Ultrastructural cryoinjury and cryoprotection of rough endoplasmic reticulum

One phase of a study on cryosurvival and cryoprotection of mammalian cells, in terms of ultrastructural alteration of rough endoplasmic reticulum (RER) within rat pancreatic acinar cells, is presented. Small (2–3 mm) squares of tissue, 0.7–0.9 mm in thickness, were compared as unfrozen controls, with (w) and without (wo) glycerol pretreatment (15% $\text{v}\text{v}$ in mammalian Ringer's solution) at 0 °C and 22 °C (to regulate glycerol permeability); as well as parallel frozen-thawed samples, after combinations of slow (3.8 °C/min) freezing (SF) and rapid (38 °C/sec) freezing (RF) with either slow (1.5 °C/min) thawing (ST) or rapid (8 °C/sec) thawing (RT). Regimens compared were SFRT, SFST, RFRT, and RFST, all w and wo glycerol pretreatment at 0 °C and 22 °C. Tissue from each treatment was prepared for electron microscopic observations. The results on rates of freezing and thawing and relative cryoprotection of intracellular and extracellular glycerol under conditions described are intended to serve as a correlative basis for subsequent parallel studies on function (protein synthesis) and ultrastructure of the frozen state. They now indicate the following: (1) Cryoinjury of RER, which occurred during all treatments compared, was manifested in irregularity, dilatation, vesiculation, and altered matrix density of cisternae, and ribosomal derangement or disjunction. Least injury was shown by some disorientation and dilatation with increasing degrees of damage involving accentuation of these and other alterations. Such ultrastructural alterations to RER are not unique to cryoinjury, since they have been induced by treatments and agents other than freeze-thawing in experimental pathology. (2) Cryoinjury is unique, however, in that it can be regulated to demonstrate a spectrum of degrees of injury to cells and their organelles, immediately after cryoexposure. Controlled cryoinjury is suggested as a research tool for studies on injury, in general, on an ultrastructural-functional level. (3) Glycerol is injurious or toxic during pretreatment. Toxicity, which resembles cryoinjury, is greater during 22 ° C (intracellular) than 0 °C (extracellular) glycerol pretreatment, especially with respect to dilatation of cisternae. (4) Extra-cellular glycerol is cryoprotective during both slow and rapid freezing followed by either slow or rapid thawing, while little or no cryoprotection is afforded when glycerol is located simultaneously in the intracellular and extracellular location. (5) Rate of freezing is more important than rate of thawing as a factor in cryosurvival. Rapid freezing is more injurious than slow freezing, in the absence of glycerol or in the presence of extracellular glycerol, with slight or no differences seen as a function of thawing rate. Neither rate of freezing nor rate of thawing is of serious consequence when glycerol is intracellular. (6) Rate of thawing has importance after slow freezing, when slow thawing is more injurious than rapid, but not after rapid freezing, either in the presence or absence of extracellular glyeerol.