Fact-checked by Grok 2 weeks ago

Golgi's method

Golgi's method, also known as the black reaction, is a pioneering histological staining technique invented by Italian physician and pathologist Camillo Golgi in 1873 while working at the Hospital of the Chronically Ill in Abbiategrasso, near Milan. Golgi briefly described the method in a short note that year. This method involves fixing small blocks of nervous tissue in a solution of potassium dichromate for several days to weeks, followed by immersion in silver nitrate, which precipitates silver chromate microparticles that selectively impregnate and stain only a sparse, random subset (typically 1-5%) of neurons black against a light yellow background. The result is a high-contrast visualization of entire individual neurons, including their cell bodies, dendrites, axons, and fine structures like dendritic spines, in three-dimensional detail without significant overlap from surrounding cells. This selective impregnation mechanism, though not fully understood even today, revolutionized the study of neural morphology by enabling unprecedented clarity in observing the intricate architecture of the nervous system. The technique's development marked a critical advancement in , as prior methods like those using or hematoxylin dyes could only reveal coarse outlines of cells and failed to delineate full neuronal processes. Golgi first applied it to study the , publishing detailed findings in 1875 that included drawings of neural structures, and it quickly became a cornerstone for neuroanatomical research. Notably, neuroscientist adopted and refined the method in the late , using it to produce seminal illustrations that provided empirical support for the doctrine—the idea that the comprises discrete, interconnected cells rather than a continuous reticulum. This work contributed to Golgi and Cajal sharing the 1906 in or , underscoring the method's transformative impact. Beyond neurons, Golgi's method facilitated the 1898 discovery of the Golgi apparatus, an organelle involved in protein modification and transport, when Golgi observed its perinuclear network in nerve cells stained via the technique. Variations, such as the Golgi-Cox method (which incorporates mercury chloride for enhanced stability), have extended its utility to modern studies of brain tissue in rodents and humans, including analyses of dendritic arborization in neurodegenerative diseases. Despite challenges like variability in staining outcomes and the need for thick sections (150-200 μm), the method remains valued for its ability to reveal holistic cellular morphology, influencing contemporary techniques in and .

History and Development

Discovery by

, an Italian physician and histologist, was born in 1843 in Corteno near and graduated in medicine from the in 1865, where he later established his career in histological research. In 1872, Golgi became chief medical officer at the Hospital of the Chronically Ill in Abbiategrasso, near , where he improvised a makeshift laboratory in a small room of the hospital (often described as a kitchen) to conduct independent experiments on the structure of the , driven by the limitations of contemporary staining techniques that only partially colored cellular components, preventing visualization of entire neurons. In 1873, Golgi developed his revolutionary silver staining method, known as the "black reaction," through experiments conducted by candlelight in his dimly lit kitchen laboratory. He first applied the technique to sections of the , where immersion in a solution after fixation with resulted in the complete blackening of select nerve cells against a clear background, revealing their full including dendrites and axons. This breakthrough addressed his frustration with prior methods, such as those using or hematoxylin, which fragmented the and obscured holistic neuronal architecture. Golgi detailed his discovery in a preliminary communication titled "Sulla struttura della sostanza grigia del cervello" (On the Structure of the Gray Matter of the Brain), published that same year in the Gazzetta Medica Italiana-Lombardia. In this short note, he described the impregnation process and presented initial observations of impregnated Purkinje cells in the , marking the method's debut in and laying the foundation for advanced neuroanatomical studies.

Evolution and Recognition

Following its initial description, Golgi continued to refine the method through a series of publications in the , applying it to detailed studies of neural structures in the and , which helped establish its reliability for visualizing complex neuronal morphologies. A significant advancement came in 1891 when introduced the "rapid Golgi" variant, which shortened the processing time by fixing tissue in a mixture of and , followed by , for more consistent and reproducible impregnation of individual neurons. This modification addressed the original method's variability due to the unstable silver chromate precipitate, making it more accessible for widespread histological research. The method gained rapid adoption in the late 1880s and 1890s, particularly after Cajal began using it in 1888 to produce groundbreaking illustrations of neurons in the cerebellar cortex and other regions, demonstrating the discrete nature of neural elements. Cajal's adaptations and applications propelled the technique's popularity among European neuroanatomists, leading to its integration into studies of neuronal connectivity across species by the mid-1890s. However, the method also fueled scientific debate, as Golgi interpreted the impregnated networks as evidence for his reticular theory, positing a continuous syncytial structure in the nervous system, while Cajal used the same stainings to support the neuron doctrine, emphasizing independent cells with contact-based communication. This initial ambiguity in interpretations—stemming from the method's selective staining—highlighted its dual role in advancing and challenging early neuroscientific paradigms. The contributions of Golgi's method culminated in international recognition when Camillo Golgi shared the 1906 Nobel Prize in Physiology or Medicine with Santiago Ramón y Cajal "in recognition of their work on the structure of the nervous system." Golgi's Nobel lecture emphasized the method's role in revealing the intricate architecture of nerve cells, underscoring its transformative impact on histology despite the ongoing theoretical rift with Cajal. This award not only honored the technique's foundational influence but also marked a pivotal moment in neuroscience, bridging empirical advances with conceptual debates on neural organization.

Scientific Background

Histological Staining Techniques

In the early , advancements in , spurred by improvements in compound microscopes and , transformed histological studies by enabling detailed observation of cellular structures, yet the friable nature of and inadequate methods hindered comprehensive visualization of neural elements. Pioneering microscopists like emphasized tissue-level analysis in 1801, but the need for stains that could enhance contrast and reveal subcellular details became pressing as improved. Among the earliest 19th-century stains, —a crimson derived from insects—emerged as a versatile , initially applied by John Hill in 1770 and later adapted for neural tissues by Joseph von Gerlach in 1858 to highlight cells and nuclei when combined with solutions like Johannes Müller's -based fixative. Hematoxylin, extracted from logwood trees, gained prominence in the and through the work of Franz Böhmer, who in 1865 introduced it with as a to produce vibrant nuclear staining in blue-violet hues, and Wilhelm von Waldeyer, who refined its application for tissue sections. The advent of synthetic aniline in the mid-19th century, pioneered by William Henry Perkin's in 1856, revolutionized selective staining. These techniques primarily targeted discrete cell parts—carmine and hematoxylin for nuclei and , and aniline dyes for selective affinity to proteins or —allowing of cell types but often requiring mordants for fixation and . Despite these innovations, prior methods suffered critical limitations, particularly for neural structures: dyes exhibited poor through sheaths, resulting in incomplete impregnation and fragmented views of neurons, where axons and distal processes remained unstained or invisible under light microscopy. Carmine and hematoxylin provided broad but non-specific contrast, often fading or diffusing unevenly, while even selective approaches omitted axonal , restricting insights into neuronal interconnectivity and overall architecture. This inadequacy underscored the demand for techniques that could reveal entire s, a challenge later addressed by Camillo Golgi's impregnation method.

Neuronal Structure Knowledge Prior to Golgi

Prior to the development of Golgi's method in the , the understanding of neuronal structure was severely limited by the constraints of early light microscopy and rudimentary staining techniques, which often depicted the as a continuous syncytial network rather than discrete cellular units. Pioneering microscopists, relying on basic fixatives like and dyes such as , could observe neural elements but struggled to resolve their full extent or individuality, fostering precursors to the reticular theory that posited an interconnected protoplasmic web throughout the brain and . This view stemmed from the apparent fusion of processes under low-resolution optics, where tissue preparation artifacts and incomplete impregnation blurred boundaries between cells. Early identifications of neuronal components began in the 1830s with Jan Evangelista Purkinje, who used hand-cut thin sections and achromatic lenses to describe flask-shaped cell bodies, or perikarya, in the cerebellar cortex of vertebrates, marking the first clear recognition of distinct neural somata. By the 1850s, researchers like Rudolf von Kölliker employed to reveal branching processes emanating from these cell bodies, noting varicosities and distinguishing initial axonal trunks from finer extensions, though full dendritic arborization remained obscured. Otto Friedrich Karl Deiters advanced this in 1865 through meticulous dissections of spinal motoneurons fixed in and stained with , identifying the within the perikaryon, multiple protoplasmic processes (later termed dendrites), and a single myelinated axis cylinder () that extended outward, providing the first systematic differentiation of these elements. Joseph von Gerlach, in the 1850s and 1860s, refined carmine-gelatin staining to visualize individual nerve fibers in the , yet his observations reinforced the notion of a networked continuum by showing processes that seemed to anastomose without clear endpoints. Despite these contributions from the to , significant challenges persisted in tracing neuronal connections and arborizations, as stains impregnated tissues unevenly, often highlighting only segments of processes and failing to reveal complete cellular morphologies. This incompleteness fueled ongoing debates about neural continuity, with reticular proponents like Gerlach arguing in 1871 for a protoplasmic linking all elements into a unified , while others, building on Deiters' discrete process distinctions, hinted at potential cellular independence without conclusive evidence. Such limitations prevented a holistic view of , leaving the full extent of dendritic trees and axonal projections largely unknown and setting the stage for methods that could selectively impregnate entire cells.

Technique

Materials and Preparation

The primary fixative used in Golgi's method is a solution, typically prepared at 3-5% concentration in distilled water, which serves to harden the soft prior to impregnation. The impregnation agent is , dissolved in an at 0.75-1% concentration, which reacts with the dichromate-fixed tissue to form deposits within selected neural elements. The method is best suited for small blocks of fresh , such as those from the or of small mammals like mice or rats, with block sizes generally limited to 3-5 mm to ensure adequate penetration of the reagents. Preparation requires clean glass vials or containers for immersion, as plastic may react with the solutions, and all procedures must be conducted in conditions or wrapped in to prevent light-induced of the silver salts. is essential, with incubations typically maintained at 20-37°C to optimize impregnation without excessive degradation. Both and are highly toxic chemicals that can cause severe skin irritation, respiratory issues, and environmental harm; proper handling includes the use of nitrile gloves, fume hoods, protective eyewear, and disposal as in accordance with laboratory safety regulations.

Step-by-Step Procedure

Golgi's method involves a multi-step to impregnate neural with , enabling visualization of individual neurons. The procedure begins with preparation and proceeds through impregnation, processing, and sectioning stages, with timings varying based on type and desired outcome. The first step entails dissecting fresh or fixed neural tissue into small blocks, typically 3-5 mm in size, followed by immersion in a solution. This hardening phase lasts 1-8 weeks in the dark at , allowing initial fixation and preparation for silver uptake. Next, the tissue is rinsed briefly in and transferred to a solution, where it remains for 1-3 days until blackening indicates successful impregnation. This step results in the formation of deposits within selected neural elements, a process that selectively fills entire cells for morphological study. Following impregnation, the tissue undergoes washing in to remove excess silver, then through a graded series of alcohols (e.g., 30%, 50%, 70%, 95%, and 100% , each for several minutes to hours). Clearing is achieved by immersing the dehydrated in clove oil or for 1-2 days to render it transparent. Finally, the cleared is embedded in a resin such as or for stability, then sectioned into slices 100-200 μm thick using a . These sections are mounted on slides for microscopic examination. The original method is notably slow, with the dichromate immersion often extending to several weeks or months for optimal results. In contrast, rapid variants, such as those developed by y Cajal, reduce the dichromate step to 1-2 days and the silver nitrate exposure to 24 hours, accelerating the overall process to under a week while maintaining selectivity.

Mechanism

Chemical Impregnation Process

The chemical impregnation process in Golgi's method begins with a fixation phase using (K₂Cr₂O₇), an that fixes proteins through oxidation and gelation by targeting reactive groups, thereby hardening the tissue and reducing its permeability to subsequent reagents. This step stabilizes cellular structures while limiting , creating localized chemical environments essential for selective deposition. In the subsequent reduction phase, the fixed tissue is immersed in (AgNO₃) solution, where residual chromate ions (CrO₄²⁻) from the dichromate interact with silver ions to form (Ag₂CrO₄) precipitates. These precipitates serve as sites, and chromate ions further facilitate the photoreduction of silver ions to metallic silver (Ag), which accumulates as opaque black granules within specific cellular compartments. The core reduction reaction can be simplified as: \ce{AgNO3 + reducing\ agent -> Ag \downarrow + other\ products} where the reducing agent primarily consists of tissue-derived organic compounds (e.g., aldehydes or lipids) activated by light, leading to the deposition of metallic silver precipitate. To control this photoreduction and avoid diffuse or extraneous deposits, the entire impregnation must occur in complete darkness, preventing unintended light-induced conversion of silver ions. The process's hallmark is its inherent randomness, with only 1-5% of cells achieving full impregnation, resulting from unpredictable microgradients in local ion concentrations, pH, and reducing substances across the tissue block. This variability underscores the method's biophysical reliance on heterogeneous chemical equilibria rather than uniform reactivity. Despite extensive research, the exact molecular determinants of this selective impregnation remain elusive.

Selectivity for Neural Elements

Golgi's method exhibits a remarkable selectivity for neural elements, preferentially impregnating a small subset of neurons—typically around 1-5%—while leaving the majority of cells unstained, a known as the "all-or-nothing" staining pattern. This capricious selectivity allows for the complete visualization of individual neurons, including their , dendrites, axons, and fine processes such as dendritic spines, against a pale, transparent background, creating high-contrast images that reveal intricate three-dimensional . The underlying chemical impregnation process, involving the reduction of , appears to target specific neuronal components, though the precise reasons for this neural preference remain incompletely understood. The precise biochemical basis for this selectivity is not fully understood but may involve differential uptake in neural structures rich in certain organic compounds. Although primarily selective for neurons, the method occasionally impregnates non-neural elements such as glial cells or blood vessels, though this is rare under optimal conditions and can be minimized through procedural adjustments. Factors influencing this selectivity include tissue freshness, with fresher or briefly fixed samples (e.g., perfused with for short durations) yielding better neural uptake; and time, where extended periods (15-45 days) promote neuronal specificity while shorter durations may favor . These variables affect the differential uptake of silver salts, underscoring the method's sensitivity to preparation conditions.

Applications

Visualization of Neurons

Golgi's method enables the complete impregnation of a small of neurons, allowing for the detailed of their entire , including the , dendrites, and axons, which appear as black silhouettes against a clear background under light microscopy. This selective staining reveals the intricate branching patterns of dendrites, their lengths, and the full extent of axonal projections, often extending over long distances within the tissue. A landmark application of the method was its use by in 1888 to observe dendritic spines for the first time on the dendrites of Purkinje cells in bird , initially appearing as small protrusions or "thorns" that increase the surface area for potential synaptic contacts. These spines, varying in shape and density across species and developmental stages, were confirmed as genuine structures through consistent observations in multiple preparations, including those from rabbits, young children, and cats. The technique's ability to stain entire dendritic trees facilitated the recognition of such fine details, which were previously undetectable with earlier staining methods. In terms of connectivity, Golgi's method supports the tracing of neural circuits by fully labeling axonal pathways and dendritic arborizations in key brain regions such as the , , and . For instance, in the , it highlights the apical and basal dendrites of pyramidal neurons, while in the , it aids in mapping layered connections between cell types. In the , the method vividly demonstrates the expansive, fan-like dendritic arborization of Purkinje cells, where primary dendrites branch into numerous secondary and tertiary processes spanning the molecular layer, often with visible spines arranged in helical patterns. Historically, the method has enabled three-dimensional reconstructions of neurons through the analysis of serial sections or z-stack imaging of stained preparations. By capturing multiple thin sections (typically 150–200 μm thick) and processing them with software like Neurolucida, researchers can reconstruct the full spatial architecture of impregnated neurons, such as pyramidal cells in the , preserving details of branching and orientation. Beyond neurons, the same impregnation process visualizes the Golgi apparatus as a reticular network in non-neural cells, confirming its presence as a ubiquitous in eukaryotic tissues. This visualization capability provided foundational insights into cellular organization that extended to broader advancements.

Contributions to Neuroscience

Golgi's method played a pivotal role in advancing the , a cornerstone of modern that posits neurons as independent cellular units rather than a fused network. In 1887, adopted and refined the technique through double impregnation, applying it to study brain tissues from immature animals, which revealed the full morphology of individual neurons including their dendrites and axons. His observations in the late 1880s and 1890s, particularly on the and , demonstrated that neurons maintain discrete boundaries and communicate across narrow gaps—later termed synapses—providing decisive evidence against continuous neural fusion and solidifying the formalized by Wilhelm Waldeyer in 1891. The method also fueled a key theoretical debate, as interpreted his own stainings as supporting the reticular theory, which envisioned the as an interconnected of fused axonal and dendritic processes forming a diffuse net. Golgi's 1873-1880s publications described neural elements blending seamlessly, initially lending credence to this view shared by contemporaries like Joseph von Gerlach. However, Cajal's meticulous drawings using the method in the 1890s refuted the reticular theory by clearly illustrating non-overlapping neuronal territories and the presence of dendritic spines, shifting consensus toward the neuron doctrine and paving the way for concepts like synaptic transmission introduced by Charles Sherrington in 1897. Beyond theoretical shifts, the method enabled seminal discoveries of neuronal diversity, illuminating brain organization at the cellular level. Golgi himself identified inhibitory in the cerebellar granule layer—now termed Golgi cells—in 1874, characterizing their polygonal shapes and extensive axonal plexuses that regulate granule cell activity. Cajal extended this by describing basket cells in the cerebellar molecular layer in 1888, highlighting their basket-like axonal baskets enveloping somata to mediate inhibition, which together advanced understanding of local circuit architecture in regions like the . The enduring legacy of Golgi's method established the groundwork for contemporary by permitting three-dimensional reconstruction of neural elements, influencing through Cajal's applications to embryonic brains that traced neuronal and circuit formation. This histological breakthrough, honored in the shared 1906 , remains foundational for mapping brain connectivity and inspires modern techniques like viral tracing for studying neural development and plasticity.

Limitations and Variations

Drawbacks of the Method

One of the primary limitations of Golgi's original method is its inherent unpredictability, where only a small fraction—typically 1-3%—of neurons in a sample become fully impregnated and stained, leaving the majority unstained and making results inconsistent across experiments. This nature stems from unknown factors determining which cells impregnate, rendering the technique unsuitable for quantitative studies requiring uniform staining of many neurons. The method is also prone to artifacts, such as patchy or unstable staining due to over-impregnation, which can blur neuronal structures or cause non-specific deposition of silver chromate precipitates throughout the tissue. These precipitates often form on the sample surface, obscuring fine details and complicating interpretation, particularly in densely stained regions. Processing with Golgi's method is highly time-intensive, requiring impregnation periods of 2 to 12 weeks or longer, followed by additional hardening and development steps that can extend the total timeline to months, which limits its practicality for large-scale or time-sensitive research. This prolonged duration arises from the slow diffusion of fixatives like potassium dichromate and silver nitrate into the tissue, making the approach inefficient for high-throughput applications. The use of hazardous chemicals, including and , poses significant toxicity and safety risks; is corrosive, causing severe skin burns, eye damage, and potential upon chronic exposure, while also being toxic to aquatic life. These require stringent handling protocols, increasing hazards and environmental concerns. Finally, the method is constrained to light , providing limited to approximately 200 nm due to optical , which prevents of ultrastructural details such as synaptic vesicles or membrane proteins that require electron microscopy. This makes it inadequate for studying subcellular architecture, though modern adaptations have sought to address such limitations.

Modern Adaptations and Alternatives

The Golgi-Cox method represents a key adaptation of the original Golgi technique, introduced by William H. Cox in 1891, which incorporates mercuric chloride alongside and to enhance impregnation and reveal a higher proportion of neurons with complete dendritic arborizations. This modification improves the clarity and reliability of staining for neuronal morphology, particularly in fixed brain tissues, allowing for better visualization of dendritic spines and overall cytoarchitecture without the variability inherent in alone. The rapid Golgi method further refines this approach by shortening the impregnation time from weeks to days through optimized fixation and staining protocols, making it suitable for time-sensitive studies in developing or postmortem tissues. Modern variants have shifted toward fluorescent techniques that mimic Golgi's selective labeling while enabling live imaging and specificity. For instance, DiOlistic labeling uses particle-mediated delivery of lipophilic dyes like to achieve Golgi-like, multicolor impregnation of neurons in fixed slices, facilitating high-resolution confocal analysis of connectivity and morphology. Genetic methods, such as transgenic expression of (GFP) under neuron-specific promoters, provide targeted visualization of subsets of neurons, offering consistent labeling across populations and integration with functional studies. Contemporary alternatives to Golgi-based methods prioritize reproducibility and ultrastructural detail over random impregnation. targets specific neuronal proteins or markers with antibodies conjugated to fluorophores or enzymes, enabling precise identification of cell types and synaptic elements in a controlled manner. provides nanoscale of synapses and spines, though it requires extensive and is less suited for large-scale surveys. techniques, such as stochastic optical reconstruction microscopy (STORM), surpass limits to resolve fine dendritic features with sub-diffraction precision, often combined with fluorescent labels for enhanced specificity. In 2025, further optimizations of the Golgi-Cox method were developed, including high-pressure-assisted Golgi-Cox (HP Golgi-Cox) that reduces staining time for whole mouse brains from 16 days to shorter periods, and near-freezing-temperature (NFT) Golgi staining that minimizes tissue autolysis to better preserve fine neuronal structures. Despite these advances, Golgi methods and their adaptations remain relevant in research, particularly for analyzing morphology in neurodegeneration models, where they reveal spine loss and alterations in diseases like Alzheimer's.

References

  1. [1]
    An Important Step in Neuroscience: Camillo Golgi and His Discoveries
    Dec 18, 2022 · Camillo Golgi was studying some specimens of nervous tissue, fixed according to a new technique. Small pieces of nervous tissue were kept in ...
  2. [2]
    The Original Histological Slides of Camillo Golgi and His ...
    Feb 18, 2019 · The metallic impregnation invented by Camillo Golgi in 1873 has allowed the visualization of individual neurons in their entirety, ...
  3. [3]
    Life and Discoveries of Camillo Golgi
    Apr 20, 1998 · In 1875 Golgi published, in an article on the olfactory bulbs, the first drawings of neural structures as visualized by the technique he had ...
  4. [4]
    Golgi-Cox Staining Step by Step - PMC - NIH
    Mar 31, 2016 · Here, we report in detail all steps of the Golgi-Cox staining method on adult mouse brain vibratome sections required for a reliable high quality staining.
  5. [5]
    Camillo Golgi – Biographical - NobelPrize.org
    Camillo Golgi was born at Corteno near Brescia on July 7, 1843, the son of a physician. He studied medicine at the University of Pavia under Mantegazza, ...
  6. [6]
    Speed read: Exposing the forest - NobelPrize.org
    Sep 16, 2009 · Searching for a better staining method, Golgi experimented by candlelight in a hospital kitchen that he converted into a laboratory. There, he ...Missing: anecdote | Show results with:anecdote
  7. [7]
    Life and discoveries of Camillo Golgi - NobelPrize.org
    Apr 20, 1998 · In 1873 he published a short note ('On the structure of the ... silver nitrate. Such revolutionary staining, which is still in use ...
  8. [8]
    Golgi Staining Technique | Embryo Project Encyclopedia
    Mar 6, 2017 · The Golgi staining technique, also called the black reaction after the stain's color, was developed in the 1870s and 1880s in Italy to make ...
  9. [9]
    A Cold Day in Stockholm | Science History Institute
    Sep 28, 2023 · Thirty-three years earlier, in 1873, Golgi had developed the black reaction, a technique that revealed for the first time the elegant detail of ...<|control11|><|separator|>
  10. [10]
    https://oxfordre.com/neuroscience/display/10.1093/acrefore/9780190264086.001.0001/acrefore-9780190264086-e-510
  11. [11]
    The unending fascination with the Golgi method - ResearchGate
    Aug 8, 2025 · It was developed by Cox in 1891 and is comprised of specimen impregnation, tissue protection, and color development 57 . Other modifications to ...
  12. [12]
    The discovery of dendritic spines by Cajal - Frontiers
    The Golgi impregnation enabled, for the first time, the relatively complete staining of the dendritic trees of neurons and is even today still widely used for ...
  13. [13]
    Golgi and Cajal: The neuron doctrine and the 100th anniversary of ...
    Mar 7, 2006 · The neuron doctrine as developed by Cajal was, in a sense, paradoxical. Although Cajal rejected Golgi's interpretations, his histological ...
  14. [14]
    The Nobel Prize in Physiology or Medicine 1906 - NobelPrize.org
    The Nobel Prize in Physiology or Medicine 1906 was awarded jointly to Camillo Golgi and Santiago Ramón y Cajal in recognition of their work on the structure of ...
  15. [15]
    Evolution of staining methods in neuroanatomy: Impetus for ...
    Mar 24, 2024 · Nissl staining method enhanced histological studies on nervous tissue to a great extent as it enabled scientists to distinguish nerve cells from ...
  16. [16]
    Histological Stains in the Past, Present, and Future - PMC
    Oct 4, 2021 · The objective of this study is to assess historical and contemporary stains and procedures, as well as the challenges surrounding their improvement.
  17. [17]
    The Contributions of Paul Ehrlich to Pharmacology - NIH
    Ehrlich's doctoral dissertation dealt with theoretical and practical aspects of histological stains, and he experimented with the recently discovered aniline ...Missing: neural | Show results with:neural
  18. [18]
    Franz Nissl (1860-1919), noted neuropsychiatrist and ... - NIH
    The major disadvantage of using Nissl staining is that the detailed morphology of the cell is not stained. In 1873, the Italian neuroanatomist Camillo Golgi, ...
  19. [19]
    Observations of synaptic structures: origins of the neuron doctrine ...
    During this same period (1862–1863), three young investigators, Max Schultze, Georg Walter and Otto Deiters, were studying nerve cells in the Anatomy Department ...
  20. [20]
    A Brief History of Neuronal Reconstruction | Neuroinformatics
    Feb 24, 2011 · In the late 1820s Jan Evangelista Purkinje began used a device (named a “microtome” by Charles Chavalier in 1839) for cutting thin brain ...
  21. [21]
    The Formation of Reticular Theory | Embryo Project Encyclopedia
    Jun 19, 2017 · Although Gerlach proposed the reticular theory in 1871 after examining evidence of his staining techniques on neurons, other scientists ...<|control11|><|separator|>
  22. [22]
    Modernization of Golgi staining techniques for high-resolution, 3 ...
    Jan 15, 2019 · In its original form, the Golgi method involves sequential incubation of tissue fragments in solutions of potassium dichromate and silver ...
  23. [23]
    The Original Histological Slides of Camillo Golgi and His ... - Frontiers
    The metallic impregnation invented by Camillo Golgi in 1873 has allowed the visualization of individual neurons in their entirety, leading to a breakthrough ...
  24. [24]
    [PDF] Material Safety Data Sheet - FD NeuroTechnologies
    Jun 25, 2020 · Toxic. Dangerous for the environment. Harmful by inhalation or in contact with skin or eyes. May be fatal if swallowed or absorbed through skin.
  25. [25]
    SILVER NITRATE - UMD
    Nov 17, 1999 · Label Precautions: Keep from contact with clothing and other combustible materials. Do not get in eyes, on skin, or on clothing. Do not breathe ...<|separator|>
  26. [26]
    Comprehensive Review of Golgi Staining Methods for Nervous Tissue
    Jun 30, 2017 · Golgi staining has been modified and developed since Camillo Golgi introduced the black reaction in 1873. ... Gazzetta Medica Italiana Lombardia.<|control11|><|separator|>
  27. [27]
    Potassium Dichromate - Chemical Fixing Agent - StainsFile
    It is incompatible with ethanol as it causes chromic oxide to be precipitated into the tissue. That is the reason for extended washing after fixation.
  28. [28]
    https://www.sciencedirect.com/science/article/pii/B9780121852559500249
  29. [29]
    The Golgi silver impregnation method - PubMed
    The Golgi silver impregnation technique is a simple histological procedure that reveals complete three-dimensional neuron morphology.
  30. [30]
    https://www.sciencedirect.com/science/article/pii/S104394719680111X
  31. [31]
    Chemical reduction of silver chromate: a procedure for electron ...
    A procedure is described by which the solid silver chromate precipitate present in Golgi-impregnated neurons is reduced by a photographic developer into ...
  32. [32]
    Advances in Thin Tissue Golgi-Cox Impregnation - PubMed Central
    In 1873, Camillo Golgi discovered the basic method ... A rapid method combining Golgi and Nissl staining to study neuronal morphology and cytoarchitecture.
  33. [33]
    Silver Impregnation - an overview | ScienceDirect Topics
    Basically, the Golgi technique involves treatment of fixed neural tissue with potassium dichromate, followed by exposure to silver nitrate. The resulting ...
  34. [34]
    Golgi Stain - an overview | ScienceDirect Topics
    The introduction of the staining method of Camillo Golgi in 1873 represented a giant step for neuroscience. Prior to this development, the visualization of ...
  35. [35]
    Golgi Stain - an overview | ScienceDirect Topics
    The intriguing aspect of the Golgi stain is that only a fraction of the cells in the sample of brain tissue are stained in an “all or nothing” fashion. This ...
  36. [36]
    The Golgi Apparatus - Madame Curie Bioscience Database - NCBI
    In the early 1900s, Golgi, Negri, Cajal and others used this method to visualize a similar reticular apparatus in many different cells,- leading to the current ...
  37. [37]
    https://doi.org/10.1016/j.cub.2006.02.053
  38. [38]
    https://doi.org/10.1113/jphysiol.2010.189605
  39. [39]
    An Optimized and Detailed Step-by-Step Protocol for the Analysis of ...
    Mar 11, 2022 · The unending fascination with the Golgi method . OA Anat . 2013. ;. 1. (. 3. ). https://doi.org/10.13172/2052-7829-1-3-848 . Google Scholar. 13 ...
  40. [40]
    [PDF] Review The unending fascination with the Golgi method
    Rapid Golgi method. The staining provided by the origi- nal Golgi method was not reproduc- ible because the unstable precipitate of chromate silver and ...<|control11|><|separator|>
  41. [41]
    Reliable and durable Golgi staining of brain tissue from human ...
    Jun 15, 2014 · A reliable procedure for Golgi staining of cerebral cortical neurons is described. · Impregnated cells are uniformly distributed, and all depths ...
  42. [42]
    Comprehensive Review of Golgi Staining Methods for Nervous Tissue
    Jun 30, 2017 · The advantages of the rapid Golgi method are that it is easier to stain neuronal cells for anatomical neuroscience research because it is easy ...
  43. [43]
    A Modified Method for Consistent and Reliable Golgi–Cox Staining ...
    The method is simple, reproducible, rapid, inexpensive, and provides uniform staining with very good resolution of neuronal soma, dendrites as well as spines.
  44. [44]
    [PDF] Silver Nitrate - Safety Data Sheet
    Mar 19, 2015 · Hazard statements: Causes skin irritation. Causes severe skin burns and eye damage. Toxic to aquatic life with long lasting effects.Missing: Golgi | Show results with:Golgi
  45. [45]
    Silver Nitrate Use and Toxicity | Iowa Head and Neck Protocols
    May 21, 2017 · The main toxic effect of topical silver nitrate is a generalized gray pigmentation of the skin called argyria. Argyria is very rare with chronic ...Missing: Golgi | Show results with:Golgi
  46. [46]
    A Confocal Reflection Super-Resolution Technique to Image Golgi ...
    However, the reported resolution of Golgi staining confocal reflection is limited by the diffraction limit of light, which is around 220 nm. Here, we report a ...<|control11|><|separator|>
  47. [47]
    Golgi Structure in Three Dimensions: Functional Insights from the ...
    Light microscopy of living cells reveals dynamic morphological events, but the method is intrinsically limited to a resolution of ∼200 nm, so interactions ...Results · Dissecting The Golgi With... · Discussion
  48. [48]
    Optimising Golgi–Cox staining for use with perfusion-fixed brain ...
    May 30, 2016 · Cox (1891) modified the original technique by replacing the silver nitrate, responsible for the impregnation of neurons, with mercuric chloride ...
  49. [49]
    Golgi‐Cox Staining of Neuronal Dendrites and ... - Current Protocols
    Apr 29, 2019 · The unending fascination with the Golgi method. OA Anatomy, 1, 1–8 ... Some evidence of the nature of the Golgi-Cox deposit and its biochemical ...Missing: source | Show results with:source
  50. [50]
    Rapid Golgi Stain for Dendritic Spine Visualization in Hippocampus ...
    Dec 3, 2021 · The method of using potassium dichromate and silver nitrate to label neurons was first described by Camillo Golgi 1, 2 and subsequently used by ...Abstract · Protocol · Materials
  51. [51]
    Imaging Neuronal Subsets in Transgenic Mice Expressing Multiple ...
    We generated transgenic mice in which red, green, yellow, or cyan fluorescent proteins (together termed XFPs) were selectively expressed in neurons.
  52. [52]
    Methods of Dendritic Spine Detection: from Golgi to High Resolution ...
    Since the original Golgi staining was very time-consuming, two main modified protocols were developed, (i) Rapid Golgi staining. Brain tissue is fixed in an ...
  53. [53]
    Imaging Synaptic Density: The Next Holy Grail of Neuroscience?
    Electron microscopy (EM) is the gold standard method to quantify changes in synaptic density, being the only technique that allows direct visualization of the ...
  54. [54]
    Staining neurons with Golgi techniques in degenerative diseases of ...
    Silver staining was introduced in histology by Camillo Golgi in 1873, more than 140 years ago, as 'reazione nera' (black reaction) (Golgi, 1873). The philosophy ...