Noninvasive corneal stromal collagen imaging using two‐photon‐generated second‐harmonic signals

PURPOSE: To investigate the feasibility of using femtosecond‐pulse lasers to produce second‐harmonic generated (SHG) signals to noninvasively assess corneal stromal collagen organization. SETTING: The Eye Institute, University of California, Irvine, California, USA. METHODS: Mouse, rabbit, and human corneas were examined by two‐photon confocal microscopy using a variable‐wavelength femtosecond lasers to produce SHG signals. Two types were detected: forward scattered and backward scattered. Wavelength dependence of the SHG signal was confirmed by spectral separation using the 510 Meta (Zeiss). To verify the spatial relation between SHG signals and corneal cells, staining of cytoskeletons and nuclei was performed. RESULTS: Second‐harmonic‐generated signal intensity was strongest with an excitation wavelength of 800 nm for all 3 species. Second‐harmonic‐generated forward signals showed a distinct fibrillar pattern organized into bands suggesting lamellae, while backscattered SHG signals appeared more diffuse and indistinct. Reconstruction of SHG signals showed two patterns of lamellar organization: highly interwoven in the anterior stroma and orthogonally arranged in the posterior stroma. Unique to the human cornea was the presence of transverse, sutural lamellae that inserted into Bowman's layer, suggesting an anchoring function. CONCLUSIONS: Using two‐photon confocal microscopy to generate SHG signals from the corneal collagen provides a powerful new approach to noninvasively study corneal structure. Human corneas had a unique organizational pattern with sutural lamellae to provide important biomechanical support that was not present in mouse or rabbit corneas.

[1]  G. Vrensen,et al.  The specific architecture of the anterior stroma accounts for maintenance of corneal curvature , 2001, The British journal of ophthalmology.

[2]  G. Benedek,et al.  The relationship between morphology and transparency in the nonswelling corneal stroma of the shark. , 1967, Investigative ophthalmology.

[3]  M Deutsch,et al.  Connective tissue polarity. Optical second-harmonic microscopy, crossed-beam summation, and small-angle scattering in rat-tail tendon. , 1986, Biophysical journal.

[4]  D. Maurice,et al.  Cohesive strength of corneal lamellae. , 1990, Experimental eye research.

[5]  Y. Pouliquen,et al.  Ultrastructural study of the posterior cornea of the dogfish "Scyliorhinus canicula L". , 1985, Cornea.

[6]  M. Zehetmayer,et al.  Interlacing and Cross‐Angle Distribution of Collagen Lamellae in the Human Cornea , 1998, Cornea.

[7]  A. Bron The architecture of the corneal stroma , 2001, The British journal of ophthalmology.

[8]  E. Pels,et al.  A new three-dimensional model of the organization of proteoglycans and collagen fibrils in the human corneal stroma. , 2003, Experimental eye research.

[9]  P. Binder,et al.  High-voltage electron microscopy of normal human cornea. , 1991, Investigative ophthalmology & visual science.

[10]  R. D. Stulting,et al.  Risk factors and prognosis for corneal ectasia after LASIK. , 2002, Ophthalmology.

[11]  Meng Han,et al.  Second-harmonic imaging of cornea after intrastromal femtosecond laser ablation. , 2004, Journal of biomedical optics.

[12]  K. Meek,et al.  X-ray scattering used to map the preferred collagen orientation in the human cornea and limbus. , 2004, Structure.

[13]  G. Vrensen,et al.  Novel aspects of the ultrastructural organization of human corneal keratocytes. , 1995, Investigative ophthalmology & visual science.

[14]  Bruce J Tromberg,et al.  Selective corneal imaging using combined second-harmonic generation and two-photon excited fluorescence. , 2002, Optics letters.

[15]  Leslie M Loew,et al.  Second-harmonic imaging microscopy for visualizing biomolecular arrays in cells, tissues and organisms , 2003, Nature Biotechnology.

[16]  W. Webb,et al.  Multiphoton microscopy in biological research. , 2001, Current opinion in chemical biology.

[17]  B. Tromberg,et al.  Imaging cells and extracellular matrix in vivo by using second-harmonic generation and two-photon excited fluorescence , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[18]  G. Kymionis,et al.  Corneal ectasia induced by laser in situ keratomileusis , 2001, Journal of cataract and refractive surgery.

[19]  T. Ushiki,et al.  The three-dimensional organization of collagen fibrils in the human cornea and sclera. , 1991, Investigative ophthalmology & visual science.

[20]  B. Hochheimer,et al.  Second harmonic light generation in the rabbit cornea. , 1982, Applied optics.

[21]  Paul J Campagnola,et al.  Second harmonic generation imaging of endogenous structural proteins. , 2003, Methods.

[22]  F. Bettelheim,et al.  The hydration of proteoglycans of bovine cornea. , 1975, Biochimica et biophysica acta.

[23]  Craig Boote,et al.  Lamellar orientation in human cornea in relation to mechanical properties. , 2005, Journal of structural biology.

[24]  M. Smolek,et al.  Interlamellar adhesive strength in human eyebank corneas. , 1990, Investigative ophthalmology & visual science.

[25]  Beop-Min Kim,et al.  Polarization-dependent optical second-harmonic imaging of a rat-tail tendon. , 2002, Journal of biomedical optics.

[26]  Michael D Twa,et al.  Characteristics of Corneal Ectasia After LASIK for Myopia , 2004, Cornea.