Your search keyword '"diffuse reflectance imaging"' showing total 9 results

1. Hyperspectral Imaging as an Early Biomarker for Radiation Exposure and Microcirculatory Damage

Author

Michael S. Chin, Brian B. Freniere, Luca eLancerotto, Jorge R. Lujan-Hernandez, Jonathan H. Saleeby, Yuan Chyuan Lo, Dennis P. Orgill, Janice F. Lalikos, and Thomas J. Fitzgerald

Subjects

Perfusion Imaging, Radiation Dosage, Radiation Effects, hyperspectral imaging, Radiation exposure, diffuse reflectance imaging, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

BACKGROUND: Radiation exposure can lead to detrimental effects in skin microcirculation. The precise relationship between radiation dose received and its effect on cutaneous perfusion still remains controversial. Previously, we have shown that hyperspectral imaging (HSI) is able to demonstrate long-term reductions in cutaneous perfusion secondary to chronic microvascular injury. This study characterizes the changes in skin microcirculation in response to varying doses of ionizing radiation and investigates these microcirculatory changes as a possible early non-invasive biomarker that may correlate with the extent of long-term microvascular damage.METHODS: Immunocompetent hairless mice (n=66) were exposed to single fractions of superficial beta-irradiation in doses of 0, 5, 10, 20, 35, or 50 Gy. A HSI device was utilized to measure deoxygenated hemoglobin levels in irradiated and control areas. HSI measurements were performed at baseline before radiation exposure and for the first three days post-irradiation. Maximum macroscopic skin reactions were graded, and histological assessment of cutaneous microvascular densities at four weeks post-irradiation was performed in harvested tissue by CD31 immunohistochemistry.RESULTS: CD31 immunohistochemistry demonstrated a significant correlation (r=0.90, p

Published

2015

2. Hyperspectral imaging as an early biomarker for radiation exposure and microcirculatory damage.

Author

Chin, Michael S., Saleeby, Jonathan H., Yuan-Chyuan Lo, Fitzgerald, Thomas J., Freniere, Brian B., Lancerotto, Luca, Orgill, Dennis P., Lujan-Hernandez, Jorge, and Lalikos, Janice F.

Subjects

RADIATION exposure, HYPERSPECTRAL imaging systems, EFFECT of radiation on skin

Abstract

Background: Radiation exposure can lead to detrimental effects in skin microcirculation. The precise relationship between radiation dose received and its effect on cutaneous perfusion still remains controversial. Previously, we have shown that hyperspectral imaging (HSI) is able to demonstrate long-term reductions in cutaneous perfusion secondary to chronic microvascular injury. This study characterizes the changes in skin microcirculation in response to varying doses of ionizing radiation and investigates these microcirculatory changes as a possible early non-invasive biomarker that may correlate with the extent of long-term microvascular damage. Methods: Immunocompetent hairless mice (n=66) were exposed to single fractions of superficial beta-irradiation in doses of 0, 5, 10, 20, 35, or 50 Gy. A HSI device was utilized to measure deoxygenated hemoglobin levels in irradiated and control areas. HSI measurements were performed at baseline before radiation exposure and for the first 3 days post-irradiation. Maximum macroscopic skin reactions were graded, and histological assessment of cutaneous microvascular densities at 4 weeks post-irradiation was performed in harvested tissue by CD31 immunohistochemistry. Results: CD31 immunohistochemistry demonstrated a significant correlation (r =0.90, p<0.0001) between dose and vessel density reduction at 4 weeks. Using HSI analysis, early changes in deoxygenated hemoglobin levels were observed during the first 3 days post-irradiation in all groups. These deoxygenated hemoglobin changes varied proportionally with dose (r =0.98, p<0.0001) and skin reactions (r =0.98, p<0.0001). There was a highly significant correlation (r =0.91, p<0.0001) between these early changes in deoxygenated hemoglobin and late vascular injury severity assessed at the end of 4 weeks. Conclusion: Radiation dose is directly correlated with cutaneous microvascular injury severity at 4 weeks in our model. Early post-exposure measurement of cutaneous deoxygenated hemoglobin levels may be a useful biomarker for radiation dose reconstruction and predictor for chronic microvascular injury. [ABSTRACT FROM AUTHOR]

Published

2015

3. Quantitative Multispectral Imaging Differentiates Melanoma from Seborrheic Keratosis

Author

Marta Lange, Szabolcs Bozsányi, Ilze Lihacova, Alexey Lihachev, Luca Fésűs, Norbert Kiss, Antal Jobbágy, K. Farkas, Kende Lőrincz, Márta Medvecz, András Bánvölgyi, Norbert Wikonkál, Dmitrijs Bliznuks, Sara Zakarias, and Pálma Anker

Subjects

Seborrheic keratosis, Medicine (General), diagnosis, Clinical Biochemistry, Multispectral image, 01 natural sciences, Article, autofluorescence imaging, 010309 optics, 030207 dermatology & venereal diseases, 03 medical and health sciences, R5-920, 0302 clinical medicine, diffuse reflectance imaging, 0103 physical sciences, melanoma, Medicine, Led illumination, quantitative analysis, business.industry, Melanoma, LED, Benign lesion, medicine.disease, Intensity (physics), Autofluorescence, seborrheic keratosis, dermoscopy, Imaging technique, business, Nuclear medicine

Abstract

Melanoma is a melanocytic tumor that is responsible for the most skin cancer-related deaths. By contrast, seborrheic keratosis (SK) is a very common benign lesion with a clinical picture that may resemble melanoma. We used a multispectral imaging device to distinguish these two entities, with the use of autofluorescence imaging with 405 nm and diffuse reflectance imaging with 525 and 660 narrow-band LED illumination. We analyzed intensity descriptors of the acquired images. These included ratios of intensity values of different channels, standard deviation and minimum/maximum values of intensity of the lesions. The pattern of the lesions was also assessed with the use of particle analysis. We found significantly higher intensity values in SKs compared with melanoma, especially with the use of the autofluorescence channel. Moreover, we found a significantly higher number of particles with high fluorescence in SKs. We created a parameter, the SK index, using these values to differentiate melanoma from SK with a sensitivity of 91.9% and specificity of 57.0%. In conclusion, this imaging technique is potentially applicable to distinguish melanoma from SK based on the analysis of various quantitative parameters. For this application, multispectral imaging could be used as a screening tool by general physicians and non-experts in the everyday practice.

Published

2021

4. Diagnostic accuracy of diffuse reflectance imaging for early detection of pre-malignant and malignant changes in the oral cavity: a feasibility study.

Author

Stephen, Manju M., Jayanthi, Jayaraj L., Unni, Nisha G., Kolady, Philip E., Beena, Valappil T., Jeemon, Panniyammakal, and Subhash, Narayanan

Subjects

*REFLECTANCE spectroscopy, *DENTAL caries, *CYTOLOGY, *EXTRACELLULAR matrix, *HISTOPATHOLOGY

Abstract

Background: Diffusely reflected light is influenced by cytologic and morphologic changes that take place during tissue transformation, such as, nuclear changes, extracellular matrix structure and composition as well as blood flow. Albeit with varying degree of sensitivity and specificity, the properties of diffusely reflected light in discriminating a variety of oral lesions have been demonstrated by our group in multiple studies using point monitoring systems. However, the point monitoring system could not identify the region with the most malignant potential in a single sitting. Methods: In order to scan the entire lesion, we developed a multi-spectral imaging camera system that records diffuse reflectance (DR) images of the oral lesion at 545 and 575 nm with white light illumination. The diagnostic accuracy of the system for 2-dimensional DR imaging of pre-malignant and malignant changes in the oral cavity was evaluated through a clinical study in 55 patients and 23 healthy volunteers. The DR imaging data were compared with gold standard tissue biopsy and histopathology results. Results: In total 106- normal/clinically healthy sites, 20- pre-malignant and 29- malignant (SCC) sites were compared. While the median pixel value of the R545/R575 image ratio for normal/clinically healthy tissue was 0.87 (IQR = 0.82-0.94), they were 1.35 (IQR = 1.13-1.67) and 2.44 (IQR = 1.78-3.80) for pre-malignant and malignant lesions, respectively. Area under the ROC curve to differentiate malignant from normal/clinically healthy [AUC = 0.99 (95% CI: 0.99-1.00)], pre-malignant from normal/clinically healthy [AUC = 0.94 (95% CI: 0.86-1.00)], malignant from pre-malignant [AUC = 0.84 (95% CI: 0.73-0.95)] and pre-malignant and malignant from normal/clinically healthy [AUC = 0.97 (95% CI: 0.94-1.00)] lesions were desirable. Conclusion: We find DR imaging to be very effective as a screening tool in locating the potentially malignant areas of oral lesions with relatively good diagnostic accuracy while comparing it to the gold standard histopathology. [ABSTRACT FROM AUTHOR]

Published

2013

5. Optical Imaging Modalities for Biomedical Applications.

Author

Dhawan, Atam P., D'Alessandro, Brian, and Fu, Xiaolei

Abstract

Optical photographic imaging is a well known imaging method that has been successfully translated into biomedical applications such as microscopy and endoscopy. Although several advanced medical imaging modalities are used today to acquire anatomical, physiological, metabolic, and functional information from the human body, optical imaging modalities including optical coherence tomography, confocal microscopy, multiphoton microscopy, multispectral endoscopy, and diffuse reflectance imaging have recently emerged with significant potential for non-invasive, portable, and cost-effective imaging for biomedical applications spanning tissue, cellular, and molecular levels. This paper reviews methods for modeling the propagation of light photons in a biological medium, as well as optical imaging from organ to cellular levels using visible and near-infrared wavelengths for biomedical and clinical applications. [ABSTRACT FROM PUBLISHER]

Published

2010

6. Autofluorescence Imaging of the Skin Is an Objective Non-Invasive Technique for Diagnosing Pseudoxanthoma Elasticum

Author

Luca Fésűs, Norbert Wikonkál, Tamas Aranyi, Alexey Lihachev, Pálma Anker, Dóra Plázár, Sara Zakarias, András Bánvölgyi, Norbert Kiss, Márta Medvecz, Marta Lange, Szabolcs Bozsányi, Ilze Lihacova, and K. Farkas

Subjects

Pathology, medicine.medical_specialty, Diagnostic methods, diagnosis, Uninvolved skin, Clinical Biochemistry, 01 natural sciences, Article, autofluorescence imaging, calcification, 010309 optics, 030207 dermatology & venereal diseases, 03 medical and health sciences, 0302 clinical medicine, diffuse reflectance imaging, 0103 physical sciences, medicine, pseudoxanthoma elasticum, Skin manifestations, lcsh:R5-920, quantitative analysis, integumentary system, business.industry, LED, Non invasive, medicine.disease, Pseudoxanthoma elasticum, Connective tissue disease, Autofluorescence, dermoscopy, lcsh:Medicine (General), business, Calcification

Abstract

Pseudoxanthoma elasticum (PXE) is a rare multisystemic autosomal recessive connective tissue disease. In most cases, skin manifestations of PXE are the first to develop, followed later by severe ocular and cardiovascular complications. In our present study, in addition to dermoscopy, we introduced novel techniques, autofluorescence (AF) and diffuse reflectance (DR) imaging for the assessment of affected skin sites of five PXE patients. PXE-affected skin areas in most skin sites showed a previously observed pattern upon dermoscopic examination. With the novel imaging, PXE-affected skin lesions displayed high AF intensity. During our measurements, significantly higher mean, minimum and maximum AF intensity values were found in areas of PXE-affected skin when compared to uninvolved skin. Conversely, images acquired with the use of 660 and 940 nm illumination showed no mentionable difference. Our results demonstrate that AF imaging may be used in the in vivo diagnostics and quantification of the severity of the skin lesions of PXE patients. In addition, it is a safe, fast and cost-effective diagnostic method. AF imaging may be also used to objectively monitor the efficacy of the possible novel therapeutic approaches of PXE in the future.

Published

2021

7. Quantitative Multispectral Imaging Differentiates Melanoma from Seborrheic Keratosis.

Author

Bozsányi, Szabolcs, Farkas, Klára, Bánvölgyi, András, Lőrincz, Kende, Fésűs, Luca, Anker, Pálma, Zakariás, Sára, Jobbágy, Antal, Lihacova, Ilze, Lihachev, Alexey, Lange, Marta, Bliznuks, Dmitrijs, Medvecz, Márta, Kiss, Norbert, and Wikonkál, Norbert M.

Subjects

*MULTISPECTRAL imaging, *KERATOSIS, *BIOFLUORESCENCE, *MELANOMA, *PHYSICIANS, *SENSITIVITY & specificity (Statistics), *PARTICLE analysis

Abstract

Melanoma is a melanocytic tumor that is responsible for the most skin cancer-related deaths. By contrast, seborrheic keratosis (SK) is a very common benign lesion with a clinical picture that may resemble melanoma. We used a multispectral imaging device to distinguish these two entities, with the use of autofluorescence imaging with 405 nm and diffuse reflectance imaging with 525 and 660 narrow-band LED illumination. We analyzed intensity descriptors of the acquired images. These included ratios of intensity values of different channels, standard deviation and minimum/maximum values of intensity of the lesions. The pattern of the lesions was also assessed with the use of particle analysis. We found significantly higher intensity values in SKs compared with melanoma, especially with the use of the autofluorescence channel. Moreover, we found a significantly higher number of particles with high fluorescence in SKs. We created a parameter, the SK index, using these values to differentiate melanoma from SK with a sensitivity of 91.9% and specificity of 57.0%. In conclusion, this imaging technique is potentially applicable to distinguish melanoma from SK based on the analysis of various quantitative parameters. For this application, multispectral imaging could be used as a screening tool by general physicians and non-experts in the everyday practice. [ABSTRACT FROM AUTHOR]

Published

2021

8. Autofluorescence Imaging of the Skin Is an Objective Non-Invasive Technique for Diagnosing Pseudoxanthoma Elasticum.

Author

Farkas, Klára, Bozsányi, Szabolcs, Plázár, Dóra, Bánvölgyi, András, Fésűs, Luca, Anker, Pálma, Zakariás, Sára, Lihacova, Ilze, Lihachev, Alexey, Lange, Marta, Arányi, Tamás, Wikonkál, Norbert M., Medvecz, Márta, Kiss, Norbert, Tatu, Alin Laurentiu, and Nwabudike, Lawrence Chukwudi

Subjects

*SKIN imaging, *BIOFLUORESCENCE, *CONNECTIVE tissue diseases, *CUTANEOUS manifestations of general diseases, *CARDIOLOGICAL manifestations of general diseases

Abstract

Pseudoxanthoma elasticum (PXE) is a rare multisystemic autosomal recessive connective tissue disease. In most cases, skin manifestations of PXE are the first to develop, followed later by severe ocular and cardiovascular complications. In our present study, in addition to dermoscopy, we introduced novel techniques, autofluorescence (AF) and diffuse reflectance (DR) imaging for the assessment of affected skin sites of five PXE patients. PXE-affected skin areas in most skin sites showed a previously observed pattern upon dermoscopic examination. With the novel imaging, PXE-affected skin lesions displayed high AF intensity. During our measurements, significantly higher mean, minimum and maximum AF intensity values were found in areas of PXE-affected skin when compared to uninvolved skin. Conversely, images acquired with the use of 660 and 940 nm illumination showed no mentionable difference. Our results demonstrate that AF imaging may be used in the in vivo diagnostics and quantification of the severity of the skin lesions of PXE patients. In addition, it is a safe, fast and cost-effective diagnostic method. AF imaging may be also used to objectively monitor the efficacy of the possible novel therapeutic approaches of PXE in the future. [ABSTRACT FROM AUTHOR]

Published

2021

9. Hyperspectral Imaging as an Early Biomarker for Radiation Exposure and Microcirculatory Damage

Author

Janice F. Lalikos, Jorge Lujan-Hernandez, Michael S. Chin, Thomas J. Fitzgerald, Yuan-Chyuan Lo, Brian B. Freniere, Jonathan Saleeby, Dennis P. Orgill, and Luca Lancerotto

Subjects

CD31, Cancer Research, Pathology, medicine.medical_specialty, business.industry, hyperspectral imaging, Perfusion Imaging, Radiation exposure, Perfusion scanning, Radiation Dosage, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, lcsh:RC254-282, Ionizing radiation, Microcirculation, microcirculatory damage, Radiation Effects, Oncology, diffuse reflectance imaging, medicine, Biomarker (medicine), Immunohistochemistry, Deoxygenated Hemoglobin, business, Perfusion, Original Research

Abstract

BACKGROUND: Radiation exposure can lead to detrimental effects in skin microcirculation. The precise relationship between radiation dose received and its effect on cutaneous perfusion still remains controversial. Previously, we have shown that hyperspectral imaging (HSI) is able to demonstrate long-term reductions in cutaneous perfusion secondary to chronic microvascular injury. This study characterizes the changes in skin microcirculation in response to varying doses of ionizing radiation and investigates these microcirculatory changes as a possible early non-invasive biomarker that may correlate with the extent of long-term microvascular damage. METHODS: Immunocompetent hairless mice (n=66) were exposed to single fractions of superficial beta-irradiation in doses of 0, 5, 10, 20, 35, or 50 Gy. A HSI device was utilized to measure deoxygenated hemoglobin levels in irradiated and control areas. HSI measurements were performed at baseline before radiation exposure and for the first three days post-irradiation. Maximum macroscopic skin reactions were graded, and histological assessment of cutaneous microvascular densities at four weeks post-irradiation was performed in harvested tissue by CD31 immunohistochemistry. RESULTS: CD31 immunohistochemistry demonstrated a significant correlation (r=0.90, p

Published

2015