A new technique for removal of amorphous phase tissue water without ice crystal damage: a preparative method for ultrastructural analysis and immunoelectron microscopy.

Abstract

An apparatus has been produced that can remove amorphous phase tissue water via molecular distillation without devitrification or rehydration. This method represents a fundamental advance in tissue preparation, making possible for the first time ultrastructural localization of soluble molecular entities without the problems of alteration, re-distribution, and loss which have plagued conventional techniques. Fresh slices of rat brain, liver, or kidney, and monkey retinal tissue were cryofixed by bounce-free, metal mirror cooling on copper bars immersed in liquid nitrogen (LN2). Tissue transferred under LN2 was then placed in a precooled copper specimen block, which was subsequently lowered into a LN2-cooled stainless steel chamber. After rough pumping at 1 X 10(-3) mbar with a mechanical pump to remove LN2, the chamber was evacuated with a cryopump or turbomolecular pump to achieve a hydrocarbon-free, ultra-high vacuum of 1 X 10(-8) mbar. Equilibrium temperature in the chamber before the drying cycle was -192 degrees C. The copper specimen block was equipped with a thermocouple and a programmable feedback-controlled heating circuit. Tissue was dried by increasing the specimen block temperature 1 degree C/hr during the critical drying phase while monitoring the rate of water removal with a partial pressure analyzer. Results obtained indicate that drying is complete below the devitrification temperature of amorphous phase tissue water. Dried tissue was fixed with osmium tetroxide vapor, vacuum-embedded in a low-viscosity epoxy resin, sectioned, stained, and viewed with the electron microscope. Processed tissue exhibits excellent morphological preservation without the use of pre-fixation or cryoprotective agents. Thin sections of this tissue are excellent for immunocytochemical staining and electron microprobe analysis.