Ultrastructure of the frog retina after high-pressure freezing and freeze substitution.

Abstract

In many types of tissue, high-pressure freezing (HPF), followed by freeze substitution, can produce excellent ultrastructural preservation at depths over 10 times that obtained by other cryofixation techniques. However, in the case of neural tissue, the benefits of HPF have not been realized. In the present study, isolated frog (Rana pipiens) retina was sliced at a thickness of 150 or 350 microns, rapidly frozen in a Balzers HPM 010 high-pressure freezer, and freeze substituted with 1% OsO4 and 0.1% tannic acid in acetone. Specially designed HPF chambers and specific freezing media (35% high-MW dextran for 150-micron slices or 15% low-MW dextran for 350-micron slices) were required for adequate freezing. The quality of preservation after HPF was excellent throughout the retina in both the 150- and 350-micron slices, compared with chemically fixed slices. Specifically, HPF resulted in better preserved cellular, mitochondrial and nuclear membranes in all retinal layers. This is the first study to successfully cryofix all of the layers of the retina. The increased depths of adequate freezing achieved by HPF should facilitate various ultrastructural studies of retina, as well as of other CNS tissues, where preservation approaching that of the 'native' state is required.