Published online by Cambridge University Press: 02 July 2020
Freeze-fracture techniques have contributed much to our understanding of membrane composition and macromolecular architecture. However, further substantive contributions from freeze fracture have seemed unlikely because: a) replicas typically fragmented, destroying histological orientation within samples; b) histochemical staining techniques were thought to be incompatible with bleach- or acid-cleaned freeze-fracture replicas; c) the limit of resolution was presumed to be 3-5 nm; and d) there were no methods for directing the fracture plane to specific components within a tissue. Recent developments in “grid-mapped freeze fracture” and freeze-fracture immunocytochemistry have addressed each of these limitations.
Using grid-mapped freeze fracture, samples are mapped in three dimensions using confocal microscopy before freeze-fracture (Fig. A), as well as after replication and stabilization in Lexan plastic on a gold “Finder” grid (Fig. B). After replica cleaning, areas of interest are correlated in confocal and TEM images —— for example, cilia of the ependymal layer of rat spinal cord (Fig. C).