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Inferior colliculus

The (IC) is a paired structure located on the surface of the rostral , functioning as the primary subcortical relay and center for ascending auditory information from the to the and . It receives convergent inputs from lower auditory nuclei, such as the cochlear nuclei and , enabling the processing of , discrimination, and through . Anatomically, the IC forms part of the tectum, caudal to the superior colliculi and to the , and is organized into three main subdivisions: the central nucleus (tonotopically organized for core auditory processing), the cortex (involved in broader frequency tuning), and the external cortex (which incorporates non-lemniscal inputs). The IC's efferent projections primarily travel via the brachium of the IC to the medial geniculate nucleus of the thalamus, ensuring organized relay of auditory signals, while descending connections from the auditory cortex allow for top-down modulation. Beyond its fundamental role in audition, the IC integrates multisensory signals, including visual cues from the retina and somatosensory inputs from the spinal trigeminal nucleus, to refine spatial hearing and behavioral responses such as head orientation. Emerging evidence also implicates the IC in higher cognitive functions, such as sensory prediction during auditory tasks, reward anticipation, and decision-making correlated with behavioral choices in primates. Clinically, disruptions to the IC—through lesions, tumors, or vascular issues—can result in auditory impairments like tinnitus, hyperacusis, sound localization deficits, and even audiogenic seizures, underscoring its critical position in the auditory pathway.

Anatomy

Location and gross morphology

The inferior colliculus comprises a pair of ovoid nuclei that form the inferior tectal bulges, appearing as symmetrical rounded prominences on the posterior surface of the tectum. These structures are part of the corpora quadrigemina, separated from the superior colliculi by the cruciform sulcus, and contribute to the overall quadrigeminal plate. Positioned in the caudal , the inferior colliculus lies immediately caudal to the and at the level of the , with the emerging just inferior to it. It is situated dorsal to the and medial to the , while its lateral boundary is defined by the brachium of the inferior colliculus, which extends laterally toward the medial geniculate body. In humans, the inferior colliculus is a small structure with a maximum dimension of less than 9 mm, typically measuring approximately 5 mm in rostrocaudal length, and is prominently visible as a paired bulge on midsagittal sections of the brainstem. The structure is positioned ventral to the and superior to the , integrating seamlessly with the surrounding architecture.

Subdivisions and cellular organization

The inferior colliculus (IC) is subdivided into three primary regions: the central nucleus (CNIC), dorsal cortex (DCIC), and external cortex (ECIC), each exhibiting distinct structural and cellular features that contribute to auditory processing. The CNIC forms the core of the IC, comprising a disk-shaped structure with layered fibrodendritic laminae that are oriented orthogonally to the tonotopic axis. These laminae organize neurons in a tonotopic manner, with low frequencies represented in the dorsolateral regions and high frequencies in the ventromedial areas. The DCIC, located dorsal to the CNIC, forms a shell-like region with a laminar parallel to the IC surface and broader tuning compared to the core. The ECIC, positioned laterally, serves as a area with less strict tonotopic and integrates non-auditory inputs alongside auditory signals. Cellular organization within the IC varies across subdivisions, with the highest neuronal density in the CNIC. In , the IC contains approximately 350,000 neurons, with over 200,000 concentrated in the CNIC, yielding densities up to around 10,000 neurons per mm³. Principal cells in the CNIC are predominantly disc-shaped or bushy neurons with flattened somata and dendrites aligned within the fibrodendritic laminae, facilitating precise frequency-specific processing. Stellate cells, characterized by multipolar somata and radiating dendrites, are prevalent throughout the IC but dominate the DCIC and ECIC, where they exhibit more diffuse orientations. , comprising 20-40% of IC neurons, provide local inhibition and are distributed across all subdivisions, with subtypes including small and multipolar cells often associated with perineuronal nets. Histological techniques reveal the IC's internal architecture effectively. Nissl staining highlights the laminar structure and neuronal somata in the CNIC, delineating its fibrodendritic layers, while (AChE) staining emphasizes input zones and accentuates subdivision boundaries. The vascular supply to the IC arises from branches of the , including the collicular artery, and the , ensuring robust perfusion to support its high metabolic demands.

Development

Embryonic formation

The originates from the alar plate of the within prosomere 1 during weeks 4-5 of gestation, as the mesencephalon differentiates from the secondary brain vesicles following closure around embryonic day 21. By embryonic day 24, the mesencephalon is established, setting the stage for dorsal alar plate derivatives including the colliculi. Its initial patterning is governed by signaling centers at the mid-hindbrain boundary, where the isthmic organizer secretes Fgf8 to induce inferior colliculus fate and restrict Otx2 expression to the territory. Complementary transcription factors Otx2 and Gbx2 establish mutual repression to define identity and position the isthmic organizer, ensuring proper of midbrain progenitors from rhombomere 1 cells as early as embryonic day 7.5 in mice (equivalent to early week 4 in humans). Disruption of Fgf8 leads to loss of medial inferior colliculus development after embryonic day 11 in mice, highlighting its role in maintaining the organizer's activity. Early involves evagination of the tectal plate, forming paired swellings that outline the prospective inferior colliculus by embryonic day 35 in humans (corresponding to embryonic day 12 in mice), when the tectal stem zone emerges proximal to the . Neuroepithelial progenitors in this zone undergo proliferative divisions regulated by FGF/ERK signaling to generate projection neurons, with sustained proliferation dependent on to prevent premature cell cycle exit. By gestational week 7, a rudimentary inferior colliculus structure is discernible in human embryos, coinciding with initial axon ingrowth from lower auditory centers such as the cochlear nuclei and . In , these ascending projections begin during late embryonic , establishing early connectivity patterns.

Postnatal maturation

The postnatal maturation of the (IC) refines its as a key auditory hub through activity-dependent processes that sharpen neural representations and enhance processing precision. Following embryonic formation, the IC undergoes significant structural and functional changes driven by sensory experience, with the central nucleus (CNIC) exhibiting progressive tonotopic organization and the dorsal cortex (DCIC) developing broader integrative capabilities. These adaptations occur during a sensitive developmental window influenced by acoustic input, ensuring alignment with environmental sound landscapes. A sensitive period for IC maturation in early infancy in humans is characterized by synaptic pruning that eliminates excess connections and refines tonotopic maps in the CNIC. This pruning process enhances frequency selectivity by reducing overlapping inputs, allowing neurons to respond more precisely to specific tones. In parallel, tonotopic sharpening occurs postnatally, with initial broad frequency representations narrowing as auditory experience guides circuit refinement. Experience-dependent plays a pivotal role during this period, modulating IC organization based on acoustic exposure. Auditory deprivation, such as from recurrent , disrupts the CNIC frequency map by altering synaptic strengths and expanding receptive fields, leading to impaired processing. Conversely, enriched auditory environments promote enhanced frequency resolution in the IC, strengthening precise neural through Hebbian mechanisms. At the cellular level, postnatal changes include myelination in the and brainstem pathways, which is largely complete by term birth and supports mature temporal processing by the first few months. inhibition matures progressively, with faster inhibitory postsynaptic potentials reducing initial broad tuning curves and enabling sharper excitatory responses in IC neurons. Growth factors like (BDNF) and (NT-3) further contribute by promoting dendritic arborization in the DCIC, expanding integrative surfaces for multisensory inputs. Maturation timelines vary across species, reflecting differences in developmental pace. In rodents, IC functional organization completes rapidly by postnatal day 21 (P21), aligning with the onset of hearing around P12 and achieving adult-like tonotopy within weeks. In contrast, primates exhibit prolonged postnatal development, extending over months to years, which allows for extended plasticity in response to complex acoustic environments.

Connectivity

Afferent inputs

The inferior colliculus (IC) receives a diverse array of afferent inputs that converge to integrate auditory and non-auditory information. Major brainstem sources include the , which provides direct anteroventral projections primarily to the central nucleus of the IC (CNIC), preserving tonotopic organization. The contributes bilateral inputs, with the lateral superior olive conveying interaural level difference cues and the medial superior olive providing interaural time difference information, targeting the CNIC via the . Additionally, the nuclei of the —specifically the dorsal and ventral nuclei—supply temporal processing signals, with the dorsal nucleus offering inhibitory projections and the ventral nucleus contributing both excitatory and inhibitory inputs. Cortical and thalamic afferents modulate IC activity through descending and ascending pathways. The primary sends descending projections from layer V neurons to the dorsal cortex of the IC (DCIC), influencing higher-order processing. Multimodal afferents expand IC function beyond audition. Somatosensory inputs from the target the DCIC, converging with auditory projections to enable integration of tactile and sound cues. Visual inputs arise from the ipsilateral , projecting to the external nucleus (ICX) to modulate auditory responses with spatial visual information. Pathway details reveal a contralateral bias in auditory inputs, with in low-frequency neurons, approximately 70% receiving their primary excitatory drive from the contralateral side via the commissure of the IC. These inputs are predominantly excitatory and , while inhibitory components are glycinergic from the lateral superior olive and from the dorsal nucleus of the . Topographic organization ensures that inputs maintain frequency-specific , particularly in the CNIC.

Efferent outputs

The central nucleus of the inferior colliculus (CNIC) serves as the primary relay for ascending auditory information, projecting primarily to the ventral division of the (MGNv) through the brachium of the inferior colliculus. These projections are tonotopically organized, preserving the frequency-specific mapping from lower auditory centers to maintain orderly representation in the . These projections to the MGN include both excitatory and inhibitory () components, with GABAergic neurons comprising 20–40% of the projecting cells. Intracollicular efferents include commissural fibers connecting the ipsilateral and contralateral inferior colliculi, primarily mediated by neurons in the external cortex of the inferior colliculus (ECIC), which facilitate bilateral of auditory signals. Local circuits within subdivisions, such as recurrent and lateral in the CNIC and ECIC, support fine-scale and modulation within the nucleus. Extracollicular projections arise mainly from the dorsal cortex of the inferior colliculus (DCIC), targeting the to contribute to orienting reflexes, the for involvement in the startle pathway, and the for feedback modulation. Additionally, inhibitory outputs from the ECIC to the CNIC provide gain control, regulating the intensity and selectivity of auditory responses.

Physiology

Neuronal properties and tonotopy

The inferior colliculus exhibits a tonotopic organization, where neurons are spatially arranged according to their preference for specific sound frequencies, reflecting the cochlea's topographic mapping. In the central nucleus (CNIC), this organization is strict and cochleotopic, with best frequencies spanning a broad range from approximately 0.2 kHz to 40 kHz across mammalian species, enabling precise representation of the auditory spectrum. In contrast, the dorsal cortex (DCIC) and external cortex (ECIC), often referred to as the shell regions, display broader tonotopy with greater overlap in frequency representations, allowing for more integrative processing of spectral information. Neurons in the inferior colliculus exhibit diverse response patterns to tonal stimuli, classified based on their peristimulus time histograms (PSTHs). Common types include onset neurons, which fire a brief burst at the start of a with minimal sustained activity (comprising about 32% of units); chopper neurons, characterized by regular, periodic firing throughout the stimulus (around 6%); and pauser neurons, featuring an initial burst followed by a short pause and then sustained (approximately 42%). tuning curves of these neurons are typically V-shaped, indicative of excitatory response areas bounded by inhibitory flanks, though shapes can vary from narrow to non-monotonic or tilted forms. Bandwidths of these curves, measured relative to , differ across subdivisions, with narrower tuning (often <1 kHz at higher intensities) in the CNIC due to stronger inhibitory sculpting, and broader bandwidths in the shell regions facilitating multisensory . Response latencies to sound onset are generally short, ranging from 5 to 20 , allowing rapid relay of auditory information through the . Many neurons demonstrate or to repeated stimuli, manifesting as stimulus-specific adaptation (SSA) where responses to frequent "standard" sounds diminish while novel "oddball" stimuli elicit stronger activity, developing rapidly and reaching maximum within 20-25 trials, with the largest differences in the onset response component up to 20 after stimulus onset and peak response latencies of 14-26 . In the DCIC, a subset of bimodal neurons integrates auditory inputs with somatosensory signals, such as pinna movements, enhancing spatial localization; these cells, comprising 5-20% of the population, show modulated firing to combined stimuli via projections from the dorsal column and trigeminal nuclei. The inferior colliculus displays high metabolic activity, particularly during auditory processing, with increased labeling observed using 2-deoxyglucose (2-DG) autoradiography.

Integration in auditory processing

The central nucleus of the inferior colliculus (CNIC) serves as a key site for integrating binaural cues to facilitate , where coincidence detector neurons compute interaural time differences (ITD) and interaural level differences (ILD) by receiving convergent excitatory and inhibitory inputs from the . These neurons exhibit maximal firing rates when inputs from the two ears coincide within narrow temporal windows, enabling the encoding of azimuthal sound positions across frequencies. In mammals, this processing refines brainstem computations, with ITD sensitivity within the physiological range of approximately ±50 μs in mice, supporting precise spatial hearing. Spectral integration in the inferior colliculus combines activity across channels to extract features of complex sounds, such as and , through nonlinear interactions that respond to structures and mistuned tones. Neurons in the CNIC exhibit broader and facilitatory sidebands that enhance responses to multi-component stimuli, contributing to the of musical intervals and vocalizations. This mechanism underpins selective in noisy environments, as seen in the cocktail party effect, where cues in the inferior colliculus aid in segregating target sounds from interferers by enhancing spatial release from masking. The inferior colliculus mediates rapid pathways by relaying processed auditory signals to downstream structures, including projections from the CNIC to the (PAG) that elicit the acoustic startle in response to intense, sudden noises, with latencies as short as 10-15 ms in . Efferent outputs to the drive orienting responses, directing gaze and head movements toward salient auditory cues via an inferior-superior colliculus circuit that modulates attention during spatial tasks. In the dorsal cortex of the inferior colliculus (DCIC), multimodal fusion integrates auditory inputs with visual and somatosensory signals, enhancing spatial awareness through convergent projections that sharpen responses to co-localized stimuli across modalities. DCIC neurons exhibit enhanced firing to pairings, supporting behaviors like prey capture in where auditory cues are aligned with visual or tactile landmarks. Computational models of ITD processing in the inferior colliculus adapt the Jeffress delay-line framework by incorporating coincidence detection with internal delays implemented via axonal branching and synaptic timing, accounting for observed neural transformations beyond the . These models predict broader ITD tuning in neurons, matching empirical data from cats and gerbils where delay lines span up to 1 ms.

Clinical significance

Lesions and deficits

Experimental lesions of the (IC) in animals have demonstrated its critical role in while preserving basic auditory detection. In cats, bilateral of the IC results in profound deficits in azimuthal sound localization, characterized by increased thresholds for interaural time differences (ITDs) and interaural level differences (ILDs), yet thresholds for sound detection and frequency discrimination remain intact. Similarly, in barn owls, electrolytic confined to the IC induce sound-localization errors, including failures to toward the sound source and misdirected turns, with the severity correlating to lesion size. Unilateral IC lesions in ferrets produce milder contralateral deficits in localization but do not significantly impair overall detection performance. Human cases of IC lesions are rare and typically arise from midbrain strokes, tumors, or hemorrhages, often leading to central auditory processing disorder (CAPD) symptoms. A 12-year-old boy with a unilateral right IC lesion exhibited normal peripheral hearing but showed impaired dichotic speech recognition when the target was presented to the left ear, deficits in duration-pattern recognition from the left ear, and contralateral sound-localization errors. In another case, a 36-year-old man with a right IC hemorrhage developed persistent left-ear tinnitus and severe impairment in contralateral sound localization without hearing loss or other major auditory thresholds affected. Bilateral IC infarction following embolization has been associated with tinnitus and reduced word recognition, indicative of disrupted binaural processing. These lesions can also contribute to hyperacusis, where normal sounds elicit discomfort due to altered central gain in auditory pathways. IC lesions disrupt auditory reflexes, particularly (PPI) of the acoustic . In rats, excitotoxic lesions of the IC significantly reduce PPI magnitude compared to controls, with impaired suppression of startle even at optimal interstimulus intervals and prepulse intensities, indicating the IC's role in sensorimotor gating circuits. This deficit arises from interrupted ascending projections that modulate startle via pontine nuclei, potentially leading to vestibular-auditory integration mismatches in more severe cases. Recovery from IC lesions is partial and relies on neural , particularly in the dorsal cortex of the (DCIC), where rerouting of inputs can compensate for core damage. In barn owls, adaptive in the external nucleus (analogous to mammalian shells) allows partial restoration of maps following lesions, driven by visual-auditory recalibration and strengthened commissural connections. In mammals, deafferentation-induced in the shells promotes synaptic reorganization, enabling some functional recovery in over weeks to months. Diagnosis of IC involvement often includes (ABR) testing, where wave IV amplitude reduction signals IC dysfunction. Ablation of the IC in animals markedly attenuates wave IV, with greater effects from contralateral stimulation, confirming its generation near or within the IC. In humans, diminished wave IV in ABR profiles, alongside preserved earlier waves, indicates selective pathology without peripheral .

Role in auditory disorders

The inferior colliculus (IC) plays a significant role in the pathophysiology of tinnitus, where hyperactivity in its neurons is observed following cochlear damage, often manifesting as central gain enhancement to compensate for reduced peripheral input. This central gain model posits that maladaptive increases in neuronal sensitivity within the IC contribute to the perception of phantom sounds, as evidenced by elevated spontaneous firing rates in animal models of noise-induced hearing loss. In these models, such as rats exposed to acoustic trauma, tonotopic map reorganization occurs in the IC, with expanded representation of low-frequency regions and reduced selectivity for high frequencies, further perpetuating tinnitus symptoms. In age-related hearing loss, or , the IC undergoes alterations in that diminish frequency resolution, leading to blurred neural representations of spectra. Studies in aged demonstrate remapping in the IC, where high-frequency hearing deficits cause shifts in best-frequency tuning, broadening receptive fields and impairing spectral discrimination. Additionally, the IC contributes to temporal processing deficits in , with reduced neural precision for detecting gaps in noise or modulating envelopes, as shown by decreased gap-detection thresholds in neurons from older CBA mice compared to young controls. These changes are linked to downregulated inhibitory neurotransmission, particularly synapses, in the IC. Noise-induced damage triggers in IC neurons, resulting in chronic maladaptive plasticity that sustains auditory dysfunction. Post-exposure, acute increases in lead to and hyperactivity in IC slices from noise-exposed mice, with long-term elevations in spontaneous activity persisting for weeks. This oxidative burden, including , disrupts normal inhibitory-excitatory balance in the IC, contributing to persistent and altered sound processing. In neurodevelopmental disorders like , the exhibits hyperactivity in response to sounds, correlating with and . Rodent models, such as valproic acid-exposed rats mimicking , show sex- and age-dependent disruptions in contextual auditory processing within the , with heightened neural responses to novel stimuli and impaired . Similarly, in models ( knockout mice), developing neurons display abnormal , characterized by increased excitatory drive and reduced inhibition, which may underlie auditory in . The inferior colliculus is critically involved in audiogenic seizures, a form of reflex triggered by high-intensity sounds, where abnormal hyperactivity and reduced inhibition in neurons initiate and propagate seizure activity, particularly in genetically -prone models. Bilateral lesions or pharmacological blockade of transmission in the IC can abolish or attenuate these seizures, highlighting its role in acoustic-motor integration underlying audiogenic . The represents a promising therapeutic target for through techniques, including (). In models of , of the suppresses behavioral indicators of phantom perception by normalizing hyperactivity and restoring tonotopic organization, with effects lasting beyond stimulation cessation; as of 2025, studies confirm reduces hyperactivity in salicylate-induced models. Electrical or bimodal targeting the has also shown potential to reduce central gain and alleviate symptoms, highlighting its role in circuit-level interventions for auditory disorders.

References

  1. [1]
    Neuroanatomy, Inferior Colliculus - StatPearls - NCBI Bookshelf
    The inferior colliculus (IC; plural: colliculi) is a paired structure in the midbrain, which serves as an important relay point for auditory information.Introduction · Structure and Function · Embryology · Blood Supply and Lymphatics
  2. [2]
    Sounds and beyond: multisensory and other non-auditory signals in ...
    The inferior colliculus (IC) is a major processing center situated mid-way along both the ascending and descending auditory pathways of the brain stem.
  3. [3]
    The multifaceted role of the inferior colliculus in sensory prediction ...
    Jan 29, 2025 · This important study presents a finding on the role of the Inferior Colliculus in sensory prediction, cognitive decision-making, and reward prediction.
  4. [4]
    The Midbrain - Colliculi - Peduncles - TeachMeAnatomy
    ### Summary of Inferior Colliculus Location and Gross Morphology
  5. [5]
    Inferior colliculus: anatomy and function - Kenhub
    The inferior colliculus, located at the posterior surface of the brainstem, is involved in auditory processing. Learn more about its anatomy now on Kenhub!
  6. [6]
    Tonotopic Organization in the Depth of Human Inferior Colliculus
    In humans, the small size of the IC (<9 mm), coupled with the limited resolution of conventional human neuroimaging studies, have precluded the non-invasive ...
  7. [7]
    Inferior Colliculus - an overview | ScienceDirect Topics
    The inferior colliculus (IC) is a principal nucleus of the midbrain tectum, forming the caudal portion of the quadrigeminal plate and situated immediately ...Anatomy, Subdivisions, and... · Functional Roles of the Inferior...
  8. [8]
    Morphological and Physiological Characteristics of Laminar Cells in ...
    The central nucleus of the inferior colliculus (IC) is organized into a series of fibro-dendritic laminae, orthogonal to the tonotopic progression.Missing: rostrocaudal human
  9. [9]
    Evidence for interactions across frequency channels in the inferior ...
    Tonotopic organization of the ICC in rodents and cats has been shown to proceed from low frequencies dorsolateral to high frequencies ventromedial (e.g. Semple ...
  10. [10]
    Structural Connectivity of Human Inferior Colliculus Subdivisions ...
    Mar 22, 2022 · Inferior colliculus (IC) is an obligatory station along the ascending auditory pathway that also has a high degree of top-down convergence ...
  11. [11]
    Immunocytochemical profiles of inferior colliculus neurons in the rat ...
    The rat IC contains about 350,000 neurons, with more than 200,000 neurons in the central nucleus alone, about 80,000 in the EIC and 45,000 in the DIC. This ...
  12. [12]
    Subtypes of GABAergic Cells in the Inferior Colliculus - PMC
    The inferior colliculus occupies a central position in ascending and descending auditory pathways. A substantial proportion of its neurons are GABAergic, ...2.1. Morphology · 2.3. 2. Perineuronal Nets... · 3.2. Gabaergic Cell Types...Missing: paper | Show results with:paper
  13. [13]
    Inferior Colliculus - an overview | ScienceDirect Topics
    The inferior colliculi are defined as smaller, flattened structures that protrude from the posterior end of the larger superior colliculi, located on the tectum ...
  14. [14]
    Functional Implications of the Prosomeric Brain Model - PMC
    ... inferior colliculus is also migrated out of r4; it is accompanied by ... Recollections on the Origins and Development of the Prosomeric Model. Front ...
  15. [15]
    Gbx2 and Fgf8 are sequentially required for formation of the ... - NIH
    FGF8 induces formation of an ectopic isthmic organizer and isthmocerebellar development via a repressive effect on Otx2 expression. Development 126, 1189 ...Gbx2 And Otx2 Cells Mutually... · Mosaic Deletion Of Gbx2... · Activation Of Fgf Signaling...
  16. [16]
    Otx2, Gbx2 and Fgf8 interact to position and maintain a ... - PubMed
    Recent experiments have shown that Otx2, Gbx2 and Fgf8 genes play a major role in the positioning and functioning of this organizing center.<|separator|>
  17. [17]
    The duration of Fgf8 isthmic organizer expression is key to ... - NIH
    Fgf8 is required after ∼E11 for development of the medial inferior colliculus and anterior-medial cerebellum ... Positioning the isthmic organizer where Otx2 and ...
  18. [18]
    Regulation of self-renewing neural progenitors by FGF/ERK ...
    The embryonic tectum displays an anteroposterior gradient in development and produces the superior colliculus and inferior colliculus.
  19. [19]
    1987 Developmental Stages In Human Embryos - Stage 20
    The inferior colliculus of the mesencephalon can be discerned (Bartelmez and Dekaban, 1962). Some optic fibers reach the optic chiasma. The choroid plexus of ...
  20. [20]
    Time Course of Embryonic Midbrain and Thalamic Auditory ...
    Here, we provide detail for the first time of the initiation and progression of projections from the inferior colliculus (IC) to the medial geniculate body (MGB) ...
  21. [21]
    Regulation of auditory plasticity during critical periods and following ...
    The dorsal CN relays directly to the inferior colliculus (IC), whereas the ventral CN first relays to the superior olivary complex (SOC), thought to be ...
  22. [22]
    Postnatal development of central auditory frequency maps
    The present review summarizes investigations of the development of tonotopy in nuclei of the central auditory system.
  23. [23]
    Developmental auditory deprivation in one ear impairs brainstem ...
    Sep 5, 2025 · Children who experience conductive hearing loss (CHL) due to otitis media ... Mechanisms of experience-dependent plasticity in the auditory ...
  24. [24]
    Central plasticity and dysfunction elicited by aural deprivation in the ...
    Experience-dependent plasticity in the auditory cortex and the inferior colliculus of bats: role of the corticofugal system. Proc. Natl. Acad. Sci. U S A 97 ...
  25. [25]
    Normal myelination | Radiology Reference Article | Radiopaedia.org
    Jun 9, 2025 · It does not reach maturity until 2 years or so. It correlates very closely to developmental milestones 3. The progression of myelination is ...Citation, Doi, Disclosures... · Radiographic Features · Mri
  26. [26]
    Postnatal development of synaptic properties of the GABAergic ...
    Abstract. The development of auditory temporal processing is important for processing complex sounds as well as for acquiring reading and language skills.Missing: review | Show results with:review<|separator|>
  27. [27]
    Distribution of BDNF, NT‐3 and NT‐4 in the developing auditory ...
    Aug 7, 2025 · In the adult, BDNF heavily labeled most neurons of the superior olivary nuclei and moderately labeled neurons of the inferior colliculus (IC).
  28. [28]
    Comparative Milestones in Rodent and Human Postnatal Central ...
    In general, altricial rodents experience greater central nervous system (CNS) immaturity at birth and accelerated postnatal development compared to humans.
  29. [29]
    The efferent projections of the central nucleus and the pericentral ...
    The efferent projections of the central nucleus of the inferior colliculus (ICC) and the pericentral nucleus of the inferior colliculus (ICP) were examined ...Missing: review | Show results with:review
  30. [30]
    Journal of Comparative Neurology - Wiley Online Library
    May 14, 2007 · One of these pathways carries information from the central nucleus of the inferior colliculus (CNIC) to the ventral division of the medial ...
  31. [31]
    Intercollicular commissural projections modulate neuronal ... - PubMed
    The right and left inferior colliculi (ICs) in the auditory midbrain are connected to one another by a bundle of fibres, the commissure of the IC.Missing: intracollicular ECIC
  32. [32]
    Functional organization of the local circuit in the inferior colliculus
    The inferior colliculus (IC) is the first integration center of the auditory system. After the transformation of sound to neural signals in the cochlea, ...
  33. [33]
    Journal of Comparative Neurology - Wiley Online Library
    Oct 17, 2006 · Inferior colliculus ... Visualization of detailed acetylcholinesterase fiber and neuron staining in rat brain by a sensitive histochemical ...
  34. [34]
    Separate projections from the inferior colliculus to the cochlear ...
    The IC also contributes to motor and vocalization functions, in part through direct projections to the pons, superior colliculus, and the periaqueductal gray ( ...
  35. [35]
    Two Classes of GABAergic Neurons in the Inferior Colliculus
    Nov 4, 2009 · The inferior colliculus (IC) is unique, having both glutamatergic and GABAergic projections ascending to the thalamus.
  36. [36]
    Classification of frequency response areas in the inferior colliculus ...
    Different receptive field shapes have been described, but we do not know if these represent discrete classes reflecting afferent inputs from individual sources, ...
  37. [37]
    Spatial organization of frequency preference and selectivity ... - Nature
    Jan 22, 2013 · The inferior colliculus (IC)—centrally located in the auditory pathway—is an obligatory relay station for all information ascending from ...
  38. [38]
    Response Properties of Neighboring Neurons in the Auditory ...
    This classification scheme includes six different peristimulus time histogram (PSTH) types: chopper, pauser, onset, on-sustained, on-chopper, and sustained.
  39. [39]
    Stimulus-Specific Adaptation in the Inferior Colliculus of the ...
    This study demonstrates that neurons in the inferior colliculus (IC) also show strong SSA using this paradigm.
  40. [40]
    a 2-deoxyglucose study - PubMed
    The 3-dimensional (3-D) functional organization of the cat's inferior colliculus (IC) was examined using the 2-deoxyglucose method.Missing: DG | Show results with:DG
  41. [41]
    A mammalian inferior colliculus model for sound source separation ...
    The inferior colliculus (IC) is a central hub in the ascending auditory brainstem. It hosts many neurons tuned to interaural time differences (ITDs). ITD tuning ...
  42. [42]
    Neuronal Sensitivity to the Interaural Time Difference of the Sound ...
    We examined the sensitivity of the neurons in the mouse inferior colliculus (IC) to the interaural time differences (ITD) conveyed in the sound envelope.
  43. [43]
    Neuronal sensitivity to the interaural time difference of the sound ...
    We examined the sensitivity of the neurons in the mouse inferior colliculus (IC) to the interaural time differences (ITD) conveyed in the sound envelope.
  44. [44]
    Spectral and Temporal Modulation Tradeoff in the Inferior Colliculus
    We report a distinct tradeoff in modulation sensitivity and tuning that is topographically ordered within the central nucleus of the inferior colliculus (CNIC).
  45. [45]
    SPECTRAL PROCESSING AND SOUND SOURCE DETERMINATION
    Cherry's paper introduced the phrase “cocktail party effect” as a general term to describe the ability to process one voice in the presence of others. Because ...
  46. [46]
    Functional role of the human inferior colliculus in binaural hearing
    Functional role of the human inferior colliculus in binaural hearing. Author ... cocktail party effect' (Cherry, 1953, Yost, 1997). In psychophysical ...
  47. [47]
    [PDF] A review of the neural basis underlying the acoustic startle response ...
    May 1, 2023 · It was initially thought that the inferior colliculus (IC) mediated ASR. Wright and Barnes (1972) observed that the superior colliculi, the red.
  48. [48]
    Connectional Modularity of Top-Down and Bottom-Up Multimodal ...
    Oct 26, 2016 · The lateral cortex of the inferior colliculus receives information from both auditory and somatosensory structures and is thought to play a ...
  49. [49]
    Segregation of Multimodal Inputs Into Discrete Midbrain ... - Frontiers
    The inferior colliculus (IC) is a strategically positioned midbrain hub that receives an array of top-down and bottom-up afferents of multisensory origin.
  50. [50]
    Sound localization: Jeffress and beyond - PMC - PubMed Central
    The Jeffress model, its variants and alternatives ... Membrane properties and firing patterns of inferior colliculus neurons: an in vivo patch-clamp study in ...
  51. [51]
    Review Detecting interaural time differences and remodeling their ...
    Transformations in processing interaural time differences between the superior olivary complex and inferior colliculus: beyond the Jeffress model. Hear. Res ...
  52. [52]
    effects of unilateral lesions in central auditory system - PubMed - NIH
    Authors. W M Jenkins, R B Masterton. PMID: 7108581; DOI: 10.1152/jn.1982.47 ... Inferior Colliculi / physiology; Mesencephalon / physiology; Olivary Nucleus ...
  53. [53]
    Sound-localization deficits induced by lesions in the barn owl's ...
    Jan 1, 1993 · Small electrolytic lesions caused sound-localization deficits that were characterized by failures to turn, turns away from the sound source, ...
  54. [54]
    Sound localization after unilateral lesions of inferior colliculus in the ...
    Each of the four animals with large unilateral lesions had a substantial impairment in sound localization in the field contralateral to the lesion site.
  55. [55]
    Auditory processing in a patient with a unilateral lesion of the inferior ...
    The role of the inferior colliculus (IC) in human auditory processing is still poorly understood. We report here the results obtained with a 12-year-old boy ...Missing: stroke tumor CAPD hyperacusis
  56. [56]
    Case Report Detail: Inferior colliculus syndrome - LesionBank
    A 36-year-old right-handed man had an intracerebral hemorrhage circumscribed to the right inferior colliculus. Following recovery from the acute phase, he had ...
  57. [57]
    [PDF] Tinnitus and reduced word recognition with a bilateral inferior ...
    Tinnitus and reduced word recognition with a bilateral inferior colliculus infarction after cerebellar arteriovenous malformation embolization. Curr J. Neurol ...
  58. [58]
    Hyperacusis - an overview | ScienceDirect Topics
    Hyperacusis is defined as an intolerance of sounds at low-to-moderate intensity levels that results in physical discomfort and can increase stress and anxiety.
  59. [59]
    Prepulse inhibition following lesions of the inferior colliculus
    The present study investigated the effects of focal excitotoxic lesions of the inferior colliculus (IC) on acoustic PPI in rats. In the first part, startle ...
  60. [60]
    Prepulse inhibition following lesions of the inferior colliculus - PubMed
    With the ISI fixed at 50 ms, as the prepulse sound level increased from 29 to 49 dB SPL, startle responses decreased quickly in both normal and cortical lesion ...Missing: impairment | Show results with:impairment
  61. [61]
    The representation of sound localization cues in the barn owl's ...
    The inferior colliculus (IC) is a central processing unit through which almost all auditory information must pass before it can reach the more central nuclei ...Abstract · Introduction · The External Nucleus of the... · Plasticity in the Barn Owl's...
  62. [62]
    Cortical Auditory Deafferentation Induces Long-Term Plasticity in the ...
    The inferior colliculus (IC) is an obligatory relay station for almost all ascending and descending auditory projections and it is a key nucleus for excitatory ...
  63. [63]
    The effect of inferior colliculus lesions on auditory evoked potentials
    When only one inferior colliculus was ablated, this reduction was greater when the ear contralateral to the lesion side was stimulated. Previous article in ...
  64. [64]
    The contribution of inferior colliculus activity to the auditory ...
    In mice, the auditory brainstem response (ABR) is frequently used to assess hearing status in transgenic hearing models. The diagnostic value of the ABR ...
  65. [65]
    Testing the Central Gain Model: Loudness Growth Correlates with ...
    May 21, 2019 · The central gain model of hyperacusis proposes that loss of auditory input can result in maladaptive neuronal gain increases in the central auditory system.
  66. [66]
    Tonotopic reorganization and spontaneous firing in inferior ...
    Dec 9, 2013 · Tonotopic reorganization and spontaneous firing in inferior colliculus during both short and long recovery periods after noise overexposure.Nuclear Dna Staining Of... · Abr Thresholds In Noise... · Discussion<|separator|>
  67. [67]
    Can Animal Models Contribute to Understanding Tinnitus ...
    Tinnitus does not require macroscopic tonotopic map reorganization. Front ... inferior colliculus of CBA/J mice after manipulations that induce tinnitus.
  68. [68]
    Altered Response Dynamics and Increased Population Correlation ...
    Animal studies have shown that age-related high-frequency hearing loss can lead to remapping of central auditory brain regions such as the inferior colliculus ...
  69. [69]
    Age-Related Alteration in Processing of Temporal Sound Features ...
    In this study we compared the neural response elicited by silent gaps imbedded in noise of single neurons in the inferior colliculus (IC) of young and old CBA ...
  70. [70]
    Increasing GABA reverses age-related alterations in excitatory ...
    A key feature of age-related hearing loss is a reduction in the expression of inhibitory neurotransmitters in the central auditory system.<|separator|>
  71. [71]
    Apoptosis in the Cochlear Nucleus and Inferior Colliculus Upon ...
    Comparison and contrast of noise-induced hyperactivity in the dorsal cochlear nucleus and inferior colliculus. Hear Res. 2013;295:114–23. doi: 10.1016/j ...
  72. [72]
    Age-related changes in the central auditory system - PubMed
    Jul 16, 2010 · ... inferior colliculus (IC) and cochlear nucleus (CN). We assessed changes in lipid peroxidation levels and apoptosis rates, and examined ...
  73. [73]
    Acute and Long-Term Effects of Noise Exposure on the Neuronal ...
    Acute and Long-Term Effects of Noise Exposure on the Neuronal Spontaneous Activity in Cochlear Nucleus and Inferior Colliculus Brain Slices. Moritz Gröschel ...
  74. [74]
    and age-dependent manner in the valproic acid-induced rat model ...
    Contextual auditory processing in the inferior colliculus is affected in a sex- and age-dependent manner in the valproic acid-induced rat model of autism.
  75. [75]
    Abnormal development of auditory responses in the inferior ...
    This study presents novel evidence for neural correlates of auditory hypersensitivity in the developing inferior colliculus (IC) in Fmr1 knockout (KO) mouse.
  76. [76]
    Contextual auditory processing in the inferior colliculus is affected in ...
    Aug 4, 2025 · Diverse biological factors, such as sex and age, confer heterogeneity on sensory processing challenges in autism.
  77. [77]
    Deep brain stimulation of the inferior colliculus in the rodent ...
    Nov 1, 2016 · In summary, this study shows that DBS of the inferior colliculi is effective in reducing behavioral signs of tinnitus in an animal model.
  78. [78]
    Tinnitus: Is there a place for brain stimulation? - PubMed
    Feb 10, 2016 · Promising structures for stimulation are the dorsal cochlear nucleus, the inferior colliculus and the medial geniculate body of the thalamus.<|control11|><|separator|>
  79. [79]
    A New Concept for Noninvasive Tinnitus Treatment Utilizing ...
    Paired somatic and acoustic stimulation resulted in enhanced or suppressed acoustic-driven neural activity in the inferior colliculus that varied depending on ...