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History of neuroscience

The history of neuroscience traces the evolution of scientific inquiry into the structure, function, and disorders of the nervous system, spanning from ancient empirical observations of the brain to the emergence of a formalized interdisciplinary field in the 20th century.^[1] This progression reflects a shift from philosophical speculations about the mind and body to empirical methods in anatomy, physiology, and electrophysiology, driven by key discoveries that established the neuron as the fundamental unit of the nervous system and illuminated its role in sensation, movement, cognition, and behavior.^[2] Milestones include early anatomical descriptions, the development of staining techniques for visualizing neural tissue, and the integration of technologies like electroencephalography and neuroimaging, culminating in modern initiatives such as the BRAIN Initiative.^[3] Ancient civilizations laid the groundwork for neuroscience through rudimentary observations of the brain's anatomy and its association with bodily functions. In Egypt around 1700 BC, the Edwin Smith Surgical Papyrus documented the brain's structure, including meninges and cerebrospinal fluid, marking the earliest known record of the nervous system.^[1] Greek philosophers like Hippocrates (c. 460–379 BC) advanced this by asserting that the brain, rather than the heart, is the seat of intelligence and sensation, and he described early neurosurgical practices such as trepanation for head wounds.^[3] Galen (c. 130–200 AD), a Roman physician, expanded on these ideas by linking the brain to sensory and motor control through concepts of fluid "animal spirits" traveling via nerves, influencing Western medicine for centuries.^[2] These early views often intertwined anatomy with philosophical debates, such as Aristotle's (384–322 BC) erroneous placement of the mind in the heart while acknowledging the brain's role in cooling blood.^[2] The Renaissance and Enlightenment periods marked a transition to more systematic anatomical and experimental approaches, fueled by technological advances like the compound microscope invented in 1590.^[1] Andreas Vesalius's 1543 publication of De Humani Corporis Fabrica revolutionized neuroanatomy with detailed illustrations of the brain, challenging Galen's inaccuracies and emphasizing direct human dissection.^[3] In the 17th century, Thomas Willis coined the term "neurology" in his 1664 work Cerebri Anatome, providing comprehensive descriptions of brain structures like the circle of Willis and advocating a materialist view of neural function.^[1] The late 18th century saw Luigi Galvani's experiments demonstrating that nerves conduct electricity, laying the foundation for electrophysiology and debating "animal electricity" with Alessandro Volta.^[3] The 19th century brought rapid advancements in localization of function and cellular neuroscience, bridging anatomy and physiology. Paul Broca's 1861 identification of a brain area (now Broca's area) linked to speech production supported cortical localization theories, while Gustav Fritsch and Eduard Hitzig's 1870 electrical stimulation experiments confirmed motor areas in the cortex.^[2] Camillo Golgi's 1873 silver staining method enabled visualization of individual neurons, though his reticular theory of a continuous nerve network was overturned by Santiago Ramón y Cajal's 1888–1890 observations supporting the neuron doctrine—that neurons are discrete cells communicating via synapses.^[1] This era also saw Hermann von Helmholtz's 1850 measurement of nerve impulse speed at about 30 meters per second, disproving vitalistic notions and affirming physical laws in neural transmission.^[1]^[4] Phrenology, popularized by Franz Joseph Gall, though pseudoscientific, spurred interest in brain modularity.^[5] In the 20th century, neuroscience coalesced as a distinct discipline, integrating psychology, biology, and medicine amid technological innovations. Hans Berger's 1924 recording of the first human electroencephalogram (EEG) opened doors to studying brain electrical activity noninvasively.^[1] The 1932 Nobel Prize awarded to Edgar Adrian and Charles Sherrington recognized breakthroughs in neural signaling and synaptic transmission.^[3] Post-World War II, Donald Hebb's 1949 theory of synaptic plasticity ("cells that fire together wire together") provided a foundation for understanding learning and memory.^[1] The 1960s–1970s saw the discovery of neurotransmitters like dopamine and the establishment of the Society for Neuroscience in 1969, formalizing the field.^[6] By the late 20th century, techniques such as functional MRI and optogenetics propelled integrative research, with Korbinian Brodmann's early 1909 cytoarchitectonic brain mapping influencing modern parcellation studies.^[2] Today, neuroscience continues to evolve, addressing complex issues like consciousness and neural disorders through global collaborations.^[5]

Ancient and Classical Foundations

Early Civilizations

In ancient Egypt and Mesopotamia, early medical observations of the nervous system were primarily practical and tied to trauma treatment, reflecting a worldview that prioritized the heart over the brain as the seat of intellect and emotion. Imhotep (c. 2650–2600 BC), a polymath under Pharaoh Djoser later deified as a god of medicine, became traditionally associated with early Egyptian medical practices in later legends, though no contemporary evidence links him to specific insights on head injuries or neurological symptoms.^[7] Mesopotamian and Egyptian healers viewed the brain largely as a secondary organ rather than contributing to cognition or sensation, a perspective evident in diagnostic texts that emphasized vascular and cardiac systems.^[8] In Mesopotamia, cuneiform tablets documented brain-related vascular disorders, such as strokes, but interpreted them through supernatural lenses, with limited anatomical detail.^[9] Egyptian sources similarly downplayed the brain's cognitive role, discarding it during mummification while preserving the heart.^[10] The Edwin Smith Papyrus, dating to c. 1700 BC but copying an original from around 2500 BC, represents the earliest systematic description of the brain and spinal cord, detailing 13 cases of head and neck trauma with observations of meninges, cerebrospinal fluid, and symptoms like seizures and hemiparesis.^[11] It includes innovative surgical approaches, such as closing wounds with sutures and using honey as an antiseptic for skull fractures, classifying injuries as treatable, contested, or untreatable based on prognosis.^[12] This text marks a shift toward empirical examination, noting pulse in cerebral vessels and linking spinal injuries to lower-body paralysis.^[13] Cultural and religious taboos in these civilizations prohibited human dissection, restricting anatomical knowledge to surface observations from wounds, mummification, or animal analogies, which fostered speculative rather than precise understandings of the nervous system.^[14] These practices laid rudimentary groundwork for later Greek inquiries into the brain's functions.

Greek and Roman Contributions

In ancient Greece, early thinkers began to conceptualize the brain as central to sensation, cognition, and disease, marking a philosophical departure from earlier views that emphasized the heart or supernatural forces. This period laid foundational ideas through observation and rudimentary dissection, influencing subsequent medical thought. Alcmaeon of Croton, around 500 BCE, was among the first to propose that the brain serves as the seat of sensation and intelligence, arguing that sensory perceptions arise from channels (poroi) connecting the extremities to the brain. He linked these pathways to the body's overall harmony, emphasizing empirical observation over mythological explanations.^[15] Hippocrates of Kos (c. 460–370 BCE), often regarded as the father of medicine, advanced these notions by asserting that the brain is the organ of thought, intelligence, and emotion. In his treatise On the Sacred Disease, he rejected supernatural attributions for epilepsy, instead describing it as a disorder originating in the brain due to phlegm or other humors blocking air passages, and he provided early accounts of brain injuries causing aphasia or paralysis. These ideas promoted a naturalistic approach to neurological conditions, prioritizing heredity and environmental factors.^[16] During the Hellenistic era in Alexandria, systematic dissections elevated anatomical precision. Herophilus of Chalcedon (c. 335–280 BCE) conducted human cadaver dissections—possibly including vivisections—to map brain structures, identifying the meninges as protective layers, distinguishing the cerebrum from the cerebellum, and delineating the four ventricles, which he viewed as sites of cognitive processing. He named the torcular Herophili, the confluence of dural venous sinuses, and recognized the brain's role in controlling the nervous system, crediting it with housing the soul's rational faculties.^[17]^[18] Erasistratus of Ceos (c. 304–250 BCE), a contemporary of Herophilus, complemented these findings through animal vivisections, distinguishing sensory nerves, which transmit perceptions to the brain, from motor nerves, which carry commands from the brain to muscles. He proposed that nerves function as conduits for pneuma (vital spirit), favoring a mechanistic model of neural transmission that contrasted with more humoral explanations in ancient medicine.^[19]^[20] In the Roman era, Galen of Pergamon (c. 129–216 CE) synthesized and expanded Greek insights, developing the influential ventricular theory of brain function. He described three interconnected ventricles—considering the lateral ones as one—through which animal spirits flow: from the anterior for sensation, middle for cognition, and posterior for motor control. Based on animal dissections and injury observations, Galen posited that these spirits, refined from blood in the brain's choroid plexuses, enable perception and voluntary movement, establishing a framework that dominated neurophysiology for centuries.^[21]^[22] These contributions drew indirectly from Egyptian medical texts, which documented brain injuries and basic anatomy, influencing Greek observers through trade and migration.^[23]

Medieval and Early Modern Developments

Islamic Golden Age

During the Islamic Golden Age, particularly from the 8th to the 10th centuries, the translation movement in Baghdad played a pivotal role in preserving and disseminating classical Greek knowledge on anatomy and medicine, including works by Galen and Hippocrates. The House of Wisdom (Bayt al-Hikma) served as a major intellectual center under Abbasid patronage, where scholars systematically translated these texts from Greek and Syriac into Arabic, ensuring their survival and expansion. Hunayn ibn Ishaq (c. 809–873), a prominent Nestorian Christian physician and translator, led this effort, rendering over 129 of Galen's works, including key anatomical treatises such as De Anatomicis Administrationibus and De Usu Partium, which detailed the structure and function of nerves and the brain.^[24]^[25] These translations not only preserved Galen's ventricular theory of brain function—positing sensory processing in the brain's anterior ventricles—but also laid the groundwork for Islamic refinements through critical commentary and integration with empirical observations.^[26] Building on this foundation, Islamic scholars advanced clinical neurology and neuroanatomy through detailed descriptions and classifications of disorders. Abu Bakr Muhammad ibn Zakariya al-Razi (Rhazes, 865–925), in his comprehensive Kitab al-Hawi (Comprehensive Book), differentiated apoplexy (a sudden loss of sensation and motion due to vascular obstruction) from epilepsy (characterized by recurrent seizures without loss of consciousness) based on distinct symptom profiles, such as the presence of convulsions versus paralysis.^[27] Al-Razi's approach emphasized careful clinical observation to distinguish neurological conditions, influencing later diagnostic practices. Similarly, Abu al-Qasim al-Zahrawi (Albucasis, c. 936–1013), in his 30-volume Al-Tasrif (The Method of Medicine), provided pioneering surgical treatments for neurological ailments, including trephination for headaches caused by skull pressure, traction for sciatica to relieve spinal nerve compression, and interventions for paralysis from head injuries or spinal damage.^[28]^[29] Al-Zahrawi's work, which included illustrations of surgical instruments and procedures, marked a shift toward practical neurosurgery grounded in anatomy.^[30] Ibn Sina (Avicenna, 980–1037) further synthesized and expanded this knowledge in his influential Al-Qanun fi al-Tibb (The Canon of Medicine), a standard text for centuries. He classified neurological disorders such as meningitis (distinguishing it from other inflammations by symptoms like fever and neck stiffness) and provided detailed brain anatomy, including descriptions and illustrations of the seven pairs of cranial nerves (excluding the olfactory), their origins from the brainstem, and roles in sensation and movement.^[31]^[32] Avicenna's systematic approach integrated Galenic theory with observational data, emphasizing the brain's role as the seat of intellect and the nerves as conduits for "psychic pneuma."^[33] Islamic physicians also introduced more rigorous experimental methods, including animal testing to verify nerve functions, which built upon but critiqued Galen's human-based dissections. Scholars like al-Razi and al-Zahrawi employed empirical observations to study sensory and motor nerve responses and test treatments for paralysis.^[26] This empirical validation fostered a culture of inquiry, where ancient texts were not merely copied but tested against observation, advancing neuroscience beyond rote preservation.^[34]

European Renaissance and Reformation

The European Renaissance marked a pivotal revival in anatomical studies, fueled by humanist scholarship that emphasized direct observation and empirical dissection over unquestioned reliance on ancient authorities like Galen. This period saw anatomists in Italy and beyond conducting human dissections to map the body's structures more accurately, laying groundwork for understanding the nervous system. Preservation of classical texts by Islamic scholars during the preceding centuries facilitated this resurgence, providing Europeans with translated works that sparked renewed inquiry.^[35] A cornerstone of this anatomical renaissance was Andreas Vesalius's 1543 publication of De humani corporis fabrica libri septem, which revolutionized brain anatomy through meticulous dissections of human cadavers. Vesalius corrected several of Galen's longstanding errors, including the erroneous depiction of a rete mirabile—a vascular network purportedly at the brain's base in humans, which Vesalius demonstrated was absent—and inaccuracies in the liver-shaped form of the cerebral ventricles. He also refined the description of cranial nerves, identifying seven pairs emerging from the brain but clarifying their origins and paths based on direct observation, such as distinguishing the optic nerves more precisely than Galen's animal-based models. These corrections challenged the Galenic ventricular theory, which posited the brain's cavities as sites of sensory processing, by offering detailed mappings that highlighted the ventricles' actual interconnected, irregular shapes rather than simplistic chambers. Vesalius's work promoted a shift toward evidence-based neuroanatomy, influencing subsequent generations to prioritize human specimens over textual tradition.^[36]^[37] Complementing Vesalius's efforts, Bartolomeo Eustachi advanced knowledge of sensory structures in the head during the mid-16th century. In his Explicatio tabularum anatomicarum (published posthumously in 1552, with plates from around 1550), Eustachi provided the first detailed illustrations of the inner ear, including the cochlea's spiral form, the stapedius muscle, and the Eustachian tube connecting the middle ear to the nasopharynx. These findings elucidated mechanisms of hearing and balance, linking peripheral anatomy to neural function and correcting vague ancient descriptions of auditory pathways. Eustachi's precise engravings of the temporal bone and its neural connections underscored the ear's role in sensory neuroscience, building on Renaissance empiricism.^[38]^[39] The invention of the printing press in the 15th century amplified these discoveries by enabling the mass production and distribution of illustrated anatomical texts. Vesalius's Fabrica, with its woodcut images by artists like Jan van Calcar, reached scholars across Europe, democratizing access to accurate brain diagrams and fostering collaborative critique of Galenic errors. This technological advancement not only standardized anatomical nomenclature but also accelerated challenges to the ventricular theory through widespread dissemination of ventricle casts and nerve tracings.^[40]^[41] Even earlier, Leonardo da Vinci's unpublished sketches from the late 15th and early 16th centuries anticipated these developments through innovative dissections of animal brains, particularly oxen. Around 1508, da Vinci injected molten wax into an ox brain to create a cast of the ventricular system, producing drawings that depicted the lateral, third, and fourth ventricles with unprecedented fidelity to their curved, communicating forms. These illustrations rejected Galen's compartmentalized model, visualizing the ventricles as a continuous network potentially involved in fluid dynamics and sensory integration, though da Vinci's work remained private until centuries later. His empirical approach exemplified the Renaissance blend of art and science in probing neural architecture.^[42]^[43]

Enlightenment and 19th-Century Advances

18th-Century Physiological Discoveries

The 18th century marked a pivotal transition in neuroscience from descriptive anatomy to experimental physiology, emphasizing the dynamic functions of nerves and muscles through empirical investigations. Building briefly on the detailed anatomical foundations established by Andreas Vesalius in the 16th century, which provided accurate depictions of neural structures essential for later experimentation, Enlightenment-era scientists began exploring the physiological mechanisms underlying sensation, motion, and involuntary actions. This era's discoveries laid the groundwork for understanding the nervous system as an active, responsive network rather than a static framework.^[44] A key figure in this shift was Albrecht von Haller, a Swiss physiologist who, through systematic experiments in the 1750s, distinguished between irritability—the inherent contractility of muscle tissue in response to stimuli—and sensibility—the capacity of nerves to perceive and transmit sensations. Haller's work, detailed in his 1757–1766 treatise Elementa Physiologiae Corporis Humani, demonstrated that muscles could contract without neural involvement, while nerves were indispensable for sensory responses, challenging earlier vitalistic views and promoting a mechanistic approach to physiology. These concepts influenced subsequent research by highlighting the distinct roles of neural and muscular tissues in bodily responses.^[45] Robert Whytt, a Scottish physician, advanced these ideas in the 1760s by elucidating early concepts of the reflex arc, describing involuntary motions as mediated by a neural pathway involving sensory input, spinal processing, and motor output. In his 1768 work An Essay on the Vital and Other Involuntary Motions of Animals, Whytt showed through vivisections that reflexes could occur in isolated spinal segments, independent of the brain, and emphasized the role of the spinal cord as a central integrator. His experiments on decapitated animals demonstrated localized reflex actions, such as limb withdrawal, establishing the reflex as a fundamental unit of nervous function.^[46] The introduction of electricity as a physiological tool revolutionized nerve studies, beginning with Luigi Galvani's 1791 experiments on frog legs, which revealed "animal electricity" as an intrinsic neural property. Galvani observed that electrical discharges from static machines or metals caused muscle contractions in prepared frog nerves, concluding in his De Viribus Electricitatis in Motu Musculari Commentarius that nerves conducted bioelectric impulses, a discovery that sparked intense debate on the nature of neural signaling. This work directly inspired Alessandro Volta's invention of the voltaic pile in 1800, a continuous-current battery that provided a reliable source for stimulating nerves and muscles in subsequent physiological experiments.^[47] Further refining spinal nerve functions, Charles Bell and François Magendie independently formulated the Bell-Magendie law between 1811 and 1824, establishing that dorsal spinal roots transmit sensory information while ventral roots convey motor commands. Bell's 1811 pamphlet Idea of a New Anatomy of the Brain proposed functional differentiation based on anatomical observations, but Magendie's 1822 experiments on dogs—severing roots selectively—provided definitive evidence, showing sensory loss with dorsal sectioning and motor paralysis with ventral sectioning. Their combined findings, confirmed through rigorous vivisection, clarified the bidirectional organization of the spinal cord and advanced the localization of neural functions.^[48]

19th-Century Anatomical and Localization Studies

In the 19th century, advancements in microscopy and surgical techniques enabled detailed anatomical studies of the nervous system, shifting focus from gross physiology to cellular structures and functional localization within the brain. Building on earlier peripheral nerve discoveries like the Bell-Magendie law, which distinguished sensory and motor spinal roots, researchers began mapping specific brain regions to cognitive functions, laying the groundwork for modern neuroscience.^[49] This era emphasized autopsy-based correlations between lesions and deficits, particularly in language and movement, while confirming the cellular composition of nervous tissue.^[50] Key physiological measurements, such as Hermann von Helmholtz's 1850 determination of nerve impulse conduction velocity at approximately 27 meters per second in frog sciatic nerve using a ballistic chronograph, further demonstrated that neural transmission followed physical laws rather than being instantaneous, as previously assumed in vitalistic theories.^[51] Theodor Schwann's work in the 1830s and 1840s established that nervous tissue, like other animal tissues, is composed of discrete cells, extending cell theory to the nervous system. In his 1839 publication Mikroskopische Untersuchungen, Schwann described myelinated nerve fibers and identified the cells enveloping them, now known as Schwann cells, through meticulous microscopic examinations of peripheral nerves.^[52] This cellular perspective challenged earlier reticular views of the nervous system and facilitated subsequent histological investigations.^[53] Pioneering localization studies emerged with Paul Broca's 1861 autopsy of patient "Tan" (Louis Victor Leborgne), who exhibited severe expressive aphasia due to a lesion in the left inferior frontal gyrus, now termed Broca's area. Broca's findings, presented in Remarques sur le siège de la faculté du langage articulé, linked this region to articulated speech production, supporting cerebral localization of function.^[49] Complementing this, Carl Wernicke in 1874 described receptive aphasia in patients with damage to the posterior superior temporal gyrus (Wernicke's area), as detailed in Der aphasische Symptomencomplex, associating it with impaired language comprehension and fluent but nonsensical speech.^[50] These observations formed the basis of the Wernicke-Geschwind model of language processing.^[54] Gustav Fritsch and Eduard Hitzig advanced motor localization in 1870 through electrical stimulation experiments on dogs, identifying excitable regions in the frontal cortex that elicited contralateral limb movements when stimulated with low-intensity direct current. Their findings, published in Untersuchungen über das Gehirn, refuted the prevailing view of the cortex as equipotential and confirmed discrete motor areas, influencing later human studies.^[55] Jean-Martin Charcot advanced clinical neurology at Paris's Salpêtrière Hospital in the 1860s–1880s, using systematic autopsies to correlate symptoms with brain pathology in conditions like hysteria and multiple sclerosis. Charcot's 1868 description of multiple sclerosis as a distinct entity, characterized by plaques in the central nervous system, relied on anatomoclinical methods to differentiate it from other disorders.^[56] His studies on hysteria emphasized neurological rather than purely psychological origins, influencing the discipline's professionalization. The culmination of these efforts came with the neuron doctrine, articulated in the late 1890s by Santiago Ramón y Cajal using Camillo Golgi's 1873 silver chromate staining method, which selectively visualized individual nerve cells. Golgi's "black reaction" revealed neurons as distinct units with axons and dendrites, while Cajal's interpretations in works like La cellule nerveuse (1890s) demonstrated their non-continuous arrangement, refuting the reticular theory.^[57] This paradigm shift earned them the 1906 Nobel Prize in Physiology or Medicine for elucidating the nervous system's histological organization.^[58]

20th-Century Consolidation

Electrophysiology and Synaptic Theory

The early 20th century marked a pivotal shift in neuroscience toward understanding the functional mechanisms of neural signaling, building upon the neuron doctrine's establishment of neurons as discrete units that interact at specialized junctions. This period saw the development of electrophysiology, which revealed how electrical impulses propagate along neurons and transmit information across these junctions, laying the groundwork for modern synaptic theory.^[59] Charles Sherrington, a pioneering British physiologist, introduced the term "synapse" in 1897 to describe the functional connection between neurons, emphasizing its role as a site of delay and modulation in neural transmission. In his seminal 1906 book, The Integrative Action of the Nervous System, Sherrington elaborated on reflex inhibition, demonstrating how antagonistic muscle reflexes are coordinated through synaptic interactions, which he characterized as dynamic processes enabling the nervous system's integrative functions. His work highlighted the synapse's "valvular" nature, allowing unidirectional signal flow and central inhibition, concepts that transformed views of neural coordination from mere wiring to active regulation.^[60]^[61] Complementing Sherrington's conceptual framework, Julius Bernstein advanced the biophysical basis of neural impulses in 1902 with his membrane theory. Bernstein proposed that the resting potential of excitable cells arises from a semipermeable membrane selectively allowing potassium ions to dominate, while excitation triggers a transient increase in permeability to other ions, generating the action potential as a propagating wave of depolarization. This model provided the first physico-chemical explanation for the electrical nature of nerve signals, resolving earlier debates on whether impulses were electrical or chemical in origin.^[62] Edgar Adrian built on these ideas through experimental electrophysiology in the 1920s, achieving the first recordings of action potentials from single nerve fibers using vacuum tube amplifiers to detect minute electrical signals. His 1928 studies on sensory nerves showed that impulses are all-or-none events, with frequency encoding stimulus intensity rather than amplitude varying with strength, a finding that clarified how individual neurons convey graded information. For these discoveries on neuron function, Adrian shared the 1932 Nobel Prize in Physiology or Medicine with Sherrington.^[63] A major breakthrough in synaptic transmission came from Otto Loewi and Henry Dale, who in 1921 demonstrated chemical neurotransmission through Loewi's famous "vagusstoff" experiment on frog hearts. Loewi electrically stimulated the vagus nerve of one heart, collected the perfusate, and applied it to a second heart, observing slowed beating—evidence of a diffusible substance mediating the effect. Dale later identified this substance as acetylcholine in 1936, confirming its role as the first known neurotransmitter at parasympathetic synapses and distinguishing cholinergic transmission from direct electrical coupling. Their collaborative work earned the 1936 Nobel Prize in Physiology or Medicine, solidifying the chemical synapse as a core element of neural communication.^[64] Parallel to these advances, Hans Berger developed electroencephalography (EEG) in 1924, recording the first human brain electrical potentials using scalp electrodes and a galvanometer. His observations of rhythmic alpha waves during relaxation provided the initial noninvasive method to monitor aggregate neuronal activity, opening avenues for studying brain states and disorders like epilepsy. Berger's EEG technique, refined through years of meticulous recordings, became a foundational tool for probing cortical electrophysiology in vivo.^[65] These contributions collectively established electrophysiology and synaptic theory as cornerstones of neuroscience, shifting focus from static anatomy to dynamic signaling processes that underpin behavior and cognition.

Neuroimaging and Molecular Mechanisms

The mid-20th century marked a pivotal shift in neuroscience toward elucidating the molecular underpinnings of neural signaling and developing tools to visualize brain structure and function, building on Charles Sherrington's foundational concept of the synapse as a functional junction between neurons.^[60] These advances, from biophysical models of action potentials to biochemical discoveries of neurotransmitters and pioneering imaging techniques, provided mechanistic insights into brain activity and laid the groundwork for modern neurobiology. In the early 1950s, Alan Hodgkin and Andrew Huxley developed the Hodgkin-Huxley model, a seminal quantitative framework describing the ionic mechanisms underlying action potential initiation and propagation in neurons. Their work relied on the innovative voltage-clamp technique, applied to the squid giant axon, which allowed precise measurement of sodium and potassium currents across the membrane during controlled voltage changes. This model demonstrated how voltage-gated ion channels drive the rapid depolarization and repolarization phases of the action potential, revolutionizing understanding of neuronal excitability.^[66] For their contributions, Hodgkin and Huxley shared the 1963 Nobel Prize in Physiology or Medicine with John Eccles. Concurrently, neurosurgeon Wilder Penfield advanced intraoperative brain mapping techniques during epilepsy surgeries at the Montreal Neurological Institute from the 1930s through the 1950s.^[67] By applying mild electrical stimulation to exposed cortical surfaces while patients were awake under local anesthesia, Penfield identified functional regions, pinpointing epileptic foci for precise resection. His mappings revealed the somatotopic organization of the primary sensory and motor cortices, leading to the iconic depictions of the sensory and motor homunculi—distorted representations of the body reflecting the disproportionate cortical area devoted to regions like the hands and face. These findings established cortical localization principles that informed subsequent neurosurgical practices and functional neuroanatomy.^[68] The identification of key neurotransmitters further illuminated molecular mechanisms of neural inhibition and modulation. In 1950, Eugene Roberts and Sam Frankel discovered gamma-aminobutyric acid (GABA) as a major component of brain tissue using chromatographic techniques. By the mid-1950s, electrophysiological studies, including 1957 experiments by researchers such as A.W. Bazemore, K.A.C. Elliot, and E. Florey, confirmed GABA's role as the primary inhibitory neurotransmitter in the central nervous system, acting via hyperpolarization of postsynaptic neurons to dampen excitability.^[69] This breakthrough explained mechanisms of neural balance and influenced studies on conditions like epilepsy and anxiety. In the 1970s, the discovery of endorphins—endogenous opioid peptides—revealed natural pain-relief systems; John Hughes and Hans Kosterlitz isolated enkephalins from pig brain in 1975, while Choh Hao Li characterized beta-endorphin shortly thereafter. These molecules, binding to opioid receptors, modulate pain, reward, and stress responses, paralleling the effects of exogenous opiates like morphine. Eric Kandel's research in the 1960s and 1970s on the marine snail Aplysia californica provided profound insights into synaptic plasticity as the cellular basis of learning and memory.^[70] Using this simple nervous system with identifiable neurons, Kandel demonstrated short-term sensitization through enhanced neurotransmitter release and long-term changes involving gene expression and new synaptic connections. His work elucidated signal transduction pathways, such as cyclic AMP-mediated modulation of presynaptic calcium channels, linking molecular events to behavioral modifications.^[71] For these discoveries concerning signal transduction in the nervous system, Kandel shared the 2000 Nobel Prize in Physiology or Medicine with Arvid Carlsson and Paul Greengard.^[72] Parallel to these molecular advances, neuroimaging techniques emerged in the 1970s to non-invasively visualize brain anatomy and metabolism. Godfrey Hounsfield, working at EMI Laboratories, invented the computed tomography (CT) scanner, with the first clinical brain scan performed in 1971 at Atkinson Morley Hospital.^[73] This X-ray-based method reconstructed cross-sectional images using computer algorithms, enabling detection of tumors, hemorrhages, and structural abnormalities without surgery. Hounsfield shared the 1979 Nobel Prize in Physiology or Medicine with Allan Cormack for this innovation, which transformed diagnostic radiology.^[74] Building on positron-emitting radionuclides, positron emission tomography (PET) was developed in the mid-1970s by Michael Phelps, Edward Hoffman, and Michael Ter-Pogossian at Washington University, with the first multi-slice scanner (PETT III) operational in 1974.^[75]^[76] PET imaged regional metabolic activity and blood flow through radiolabeled tracers like 18F-fluorodeoxyglucose, revealing functional deficits in disorders such as Alzheimer's and schizophrenia during the 1980s.^[75] These modalities bridged anatomical and physiological neuroscience, facilitating in vivo studies of brain function.

21st-Century Innovations

Optogenetics and Neural Engineering

Optogenetics emerged as a transformative technique in the early 21st century, enabling precise control of neural activity with light. In 2005, Karl Deisseroth and colleagues introduced this method by expressing light-sensitive ion channels, such as channelrhodopsin-2 from green algae, in specific neuron populations using viral vectors. This allowed for millisecond-precision activation or inhibition of targeted cells, revolutionizing the study of neural circuits by providing causal insights into behavior and function that were previously unattainable through electrical or pharmacological methods.^[77] Ed Boyden, a key collaborator in the initial development and subsequent innovator, advanced optogenetics through refined tools and applications in the 2010s. His work expanded the toolkit to include opsins for silencing neurons and integrated genetic targeting for more complex manipulations, facilitating experiments on learning and psychiatric models. For instance, optogenetic techniques enabled the manipulation of fear memories in mice, demonstrating the ability to reactivate or suppress engram cells associated with conditioned responses, akin to analogs of post-traumatic stress disorder (PTSD). These advancements built on foundational synaptic plasticity concepts, allowing direct testing of memory formation mechanisms.^[78]^[79] Neural engineering progressed alongside optogenetics with the development of brain-computer interfaces (BCIs), which translate neural signals into external actions. Building on earlier implantable electrode arrays like the Utah array commercialized in the 2000s, Blackrock Neurotech advanced high-density BCIs that enabled paralyzed individuals to control cursors or prosthetics with thoughts, with over 50 human implants as of 2025 demonstrating long-term stability. In 2016, Elon Musk co-founded Neuralink to scale these technologies, developing flexible thread-like electrodes for thousands of channels to achieve bidirectional communication between brains and computers, aiming to treat neurological disorders and enhance cognition. Neuralink conducted its first human implant in 2024, with 12 individuals receiving devices by November 2025, enabling activities like cursor control and communication for those with paralysis.^[80] Stem cell therapies and gene editing further enhanced neural repair capabilities in the 2010s. Induced pluripotent stem cells (iPSCs), pioneered by Shinya Yamanaka in 2006, were differentiated into neural progenitors and tested in preclinical spinal cord injury models, showing functional recovery through remyelination and axon regrowth; human trials began in the late 2010s, such as Japan's 2019 study transplanting iPSC-derived cells into patients with chronic injuries. Concurrently, CRISPR-Cas9, introduced in 2012, enabled precise gene editing in neural circuits, with applications in modeling diseases like epilepsy by knocking out specific genes in vivo and correcting mutations in patient-derived neurons.^[81]^[82]

Global Brain Projects and Computational Neuroscience

The 21st century has seen the emergence of ambitious international initiatives aimed at mapping and simulating the brain at unprecedented scales, leveraging advances in neuroimaging, high-performance computing, and big data analytics. These global brain projects represent a shift toward integrative, multidisciplinary approaches in neuroscience, combining experimental data with computational models to unravel the brain's structural and functional organization. Key efforts, such as the Human Connectome Project and the BRAIN Initiative, have mobilized substantial public funding to create comprehensive brain atlases, while European counterparts like the Human Brain Project have focused on digital simulations. These projects not only accelerate discovery but also foster collaborations across institutions, emphasizing open data sharing to drive progress in understanding neural circuits and their relation to cognition and behavior.^[83]^[84]^[85] The Human Connectome Project (HCP), launched in 2010 under the auspices of the U.S. National Institutes of Health (NIH), sought to map the brain's macroscale structural and functional connections in healthy adults using advanced imaging techniques. With an initial $30 million investment from the NIH Blueprint for Neuroscience Research, the project employed diffusion magnetic resonance imaging (dMRI) to trace white matter tracts and resting-state functional MRI (fMRI) to identify correlated activity patterns across networks. Over its phases, the HCP collected high-resolution data from over 1,200 subjects, enabling the creation of a publicly accessible database that has facilitated studies on individual variability in brain connectivity and its links to behavior. This resource has been instrumental in advancing connectomics, the comprehensive mapping of neural connections, and has influenced subsequent large-scale neuroimaging efforts.^[86]^[87]^[83] Building on such foundations, the BRAIN Initiative, announced by President Obama in 2013 and led by the NIH, has funded multi-billion-dollar efforts to develop innovative technologies for brain mapping, recording, and simulation. As of 2025, the initiative has invested over $3 billion across more than 1,300 projects, though facing budget reductions in recent years (e.g., FY2025 allocation of $321 million), supporting tools for large-scale neural circuit analysis and integration of multimodal data. Complementing this, the European Union's Human Brain Project (HBP), also initiated in 2013 and concluding in 2023, allocated €607 million to construct a unified research infrastructure for simulating brain structure and function. The HBP emphasized multiscale modeling, from molecular to systems levels, and developed the EBRAINS platform for data sharing and collaborative simulation. Following the HBP's end, the EBRAINS infrastructure has continued to evolve through the EBRAINS 2.0 project, providing ongoing data sharing and simulation tools as of 2025. Together, these initiatives have spurred advancements in whole-brain modeling, with the BRAIN Initiative prioritizing technology development and the HBP focusing on computational integration to bridge experimental neuroscience with predictive simulations.^[88]^[84]^[89]^[90]^[91] Pioneering computational neuroscience, the Blue Brain Project, founded in 2005 by Henry Markram at the École Polytechnique Fédérale de Lausanne (EPFL), has aimed to create biologically detailed digital reconstructions of mammalian brain regions. Starting with the rat neocortical column, the project reverse-engineered cellular and synaptic properties using electron microscopy data and supercomputing to simulate neural activity at the subcellular level. Integrated into the HBP from 2013, Blue Brain's efforts produced the first large-scale, data-driven models of cortical microcircuits, demonstrating emergent properties like synchronized oscillations. These reconstructions have provided a framework for testing hypotheses about neural information processing and have advanced simulation neuroscience as a tool for hypothesis generation in brain research.^[92]^[93]^[94] Advances in connectomics have accelerated through these projects, culminating in the complete mapping of simpler brains to inform human-scale efforts. In 2024, the FlyWire consortium, building on efforts from 2023, achieved a milestone by publishing the full connectome of an adult female fruit fly (Drosophila melanogaster) brain, comprising 139,255 neurons and over 50 million synapses derived from high-resolution electron microscopy. This dataset, released publicly via the FlyWire platform, reveals detailed wiring patterns and has enabled analyses of circuit motifs underlying behaviors like navigation and learning. Such invertebrate connectomes serve as benchmarks for validating mapping techniques and computational models applicable to vertebrate brains.^[95]^[96]^[97] The intersections between computational neuroscience and artificial intelligence (AI) have intensified in the 2010s and 2020s, with deep learning architectures drawing inspiration from biological neural networks to model brain-like processing. Convolutional neural networks (CNNs), for instance, emulate hierarchical feature detection in the visual cortex, as seen in seminal works like AlexNet (2012), which revolutionized image recognition by mimicking ventral stream processing. These AI models have reciprocally aided neuroscience by analyzing large-scale imaging data from projects like HCP and BRAIN, improving segmentation and connectivity inference. This bidirectional synergy has led to hybrid approaches, such as neuromorphic computing, enhancing both AI efficiency and insights into neural computation.^[98]^[99]^[100]

Institutions and Professionalization

Early Institutes

The establishment of dedicated research centers in the late 19th and early 20th centuries marked a pivotal shift toward specialized neuroscience investigation, transitioning from individual scholarly pursuits to institutionalized efforts focused on the structure and function of the nervous system. One of the earliest such institutions was the Institute for Anatomy and Physiology of the Central Nervous System in Vienna, founded in 1882 by Heinrich Obersteiner.^[101] This institute, later known as the Neurological Institute or Obersteiner Institute, emerged as a leading hub for neuroanatomical and neurophysiological studies, emphasizing the morphology and pathology of the nervous system under the influence of Viennese medical traditions.^[101] Obersteiner's work there integrated clinical neurology with experimental approaches, fostering advancements in understanding neural pathways and localization of brain functions.^[102] Building on this European foundation, the Montreal Neurological Institute (MNI), founded in 1934 by neurosurgeon Wilder Penfield, represented a North American milestone in integrated brain research and clinical care.^[103] Supported by a $1.2 million grant from the Rockefeller Foundation, the MNI was designed as a comprehensive center for studying neurological disorders, particularly epilepsy, where Penfield developed innovative surgical mapping techniques to identify seizure origins in the brain.^[103] Over its early decades, the institute pioneered the "Montreal Procedure" for epilepsy treatment and advanced electrocorticography for intraoperative brain mapping, treating thousands of patients and establishing protocols adopted worldwide.^[103] In post-war Germany, the Max Planck Institute for Brain Research solidified the continuity of European neuroscience traditions when it was formally established in 1948 as part of the Max Planck Society.^[104] Evolving from the Kaiser Wilhelm Institute for Brain Research—originally founded in 1914 and disrupted by World War II—the institute reunified scattered departments from five West German cities into a new Frankfurt facility in 1962, focusing on neuroanatomy, neurophysiology, and comparative brain studies.^[104] This relocation and reorganization preserved expertise in neural morphology amid the era's challenges, enabling sustained research into brain evolution and function.^[105] These early institutes played a crucial role in training and networking a generation of neuroscientists, serving as intellectual crossroads that influenced foundational figures like Santiago Ramón y Cajal and Charles Sherrington through collaborations and exchanges. Obersteiner's Vienna institute hosted international visitors and alumni who engaged with Cajal's neuron doctrine during key meetings, advancing synaptic theory and neural integration concepts.^[106] The World Wars profoundly disrupted these institutions, prompting relocations, funding shifts, and reconstruction efforts that reshaped global neuroscience. World War II devastated many Kaiser Wilhelm Society facilities, including brain research centers, leading to the death or emigration of scientists to Allied countries and the dispersal of assets to avoid Soviet occupation.^[107] In response, post-1945 rebuilding in West Germany relied on foundations like the Volkswagen Foundation for the Max Planck Society's revival, while U.S. and British funding supported relocated experts, ultimately accelerating international collaboration in neural research by the 1950s.^[107]

Modern Organizations and Societies

The Society for Neuroscience (SfN), founded in 1969 in the United States by a group of pioneering researchers including Ralph W. Gerard, has become the world's largest organization dedicated to advancing brain research.^[108] Initially starting with just 20 members, SfN has grown to nearly 35,000 members from over 95 countries by the mid-2020s, fostering interdisciplinary collaboration among scientists, clinicians, and educators.^[108] The society hosts an annual meeting, such as Neuroscience 2025 in San Diego, which attracts over 30,000 attendees and serves as a premier platform for presenting cutting-edge research, networking, and policy discussions.^[109] Established in 1961 under the auspices of UNESCO, the International Brain Research Organization (IBRO) emerged as the first global federation of neuroscience societies to promote international cooperation amid Cold War tensions. IBRO's mission focuses on supporting neuroscience worldwide through training programs, funding for early-career researchers in low- and middle-income countries, and organizing world congresses that facilitate knowledge exchange across diverse regions. By coordinating efforts among over 90 member societies, IBRO has played a key role in building a unified global neuroscience community, emphasizing equitable access to resources and ethical standards in research. In 2008, the Kavli Prize for Neuroscience was inaugurated as part of the broader Kavli Prizes, established in 2005 by the Kavli Foundation in partnership with the Norwegian Academy of Science and Letters and the Norwegian Ministry of Education and Research.^[110] Awarded biennially, the prize recognizes outstanding scientific advances in understanding the neural basis of cognition, perception, or neural systems, with each laureate receiving one million U.S. dollars. Notable recipients include the 2014 winners for discoveries relating to the neural basis of spatial memory, navigation, and the neural circuitry of cognitive functions^[111] and the 2022 honorees for pioneering the discovery of the genetic causes of intellectual disability and autism spectrum disorders.^[112] Efforts to address gender equity in neuroscience gained momentum with the founding of Women in Neuroscience (WIN) in 1980 as an affiliate of SfN, aimed at promoting the professional advancement of women through mentorship, advocacy, and visibility initiatives.^[113] WIN provides resources such as networking events, career development workshops, and studies on gender disparities in academia, helping to increase women's representation in leadership roles within the field.^[114] Similar organizations, including regional chapters and international groups like the European Dana Alliance for the Brain's women-focused programs, have built on this foundation to tackle systemic barriers and foster inclusive environments. The rise of neuroethics in the 2000s prompted neuroscience organizations to establish dedicated committees addressing ethical challenges posed by advances in brain research, such as neuroimaging and neuroenhancement.^[115] The International Neuroethics Society (INS), founded in 2006 following a 2002 foundational conference, serves as a key body for examining the ethical, legal, and social implications of neuroscience, organizing annual meetings and publishing guidelines on issues like privacy in brain data.^[116] SfN and IBRO have integrated neuroethics into their frameworks, forming internal committees in the early 2000s to guide responsible research practices and public engagement.^[117] These efforts also support broader initiatives, such as the BRAIN Initiative, by advocating for ethical standards in large-scale brain mapping projects.^[118]

References

[1]
History of Neuroscience
460-379 BC - Hippocrates states that the brain is involved with sensation and is the seat of intelligenceto 1500 AD · to 1600 AD · to 1700 AD · to 1800 AD
[2]
History of Neuroscience
Timeline ; Plato 427-347 bc. [Mind-Brain] ; Aristotle 384-322 bc. [Mind-Brain] ; Galen 130-200 ad. [Neural Communication].
[3]
Why Study the History of Neuroscience? - PMC - NIH
May 22, 2019 · The history of neuroscience is the memory of the discipline and this memory depends on the study of the present traces of the past.
[4]
Editorial: History of Neuroscience - Frontiers
The History of Neuroscience is a vital field of research inquiry which brings into perspective the scholarship of the past and provides new insights into our ...Editorial · History of Neuroscience—The... · The Individual Contributions to...
[5]
History and Neuroscience: An Integrative Legacy | Isis: Vol 105, No 1
A vision of neural science and medicine that connected reductionist science to broader inquiries about the mind, brain, and human nature.
[6]
Imhotep and the Discovery of Cerebrospinal Fluid - PMC - NIH
Feb 21, 2014 · Herbowski (2013) suggested recently the Egyptian Imhotep from the 3rd dynasty in Egypt to be the discoverer of cerebrospinal fluid.
[7]
Relevance of Imhotep and the Edwin Smith Papyrus - PubMed
History of Occupational Medicine: Relevance of Imhotep and the Edwin Smith Papyrus. Br J Ind Med. 1987 Jan;44(1):68-70. doi: 10.1136/oem.44.1.68.
[8]
Human senses and sensors from Aristotle to the present - PMC
Jul 3, 2024 · Egypt/Mesopotamia. The cardiocentric view that the heart rather than the brain is the seat of the soul and the center of emotions, cognition, ...2. Historical Review · 2.1. 3. Aristotle · 2.4. Proprioception And Pain...<|control11|><|separator|>
[9]
Stroke in Ancient Mesopotamia - PMC - NIH
The Mesopotamians had noticed and documented vascular disorders of the brain and some pertinent diseases. The ašu and the āšipu demonstrated an observational ...
[10]
Neuroscience for Kids - Ancient "Brain" - University of Washington
The surgical papyrus is named after Edwin Smith, an American Egyptologist who was born in 1822 and died in 1906. On January 20, 1862 in the city of Luxor, Smith ...
[11]
OIP 3. The Edwin Smith Surgical Papyrus, Volume 1
The Edwin Smith Surgical Papyrus, the most important document in the history of science surviving from the pre-Greek age of mankind (seventeenth century bc).
[12]
The Edwin Smith surgical papyrus: description and analysis of the ...
The Edwin Smith surgical papyrus, which dates back nearly five millennia, is the oldest known medical text and contains the first written example of the ...
[13]
The Edwin Smith papyrus: a clinical reappraisal of the oldest known ...
In the head injury cases, neck stiffness is attributed by the Egyptian physicians to what amounts, in our terms, meningismus from traumatic subarachnoid ...
[14]
The Rise and Fall of Human Dissection in Hellenistic Alexandria
Advancements in the study of human anatomy were inhibited by religious taboos that prevented the practice of human dissection. These taboos took hold of Greek ...
[15]
Alcmaeon - Stanford Encyclopedia of Philosophy
Apr 10, 2003 · He was the first to identify the brain as the seat of understanding and to distinguish understanding from perception. Alcmaeon thought that the ...
[16]
The History of Epilepsy: From Ancient Mystery to Modern ...
Mar 17, 2021 · Distinguishing themselves from the Mesopotamians, who believed spirits and gods were the cause of seizures, the Egyptians proved that seizures ...
[17]
Greek anatomist herophilus: the father of anatomy - PMC - NIH
Herophilus named the meninges and ventricles in the brain, appreciated the division between cerebellum and cerebrum and recognized that the brain was the ...Missing: torcular | Show results with:torcular
[18]
The Neuroanatomy of Herophilus - Karger Publishers
Feb 23, 2013 · From cadaveric dissections and possibly vivisection Herophilus considered the ventricles to be the seat of the soul, intelligence and mental functions.
[19]
https://oxfordre.com/classics/display/10.1093/acrefore/9780199381135.001.0001/acrefore-9780199381135-e-2476
[20]
Herophilus, Erasistratus, Aretaeus, and Galen: ancient roots of the ...
According to Galen, what Herophilus and Erasistratus did not do was define “the beginnings of the nerves that reach each part.” In Galen's mind, this was the ...
[21]
The cerebral ventricles, the animal spirits and the dawn of brain ...
This paper reviews the early history of brain localization of function. It analyses the doctrines professed in ancient times by philosophers and physicians.
[22]
The anatomical and neuroanatomical concepts of Galen
Within the brain, Galen distinguished three ventricles, considering both lateral ventricles as a single chamber. He regarded the brain as the seat of the soul. ...
[23]
History The Ancient Greek discovery of the nervous system
Alcmaeon argued that the brain is the seat of intelligence, connected to the extremities of the body by poroi. ... Alcmaeon of Croton and his theory of the brain.
[24]
An untold story: The important contributions of Muslim scholars for ...
Nov 22, 2016 · Arab, Persian, and Christian scholars, like Hunayn ibn Ishaq who translated more than 129 works of Galen, were part of this educational ...
[25]
The Epic of the Thalamus in Anatomical Language - PMC
Oct 7, 2021 · De Anatomicis Administrationibus and De Usu Partium, like many other works by Galen, were translated into Syriac by Hunayn ibn Ishaq at the ...
[26]
The Air of History Part III: The Golden Age in Arab Islamic Medicine ...
The Golden Age in Arab Islamic medicine was influenced by the Islamic faith, learning institutions, Caliph support, and the translation of ancient works.Missing: neuroscience | Show results with:neuroscience
[27]
Introductory Chapter: Seizures and Its Historical Background
May 2, 2018 · The most famous medieval Islamic writers were Abu Bakr Muhammad Ibn Zakariya al-Razi ... epilepsy in comparison with apoplexy and hysteria [22].
[28]
Al-Zahrawi (936-1013 AD): On the Surgical Treatment of ... - PubMed
In this article, we focus for on the contributions of al-Zahrawi toward the treatment of neurological disorders in the surgical chapters of his medical ...
[29]
Abu Al Qasim Al Zahrawi (Albucasis): Pioneer of Modern Surgery - NIH
Al Zahrawi contributed early descriptions of neurosurgical diagnoses and treatment including management of head injuries, skull fractures, spinal injuries and ...
[30]
Al-Zahrawi and Arabian neurosurgery, 936–1013 ad - ScienceDirect
The authors highlight the neurosurgical contributions of an Arabic surgeon by the name of Abul-Qasim Al-Zahrawi, known in Western literature as Abulcasis.
[31]
The Structure and Function of the Central Nervous System and ...
Jan 18, 2017 · In the current vignette, we present an analysis of the basic anatomy of the brain, spinal cord and some sense organs as presented in the Canon ...
[32]
[PDF] revisiting avicenna's (ad 980–1037) anatomical concepts of the ...
Avicenna proposed that cranial nerves consisted of seven pairs of nerves excluding the olfactory nerve [18‑20, 30, 31].
[33]
[PDF] The Structure and Function of the Central Nervous System and ...
In the current vignette, we present an analysis of the basic anatomy of the brain, spinal cord and some sense organs as presented in the. Canon of medicine and ...
[34]
Islamic Golden Age (SC) – Revisiting the History of Psychology
To provide evidence of his theories, he created rigorous experimental methods, including systematic observation and repetition, which closely resemble the ...
[35]
The rich heritage of anatomical texts during Renaissance and ... - NIH
It was Vesalius who first held the dissection knife in his own hand, conducted the dissections all by himself and through his observations initiated the ...
[36]
The Representation of the Rete Mirabile in Early Modern Anatomy
In 1543, in the Fabrica, Vesalius criticized other physicians for their blind belief in Galen's account of the “wonderful plexus reticularis” (i.e. the rete ...
[37]
Overview of the History of the Cranial Nerves: From Galen to the ...
Nov 9, 2018 · After Vesalius, during the sixteenth and seventeenth centuries many different anatomists improved the descriptions of the cranial nerves, but ...
[38]
The giant anatomist, whose value is later understood: Bartolomeo ...
Mar 5, 2019 · He is the first who described the structure of the dental pulp, periodontal membrane, thoracic duct, abducens nerve, and adrenal glands [1,2,3] ...
[39]
Bartolomeo Eustachio of the Anatomical Trinity - Hektoen International
Jul 1, 2019 · The overall work consists of six parts, describing the kidneys, inner ear, teeth, bones, head, and vena azygos. In them he describes not only ...
[40]
The Role Print Played on the Study of Human Anatomy - UBC Blogs
Nov 7, 2010 · The printing press gave the general public access to knowledge in books that had not been available to them previously, resulting in increased ...
[41]
Medieval and Renaissance anatomists: The printing and ...
Although Vesalii found such piracy frustrating and annoying, the long-term effect was to make Vesalii's ideas known to a wider readership and to help solidify ...
[42]
Leonardo da Vinci, Neuroscientist | Scientific American
Mar 1, 2017 · As part of his extensive anatomical explorations, Leonardo injected wax into ox brains to make casts of the ventricles, which he then sketched.
[43]
Leonardo da Vinci's studies of the brain - ScienceDirect.com
Apr 12, 2019 · His earliest surviving anatomical drawings (circa 1485–93) included studies of the skull, brain, and cerebral ventricles.
[44]
Andreas Vesalius: Celebrating 500 years of dissecting nature - PMC
Vesalius, considered as the founder of modern anatomy, had profoundly changed not only human anatomy, but also the intellectual structure of medicine.
[45]
Irritability and Sensibility: Key Concepts in Assessing the Medical ...
Dec 1, 2008 · Albrecht von Haller was an active researcher. An assiduous and systematic experimenter, he contributed to establishing the bases of physiology.
[46]
Robert Whytt and the pupils - PubMed
Whytt recognise the peripheral neural mechanisms of the reflex arc and demonstrated that its central element occurred in a limited segment of the neuraxis, ...Missing: 1760s scholarly sources
[47]
The Long Journey from Animal Electricity to the Discovery of Ion ...
Abstract. This retrospective begins with Galvani's experiments on frogs at the end of the 18th century and his discovery of 'animal electricity'.
[48]
Re-establishing Broca's Initial Findings - PMC - NIH
Broca's original work (Broca, 1861,1863) revealed that his descriptions of Leborgne's speech were much more akin to today's understanding of apraxia of ...Missing: source | Show results with:source
[49]
Neuroanatomy, Wernicke Area - StatPearls - NCBI Bookshelf
Jul 24, 2023 · Wernicke area was first discovered in 1874 by a German neurologist, Carl Wernicke. It has been identified as 1 of 2 areas found in the cerebral ...
[50]
Theodor Schwann (1810–1882) - PMC - NIH
In the book, Schwann precisely described the myelinated nerve fiber. His research led to the discovery of the cell that produces the myelin sheath that envelops ...Missing: 1840s | Show results with:1840s
[51]
The Discovery of the Cell of Schwann in 1839 - Semantic Scholar
Theodor Schwann described for the first time those cells of the peripheral nerve fibers which ever since have been known by his name, and as the fruit of ...
[52]
Carl Wernicke of the Wernicke Area: A Historical Review
The Wernicke area, also known as Brodmann area 22, is located in the posterior segment of the superior temporal gyrus in the dominant hemisphere. Carl ...
[53]
Jean-Martin Charcot: The Father of Neurology - PMC - NIH
The first description of multiple sclerosis (MS) dates back to the 14th century, but it was Charcot and the use of the anatomoclinical method that made the ...
[54]
Speed read: Exposing the forest - NobelPrize.org
Sep 16, 2009 · The 1906 Nobel Prize in Physiology or Medicine was awarded to Camillo Golgi and Santiago Ramón y Cajal for revealing the inner beauty of the nervous system.
[55]
Golgi and Cajal: The neuron doctrine and the 100th anniversary of ...
Mar 7, 2006 · But it was not until 1906 that Golgi shared the prize with Santiago Ramón y Cajal. For the first time the prize was shared between two people.
[56]
origins of the neuron doctrine and its current status - PubMed - NIH
The neuron doctrine represents nerve cells as polarized structures that contact each other at specialized (synaptic) junctions.
[57]
from Sherrington to the molecular biology of the synapse and beyond
The term was introduced by Charles Sherrington in 1897. The centenary of this event is an appropriate time to review the term's origins and utility.
[58]
Sir Charles Sherrington's The integrative action of the nervous system
Apr 1, 2007 · In 1906 Sir Charles Sherrington published The Integrative Action of the Nervous System ... Recruitment and some other factors of reflex inhibition.
[59]
From Bernstein's rheotome to Neher‐Sakmann's patch electrode ...
Jan 3, 2019 · The period covered starts with Bernstein's formulation of the membrane hypothesis and the measurement of the nerve and muscle action potential.
[60]
Edgar Adrian – Facts - NobelPrize.org
Edgar Adrian developed methods for measuring electrical signals in the nervous system, and in 1928 he found that these always have a certain size.Missing: single potentials 1920s<|separator|>
[61]
Henry Dale and the Discovery of Chemical Synaptic Transmission
Jul 16, 2008 · Henry Dale received the Nobel prize in physiology or medicine in 1936 with Otto Loewi for their research which proved chemical synaptic transmission in the ...
[62]
Hans Berger (1873–1941), Richard Caton (1842–1926), and ...
Hans Berger recorded the first human electroencephalograms (EEGs) in 1924. He obtained his medical degree from the University of Jena, Germany, in 1897.
[63]
A color-coded graphical guide to the Hodgkin and Huxley papers
The five papers published by Hodgkin and Huxley in 1952 are seminal works in the field of physiology, earning their authors the Nobel Prize in 1963 and ...Missing: primary | Show results with:primary<|separator|>
[64]
Penfield – A great explorer of psyche-soma-neuroscience - PMC
His surgical studies yielded reports on brain tumours, the pial circulation, the mechanisms of headache, the localization of motor, sensory and speech functions ...
[65]
Wilder Penfield redrew the map of the brain — by opening the heads ...
Jan 26, 2018 · Penfield developed the method, called the “Montreal Procedure,” in the 1930s. It helped him pinpoint the source of the seizure in the brain so he could remove ...
[66]
The discovery of GABA in the brain - PMC - PubMed Central
Dec 7, 2018 · GABA's activity in the brain was eventually clarified in 1957 when researchers in Canada reported that an unknown compound having inhibitory ...
[67]
[PDF] Eric R. Kandel - Nobel Lecture
Spaced repetition converts short-term memory into long-term memory in Aplysia. ... This was a major ad- vance and opened up the study of synaptic plasticity in ...Missing: 1970s | Show results with:1970s
[68]
The molecular biology of memory storage: a dialogue between ...
The molecular biology of memory storage: a dialogue between genes and synapses. Science ... Signal Transduction; Synapses / physiology*; Synaptic Transmission ...
[69]
The Nobel Prize in Physiology or Medicine 2000 - Press release
Eric Kandel, Center for Neurobiology and Behavior, Columbia University, New York, is rewarded for his discoveries of how the efficiency of synapses can be ...
[70]
How CT happened: the early development of medical computed ...
Only 15 samples were scanned on the lathe bed scanner before the decision, in January, 1970, to build a clinical prototype for installation at Atkinson Morley ...
[71]
NIHF Inductee Godfrey Hounsfield, Who Invented the CT Scan
Godfrey Hounsfield invented the CT scan, using an X-ray scanner to create 3D images of the head, which revolutionized medical care.
[72]
PET and CT: a perfect fit - CERN Courier
Jun 6, 2005 · In 1975, M Ter-Pogossian, M E Phelps and E Hoffman at Washington University in St Louis presented their first PET tomograph, known as Positron ...
[73]
Millisecond-timescale, genetically targeted optical control of neural ...
Aug 14, 2005 · We demonstrate reliable, millisecond-timescale control of neuronal spiking, as well as control of excitatory and inhibitory synaptic transmission.Missing: seminal | Show results with:seminal
[74]
Ed Boyden: A light switch for neurons - TED Talks
May 15, 2011 · With this unprecedented level of control, he's managed to cure mice of analogs of PTSD and certain forms of blindness. On the horizon ...
[75]
Neuralink — Pioneering Brain Computer Interfaces
Creating a generalized brain interface to restore autonomy to those with unmet medical needs today and unlock human potential tomorrow.Careers · Technology · Clinical Trials · UpdatesMissing: 2016 history
[76]
Therapeutic potential of appropriately evaluated safe-induced ...
Jul 6, 2010 · Here we show the directed neural differentiation of murine iPS cells and examine their therapeutic potential in a mouse spinal cord injury (SCI) model.Results · Safe Mef-Ips Cells Can... · Spinal Cord Injury Model And...<|control11|><|separator|>
[77]
Applications of CRISPR-Cas systems in neuroscience - PMC
CRISPR-Cas enables new model systems for studying the nervous system, advancing research on synaptic function, neuronal development, and diseases.
[78]
Human Connectome Project (HCP) - National Institute of Mental ...
The Human Connectome Project (HCP) aimed to map the macroscale connections of the human brain. Macroscale connections are pathways created by bundles of nerve ...
[79]
https://www.ted.com/talks/ed_boyden_a_light_switch_for_neurons
[80]
Overview - Human Brain Project
To tame brain complexity, the project is building a research infrastructure to help advance neuroscience, medicine, computing and brain-inspired technologies - ...
[81]
NIH Launches the Human Connectome Project to Unravel the ...
Jul 16, 2009 · The National Institutes of Health Blueprint for Neuroscience Research is launching a $30 million project that will use cutting-edge brain ...
[82]
The Human Connectome Project: A data acquisition perspective
The Human Connectome Project (HCP) is an ambitious 5-year effort to characterize brain connectivity and function and their variability in healthy adults.
[83]
The BRAIN Initiative® and NIDCD
Feb 6, 2025 · Since 2014, the BRAIN Initiative has invested more than $3 billion to fund more than 1,300 projects. Funded Awards in NIDCD Mission Areas. A ...Missing: total | Show results with:total
[84]
Human Brain Project celebrates successful conclusion
Sep 12, 2023 · The HBP was one of the first flagship projects and, with 155 cooperating institutions from 19 countries and a total budget of 607 million euros, ...
[85]
Blue Brain Project ‐ EPFL
Led by Founder and Director Professor Henry Markram, Blue Brain established simulation neuroscience as a complementary approach to understanding the brain ...Blue Brain Portal · Blue Brain’s Scientific Milestones · Research · In brief
[86]
About – Blue Brain Project
EPFL's Blue Brain Project is a Swiss brain research Initiative led by Founder and Director Professor Henry Markram. The aim of Blue Brain is to establish ...
[87]
The blue brain project: pioneering the frontier of brain simulation
Nov 2, 2023 · One such project is the Blue Brain Project, which is spearheaded by Henry Markram at the École Polytechnique Fédérale de Lausanne (EPFL) ...
[88]
Neuronal wiring diagram of an adult brain - Nature
Oct 2, 2024 · Although FlyWire is currently the only adult fly connectome, it can be compared with the hemibrain reconstruction in regions where they ...
[89]
FlyWire
Whole-Brain Connectome of an adult female Drosophila. AI-segmented, expert-proofread neurons with millions of connections, crowdsourced labels, and ...Brain · FlyWire · Brain & Nerve Cord · Codex
[90]
Complete wiring map of an adult fruit fly brain - NIH
Oct 22, 2024 · Scientists built a neuron-by-neuron and synapse-by-synapse roadmap, called a connectome, of the entire brain of an adult fruit fly.Missing: 2023 | Show results with:2023
[91]
Artificial Neural Networks for Neuroscientists: A Primer - PMC
SUMMARY. Artificial neural networks (ANNs) are essential tools in machine learning that have drawn increasing attention in neuroscience.Missing: 2020s | Show results with:2020s
[92]
Toward an Integration of Deep Learning and Neuroscience - Frontiers
We will argue here, however, that neuroscience and machine learning are again ripe for convergence. Three aspects of machine learning are particularly important ...Missing: seminal | Show results with:seminal
[93]
A short history of neurosciences in Austria - PubMed
Meynert (1833-1892) the activator, and H. Obersteiner (1847-1922) as the founder of the Vienna Neurological Institute, presented basic contributions to the ...
[94]
Heinrich Obersteiner and his contributions - PubMed
Heinrich Obersteiner (1847-1921) was amongst the most influential neuroscientists in the 19th century. Born into a family of physicians, he gained early ...Missing: 1887 | Show results with:1887
[95]
A storied history | The Neuro - McGill University
Since its founding in 1934 by renowned neurosurgeon Dr. Wilder Penfield, The Neuro has grown to be the largest specialized neuroscience research and clinical ...
[96]
History of the Max Planck Society
A new building for the MPI for Brain Research (1961). The Max Planck Institute for Brain Research moved into a new building in Frankfurt in 1961, marking the ...Missing: evolution labs
[97]
On the history of neuroscience research in the Max Planck Society ...
Mar 22, 2023 · This special issue of the Journal of the History of the Neurosciences is composed of an introduction, five articles, and two neuroscience history interviews.
[98]
Cajal's Interactions with Sherrington and the Croonian Lecture
Jun 6, 2019 · We review here some of the scientific exchanges between Cajal and Sherrington, with particular attention to 1894, when the two neuroscientist met in London.Missing: early | Show results with:early
[99]
Bringing Back Neurology Following WWII
Oct 29, 2017 · A prominent example is the former Institute for Brain Research of the KWG, headed by neuroanatomist Oskar Vogt (1870-1959) and his wife Cécile ...Missing: evolution physiological
[100]
Society for Neuroscience - About - SfN
Founded in 1969, the Society for Neuroscience (SfN) has over 30,000 members in more than 95 countries.
[101]
Society for Neuroscience - Neuroscience 2025 - SfN
Meeting Dates: Saturday, November 15–Wednesday, November 19. Location: San Diego Convention Center. We must continue to do the important work of science, ...Dates and Deadlines · Membership · Sessions and Events · Housing and Travel
[102]
The Kavli Prize - Kavli Foundation
Established in 2005, The Kavli Prize is a partnership among The Kavli Foundation, The Norwegian Academy of Science and Letters, and The Norwegian Ministry of ...
[103]
[PDF] a history of the Society for Neuroscience - SfN
The founding of the SfN in 1969 signaled a reversal of this trend and the beginning of a new era. Just seven years earlier, Francis O. Schmitt had used the term ...
[104]
Women in neuroscience (WIN): the first twenty years - PubMed
WIN was created in 1980, when despite major changes and advances in 'equal opportunities', women were still not achieving a proportionate level of success in ...Missing: date | Show results with:date
[105]
The First Neuroethics Meeting: Then and Now - PubMed Central - NIH
The field of neuroethics has flourished in the 15 years since the 2002 landmark conference, “Neuroethics: Mapping the Field,” and its subsequent publication-- ...
[106]
About - International Neuroethics Society
The decision to start a neuroethics society came out of a small meeting held in Asilomar, California in May 2002. Until that time, people interested in ...Missing: date | Show results with:date
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[PDF] SHORT COURSE 3 - Neuroethics and Public Engagement - SfN
From the late 2000s, the field of neuroethics has grown, supported by foundational books (Illes, 2006; Levy, 2007; Farah, 2010; Racine. 2010; Illes and Sahakian ...
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Background Information on Neuroethics - NCBI - NIH
The Declaration, amended several times, most recently in 2000…, is a comprehensive international statement of the ethics of research involving human subjects.