Cryopreservation of rabbit corneas in dimethyl sulfoxide.

PURPOSE To minimize the injury to endothelial cells during cryopreservation of rabbit corneas with dimethyl sulfoxide. METHODS Rabbit corneas were cryopreserved using 20% wt/wt dimethyl sulfoxide (Me2SO), added and removed in stages to maintain the osmotically induced excursions in cell volume to within +/-40% of their isotonic volume. The vehicle solution, cooling rate, and conditions of storage used were those already reported to be optimal for endothelial cell survival after exposure to low temperatures. Survival was assessed by confocal microscopy with vital staining and by the ability of the endothelium to control stromal hydration during 3 hours of normothermic perfusion. The effect of temperature of addition and removal of Me2SO (room temperature [RT] or 2 degrees C) on endothelial viability also was measured. RESULTS After thawing, all the cryopreserved corneas appeared structurally intact when assessed by vital staining and could limit stromal swelling during subsequent normothermic perfusion. Analysis of the rate of stromal swelling during the first 1.5 hours of normothermic perfusion indicated a substantial benefit when the Me2SO was removed at RT. Adding and removing the Me2SO at RT, which allowed a briefer exposure to Me2SO before cooling, resulted in better structural integrity of the endothelial layer than when the addition of cryoprotectant took place on ice. CONCLUSIONS These results demonstrate the importance of osmotic stresses in the generation of injury to corneal endothelium during cryopreservation and the possibility of eventual successful cryopreservation of this tissue.

[1]  A. Kanai,et al.  Non-contact specular microscopic observation for early response of corneal endothelium after contact lens wear. , 1996, The CLAO journal : official publication of the Contact Lens Association of Ophthalmologists, Inc.

[2]  S. Kaufman,et al.  Transient corneal stromal and endothelial changes following soft contact lens wear: a study with confocal microscopy. , 1996, The CLAO journal : official publication of the Contact Lens Association of Ophthalmologists, Inc.

[3]  A. Busza,et al.  Ethylene glycol permeation and toxicity in the rabbit common carotid artery. , 1995, Cryobiology.

[4]  W. M. Bourne,et al.  Human corneal endothelial tolerance to glycerol, dimethylsulfoxide, 1,2-propanediol, and 2,3-butanediol. , 1994, Cryobiology.

[5]  N. Ehlers,et al.  Long‐term results with organ cultured, cryopreserved human corneal grafts. Re‐examination of 17 patients , 1993, Acta ophthalmologica.

[6]  W. Armitage,et al.  Corneal tolerance of vitrifiable concentrations of propane-1,2-diol. , 1991, Cryobiology.

[7]  D. Easty,et al.  Effects of osmotic stress on rabbit corneal endothelium. , 1985, Cryobiology.

[8]  C. Hunt,et al.  Cryopreservation of the rabbit cornea: freezing with dimethyl sulphoxide in air or in medium. , 1987, Current eye research.

[9]  M. Taylor Clinical cryobiology of tissues: preservation of corneas. , 1985, Cryobiology.

[10]  M. Taylor,et al.  A new preservation solution for storage of corneas at low temperatures. , 1985, Current eye research.

[11]  C. A. Walter,et al.  Effects of electrolyte composition and pH on the structure and function of smooth muscle cooled to −79 °C in unfrozen media , 1972 .

[12]  D. Maurice,et al.  The metabolic basis to the fluid pump in the cornea , 1972, The Journal of physiology.

[13]  F. O. Mueller Short-term experiments on grafting fresh and frozen corneal tissue in dogs. , 1968, The British journal of ophthalmology.

[14]  P. Trevor-Roper,et al.  Full-thickness corneal grafts in Addis Ababa, Ethiopia. , 1967, The British journal of ophthalmology.

[15]  J. E. Robbins,et al.  Preservation of viable corneal tissue. , 1965, Cryobiology.

[16]  G. Pappas,et al.  Studies on the cornea. II. The uptake and transport of colloidal particles by the living rabbit cornea in vitro. , 1962 .