Cajal and the discovery of the Golgi method: a neuroanatomist's dream.

Abstract

This article explores the historical progression of studying neuronal connections, beginning with nineteenth-century advancements in light microscopy and histological techniques. Early methods were limited in terms of their capacity to trace neuronal connections, but a breakthrough came with Camillo Golgi's "black reaction" staining method, later refined and extensively used by Santiago Ramón y Cajal. Cajal's observations supported the Neuron Theory, which proposed that neurons communicate via specialized points of contact, contradicting the prevailing Reticular Theory of a continuous neural network, which was supported by Golgi. This contrast is particularly intriguing because, although Golgi and Cajal used the same black reaction technique and similar microscopes, their interpretations of the microscopic world diverged significantly. An important consequence of the Neuron Theory was Cajal's Law of Dynamic Polarization, which proposed that neurons generally consist of three functionally distinct regions: a receptor apparatus (dendrites and soma), an emission apparatus (axon), and a distribution apparatus (terminal axonal arborization). He applied this principle across various parts of the nervous system and to different neuron types, enabling the generation of the first detailed circuit diagrams of the brain. Cajal's observations, concepts, and theories had a profound impact-not only on researchers of his time, but also on modern neuroscience. This article reflects on the early studies of neuronal connections, highlighting the scientific climate in which Golgi and Cajal initiated their groundbreaking research.