameters, regional hemoglobin concentration (rCHb), tissue oxygen saturation (StO2), oxygen extraction fraction, and light-scattering signals as a signature of cortical spreading depolarization (CSD). Immediately after LISW exposure, rCHb and StO2 were significantly decreased with distinct venular constriction. CSD was then generated and was accompanied by distinct hyperemia/hyperoxemia. This was followed by oligemia with arteriolar constriction, but it soon recovered (within ∼20 min). However, severe hypoxemia was persistently observed during the post-CSD period (∼1 h). These observations indicate that inadequate oxygen supply and/or excessive oxygen consumption continued even after blood supply was restored in the cortex. Such a hypoxemic state and/or a hypermetabolic state might be associated with brain damage caused by a shock wave.

Published

2019

11. Coregistered optical coherence tomography and frequency-encoded multispectral imaging for spectrally sparse color imaging

Author

Caroline Boudoux, Martin Poinsinet de Sivry-Houle, Xavier Attendu, and Marie Hélène Bourget

Subjects

Paper, Diagnostic Imaging, Computer science, Multispectral image, Biomedical Engineering, Color, 01 natural sciences, Multiplexing, color reconstruction, 010309 optics, Biomaterials, Optical coherence tomography, Wavelength-division multiplexing, 0103 physical sciences, multispectral imaging, medicine, Fiber Optic Technology, Computer vision, Endoscopes, optical coherence tomography, medicine.diagnostic_test, Color difference, Special Section on Biomedical Imaging and Sensing, Phantoms, Imaging, business.industry, Frequency domain multiplexing, double-clad fiber coupler, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, frequency domain multiplexing, Color imaging, Artificial intelligence, business, Structural imaging, Mathematics, Tomography, Optical Coherence

Abstract

We present a system combining optical coherence tomography (OCT) and multispectral imaging (MSI) for coregistered structural imaging and surface color imaging. We first describe and numerically validate an optimization model to guide the selection of the MSI wavelengths and their relative intensities. We then demonstrate the integration of this model into an all-fiber bench-top system. We implement frequency-domain multiplexing for the MSI to enable concurrent acquisition of both OCT and MSI at OCT acquisition rates. Such a system could be implemented in endoscopic practices to provide multimodal, high-resolution imaging of deep organ structures that are currently inaccessible to standard video endoscopes.

Published

2019

12. Noninvasive evaluation of hemodynamics and light scattering property during two-stage mouse cutaneous carcinogenesis based on multispectral diffuse reflectance images at isosbestic wavelengths of hemoglobin

Author

Satoko Kawauchi, Shunichi Sato, Md. Abdul Wares, Naoki Tobita, and Izumi Nishidate

Subjects

Paper, Skin Neoplasms, Diffuse reflectance infrared fourier transform, Biomedical Engineering, light scattering property, 01 natural sciences, Light scattering, hemoglobin concentration, 010309 optics, Biomaterials, Hemoglobins, Mice, Nuclear magnetic resonance, In vivo, 0103 physical sciences, multispectral imaging, Animals, Scattering, Radiation, two-stage carcinogenesis, Monte Carlo simulation, Skin, Isosbestic point, Special Section on Biomedical Imaging and Sensing, Chemistry, Scattering, Spectrum Analysis, Hemodynamics, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Tumor progression, Tumor promotion, sense organs, Hemoglobin

Abstract

We investigate a multispectral imaging method to evaluate spatiotemporal changes in both cutaneous hemoglobin concentration and light scattering parameter in mouse skin through diffuse reflectance spectroscopy using the reflectance images acquired at isosbestic wavelengths of hemoglobin (420, 450, 500, and 585 nm). In the proposed approach, Monte Carlo simulation-based empirical formulas are introduced to extract the scattering power b representing the wavelength dependence of light scattering spectrum of skin tissue, as well as the total hemoglobin concentration Cth in dermal vasculatures. The use of isosbestic wavelengths of hemoglobin enables the values of Cth and b to be estimated independently of the oxygenation of hemoglobin. Experiments using in vivo mice two-stage chemical carcinogenesis model are performed to confirm the feasibility of the proposed method for evaluating the changes in cutaneous vasculatures and tissue morphology during tumor initiation, promotion, and progression processes. The experimental results reveal that the changes in scattering power b of back skin are significantly reduced and followed by the increase in total hemoglobin concentration Cth in the carcinogenesis mice group, which indicates morphological changes in skin tissue such as edema and cell swelling caused by tumor promotion and successive angiogenesis along with tumor progression. The results suggest that the potential of the present method to detect cutaneous carcinogenesis in an early stage and monitor physiological changes during promotion and progression process of nonmelanoma tumors.

Published

2019