Your search keyword '"tissue water content interactions"' showing total 2 results

1. THz and mm-Wave Sensing of Corneal Tissue Water Content: in Vivo Sensing and Imaging Results

Author

Taylor, Zachary D, Garritano, James, Sung, Shijun, Bajwa, Neha, Bennett, David B, Nowroozi, Bryan, Tewari, Priyamvada, Sayre, James W, Hubschman, Jean-Pierre, Deng, Sophie X, Brown, Elliott R, and Grundfest, Warren S

Subjects

Biological and medical imaging, clinical instruments, medical diagnostics, tissue water content interactions, Optical Physics, Electrical and Electronic Engineering

Abstract

A pulsed terahertz (THz) imaging system and millimeter-wave reflectometer were used to acquire images and point measurements, respectively, of five rabbit cornea in vivo. These imaging results are the first ever produced of in vivo cornea. A modified version of a standard protocol using a gentle stream of air and a Mylar window was employed to slightly dehydrate healthy cornea. The sensor data and companion central corneal thickness (CCT) measurements were acquired every 10-15 min over the course of two hours using ultrasound pachymmetry.. Statistically significant positive correlations were established between CCT measurements and millimeter wave reflectivity. Local shifts in reflectivity contrast were observed in the THz imagery; however, the THz reflectivity did not display a significant correlation with thickness in the region probed by the 100 GHz and CCT measurements. This is explained in part by a thickness sensitivity at least 10× higher in the mm-wave than the THz systems. Stratified media and effective media modeling suggest that the protocol perturbed the thickness and not the corneal tissue water content (CTWC). To further explore possible etalon effects, an additional rabbit was euthanized and millimeter wave measurements were obtained during death induced edema. These observations represent the first time that the uncoupled sensing of CTWC and CCT have been achieved in vivo.

Published

2015

2. THz and mm-Wave Sensing of Corneal Tissue Water Content: In Vivo Sensing and Imaging Results

Author

Sophie X. Deng, Neha Bajwa, Elliott R. Brown, Bryan Nowroozi, Warren S. Grundfest, James Garritano, Shijun Sung, David B. Bennett, James Sayre, Zachary Taylor, Priyamvada Tewari, and Jean-Pierre Hubschman

Subjects

Radiation, Materials science, business.industry, Terahertz radiation, Ultrasound, Optical Physics, Article, eye diseases, clinical instruments, medical diagnostics, medicine.anatomical_structure, Optics, Corneal edema, In vivo, Cornea, Extremely high frequency, medicine, sense organs, Electrical and Electronic Engineering, business, Biological and medical imaging, Water content, tissue water content interactions, Fabry–Pérot interferometer

Abstract

A pulsed terahertz (THz) imaging system and millimeter-wave reflectometer were used to acquire images and point measurements, respectively, of five rabbit cornea in vivo. These imaging results are the first ever produced of in vivo cornea. A modified version of a standard protocol using a gentle stream of air and a Mylar window was employed to slightly dehydrate healthy cornea. The sensor data and companion central corneal thickness (CCT) measurements were acquired every 10–15 min over the course of two hours using ultrasound pachymmetry.. Statistically significant positive correlations were established between CCT measurements and millimeter wave reflectivity. Local shifts in reflectivity contrast were observed in the THz imagery; however, the THz reflectivity did not display a significant correlation with thickness in the region probed by the 100 GHz and CCT measurements. This is explained in part by a thickness sensitivity at least 10 $\times$ higher in the mm-wave than the THz systems. Stratified media and effective media modeling suggest that the protocol perturbed the thickness and not the corneal tissue water content (CTWC). To further explore possible etalon effects, an additional rabbit was euthanized and millimeter wave measurements were obtained during death induced edema. These observations represent the first time that the uncoupled sensing of CTWC and CCT have been achieved in vivo.

Published

2015