PURPOSE: To overcome the anterior corneal mosaic (ACM) phenomenon in in vivo confocal laser scanning microscopy (CLSM) and to reconstruct undistorted images of the subbasal nerve plexus (SNP), facilitating morphometric analysis in the presence of ACM ridges. METHODS: CLSM was performed in five healthy volunteers. An original image processing algorithm based on phase correlation was used to analyze and reduce motion distortions in volume scan image sequences. Three-dimensional tracing of the SNP was performed to reconstruct images containing only the SNP layer, with nerve fibers clearly visible even in ACM areas. RESULTS: Real-time mapping of the SNP revealed the presence of ridges with K-structures underneath them in all cases. The occurrence of K-structures correlated directly with development of ACM observed by slit lamp and resulted in massive deformation at the level of Bowman's membrane, seriously interfering with examination of SNP structures. The average elevation of ACM ridges was 20.6 μm (range, 8.7-34.0 μm). The novel method presented permitted reconstruction of the SNP layer in regions of ACM. CONCLUSIONS: The described method allows the precise analysis and elimination of motion artifacts in CLSM volume scans, in conjunction with the capability to reconstruct SNP structures even in the presence of severe ACM. The robustness and automation of the described algorithms require ongoing development, but this will provide a sound basis for extended studies of corneal nerve regeneration or degeneration and for use in clinical practice.
PURPOSE: To overcome the anterior corneal mosaic (ACM) phenomenon in in vivo confocal laser scanning microscopy (CLSM) and to reconstruct undistorted images of the subbasal nerve plexus (SNP), facilitating morphometric analysis in the presence of ACM ridges. METHODS: CLSM was performed in five healthy volunteers. An original image processing algorithm based on phase correlation was used to analyze and reduce motion distortions in volume scan image sequences. Three-dimensional tracing of the SNP was performed to reconstruct images containing only the SNP layer, with nerve fibers clearly visible even in ACM areas. RESULTS: Real-time mapping of the SNP revealed the presence of ridges with K-structures underneath them in all cases. The occurrence of K-structures correlated directly with development of ACM observed by slit lamp and resulted in massive deformation at the level of Bowman's membrane, seriously interfering with examination of SNP structures. The average elevation of ACM ridges was 20.6 μm (range, 8.7-34.0 μm). The novel method presented permitted reconstruction of the SNP layer in regions of ACM. CONCLUSIONS: The described method allows the precise analysis and elimination of motion artifacts in CLSM volume scans, in conjunction with the capability to reconstruct SNP structures even in the presence of severe ACM. The robustness and automation of the described algorithms require ongoing development, but this will provide a sound basis for extended studies of corneal nerve regeneration or degeneration and for use in clinical practice.
Authors: B Köhler; S Allgeier; A Bartschat; R F Guthoff; S Bohn; K-M Reichert; O Stachs; K Winter; R Mikut Journal: Ophthalmologe Date: 2017-07 Impact factor: 1.059
Authors: B S Kowtharapu; K Winter; C Marfurt; S Allgeier; B Köhler; M Hovakimyan; T Stahnke; A Wree; O Stachs; R F Guthoff Journal: Eye (Lond) Date: 2016-11-04 Impact factor: 3.775
Authors: Ahmad Kheirkhah; Rodrigo Muller; Janine Mikolajczak; Ai Ren; Ella Maria Kadas; Hanna Zimmermann; Harald Pruess; Friedemann Paul; Alexander U Brandt; Pedram Hamrah Journal: Invest Ophthalmol Vis Sci Date: 2015-09 Impact factor: 4.799