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Musicality

Musicality is a complex, polymorphic human trait that encompasses the sensitivity to, knowledge of, and talent for music, manifesting through both receptive abilities—such as perceiving pitch, rhythm, and emotional content—and productive abilities, including singing, playing instruments, and composing.^[1] It integrates physical, emotional, cognitive, and psychosocial factors, enabling individuals to engage with music in ways that convey meaning and foster social connections.^[1] Defined as a uniquely human and spontaneously developing capacity, musicality emerges early in life without formal training and is constrained by biological and cognitive mechanisms.^[2] In psychological research, musicality is viewed as an innate predisposition that supports emotional well-being and social bonding, with studies highlighting its role in processing musical syntax and eliciting affective responses across diverse populations.^[3] Developmentally, it unfolds through longitudinal patterns observable in infancy, influenced by genetic factors like variations in the arginine vasopressin receptor gene^[4] and environmental interactions such as exposure to music-making,^[5] with ongoing genomic research as of 2025 exploring broader genetic pathways to musical traits.^[6] In performance contexts, musicality extends to expressive interpretation, where musicians apply technical proficiency to vary dynamics, tempo, and phrasing, thereby infusing compositions with personal and cultural nuance.^[7] Evolutionary perspectives posit musicality as an adaptive trait rooted in vocal communication, potentially enhancing group cohesion and mate selection through coordinated musical activities.^[8] While universal in its basic perceptual elements, individual differences in musicality—ranging from amusia (tone deafness) to exceptional talent—underscore its variability, with no single metric fully capturing its scope.^[1] This multifaceted nature positions musicality at the intersection of neuroscience, education, and cultural studies, informing therapeutic applications like music therapy for cognitive and emotional rehabilitation.^[3]

Definition and Core Concepts

Definition of Musicality

Musicality refers to the innate or developed human capacity to perceive, appreciate, produce, and respond to musical elements such as rhythm, pitch, timbre, and harmony, often manifesting as a spontaneous trait distinct from formal musical training or expertise.^[9] This trait is characterized as a natural predisposition rooted in biology and cognition, enabling individuals to engage with music intuitively without deliberate instruction.^[2] Unlike technical proficiency, musicality emphasizes an inherent sensitivity that allows for fluid interaction with musical forms, making it a foundational aspect of human auditory and expressive behavior.^[10] The term "musicality" derives from the adjective "musical," which entered English in the mid-15th century from Medieval Latin musicalis, meaning "pertaining to music" or "tuneful and harmonious."^[11] By the 19th century, "musicality" itself emerged around 1839 as a noun formed by adding the suffix "-ity" to "musical," initially denoting a general fondness for or skill in music, as reflected in early dictionary definitions.^[12] In the 20th century, its usage evolved to highlight expressiveness and sensitivity, encompassing not just affinity for music but also the nuanced ability to convey emotion through musical means, aligning with broader artistic interpretations of innate talent.^[13] Central components of musicality include sensitivity to musical structure, which involves recognizing patterns in sound organization; emotional expressiveness, the capacity to infuse performances or responses with feeling; and improvisational flair, the spontaneous adaptation or creation within musical contexts.^[9] These elements distinguish musicality as a holistic quality that integrates cognitive processing with affective response, allowing individuals to derive pleasure and meaning from music beyond rote learning.^[2] Everyday manifestations of musicality appear in simple behaviors such as humming familiar tunes or tapping fingers to a beat, which demonstrate an unconscious synchronization with rhythmic and melodic patterns present in the environment.^[14] These actions reveal the trait's accessibility across populations, serving as evidence of a basic, widespread capacity for musical engagement without requiring specialized skills.^[10]

Musicality Versus Music

Music, as a structured art form, encompasses compositions, instruments, genres, and performances that form the tangible products of cultural and artistic creation, whereas musicality refers to the innate, subjective capacity individuals possess to perceive, interpret, and infuse expressiveness into musical experiences.^[15] This distinction highlights music as an external, learned construct shaped by societal norms and traditions, in contrast to musicality as a spontaneous trait rooted in cognitive and perceptual abilities that enable personal engagement with sound.^[15] Philosophically, this separation is evident in Susanne Langer's framework, where music functions as a non-discursive symbolic form that articulates the "forms of sentience" and dynamic patterns of human feeling, independent of its technical production or literal representation.^[16] Langer posits that music's expressive power derives from its ability to create a "virtual time" through tonal structures, mirroring emotional rhythms like growth and resolution without relying on the craftsmanship of composition or performance techniques.^[16] In this view, musicality emerges as the perceptual grasp of these symbolic elements, allowing individuals to experience the "life of feeling" beyond the mechanical aspects of music itself.^[16] Illustrative examples underscore this divide: a highly trained violinist may demonstrate flawless technical proficiency by executing complex passages with precise intonation and speed, yet produce a performance perceived as "robotic" or devoid of emotional depth if lacking musicality. Conversely, an untrained listener or amateur might exhibit strong musicality through an intuitive sense of rhythm and phrasing, such as spontaneously clapping in sync with a beat or humming a melody's emotional arc, revealing an inherent ability to connect with music's expressive core without formal skills. Cultural variations further illuminate differing perceptions of musicality, as societies emphasize distinct facets of engagement with music. In jazz traditions, musicality is often valued through improvisation and rhythmic flexibility, where performers infuse personal expression and "swing" into spontaneous variations, prioritizing intuitive feel over rigid notation.^[17] In contrast, classical music cultures highlight musicality via precise interpretation of composed scores, focusing on technical accuracy and fidelity to the composer's intent to convey structured emotional narratives.^[18] These perspectives reflect broader aesthetic criteria, with jazz celebrating individual spontaneity as a hallmark of musicality, while classical traditions view it as emerging from disciplined adherence to form.^[18]

Biological Foundations

Innate Musical Traits

Musicality exhibits a significant genetic component, as evidenced by twin studies that estimate heritability for various musical traits between 40% and 80%. For instance, research on music pitch recognition, including aspects related to perfect pitch, has shown genetic factors accounting for 70-80% of individual differences, with no substantial influence from shared environment. Similarly, studies on rhythm synchronization and beat perception report heritability estimates of 13-16% on the liability scale, though broader musical aptitude measures, such as rhythm discrimination, range from 42% to 71%. These findings underscore the heritable nature of innate musical processing, distinct from environmental training effects. Neurophysiological evidence further highlights the biological foundations of musicality, with key brain regions including the auditory cortex, basal ganglia, and corpus callosum playing central roles in processing pitch, rhythm, and temporal elements. The auditory cortex is particularly implicated in fine-grained pitch discrimination, where structural differences, such as reduced white matter volume in the right inferior frontal gyrus, correlate with impaired music perception. Congenital amusia, a neurodevelopmental disorder affecting about 4% of the population and characterized by deficits in tone perception despite intact hearing, reveals specific vulnerabilities: individuals with amusia show reduced connectivity in the corpus callosum, limiting interhemispheric transfer of musical information, and atypical activation in the basal ganglia, which is crucial for rhythm processing and synchronization. These anatomical variations demonstrate how innate neural architecture underpins spontaneous musical abilities, independent of musical experience. The spontaneous emergence of musicality is observable from infancy, indicating an early developmental onset rooted in biological predispositions. Newborns exhibit a preference for consonant musical intervals over dissonant ones, as demonstrated in studies where they orient more toward harmonious sounds, suggesting an innate sensitivity to musical structure. By a few months of age, infants entrain their movements and physiological responses, such as heart rate, to the rhythm and melody of maternal singing, which promotes bonding and co-regulation more effectively than speech. This entrainment reflects an intrinsic capacity for temporal and emotional synchronization to musical stimuli. Comparative biology reveals parallels in basic musical traits across species, though humans uniquely integrate syntactic complexity with emotional expression. Songbirds, such as zebra finches, display advanced vocal learning and rhythmic patterning in their songs, mirroring human pitch and sequence processing through analogous brain circuits like the song system. Non-human primates, including marmosets, engage in coordinated vocalizations that convey affective states, but lack the combinatorial syntax seen in human music. This human-specific fusion of structural rules and emotional depth in musicality likely stems from evolved neural enhancements beyond those in other animals.

Evolutionary Origins

The evolutionary origins of musicality have been debated through competing theories, with Charles Darwin proposing in 1871 that music emerged via sexual selection, serving as a courtship display to attract mates by signaling genetic fitness and cognitive prowess.^[19] This hypothesis posits that proto-musical vocalizations in early hominids functioned similarly to birdsong, where elaborate displays enhance reproductive success, a view supported by cross-species comparisons and human mate preferences for musical ability.^[20] In contrast, group cohesion models emphasize music's role in fostering social bonds among early humans, suggesting that shared singing and rhythmic activities promoted cooperation and synchronization in hunter-gatherer groups, potentially predating sexual selection as a primary driver.^[21] These models argue that music evolved as a cultural adaptation reinforcing group rituals, with empirical evidence from modern analogs showing synchronized vocalizations increasing prosocial behavior and endorphin release.^[22] Archaeological evidence underscores musicality's deep antiquity, with the oldest known instruments—bone flutes crafted from vulture wings and mammoth ivory—dating to approximately 40,000 years ago in Germany's Hohle Fels cave, indicating deliberate musical production during the early Aurignacian period of modern human migration into Europe.^[23] These artifacts, featuring precisely drilled finger holes and tuned notes, suggest that musical behaviors were present during the emergence of behavioral modernity in Europe around 40,000–50,000 years ago. Recent genomic studies indicate that the capacity for complex symbolic cognition and language may have originated much earlier, at least 135,000 years ago in Africa.^[24] Such findings align with ethnographic observations of Paleolithic-like societies, where simple instruments facilitated communal activities, hinting at music's role in early human adaptation. In functional terms, musicality likely enhanced empathy, cooperation, and emotional regulation within hunter-gatherer societies by synchronizing group emotions and reducing conflict through collective entrainment, as seen in rituals that built trust and coordinated hunting or foraging efforts.^[25] For instance, shared singing in these egalitarian groups fostered oxytocin-mediated bonding, paralleling modern communal rituals like choral singing, which elevate pain thresholds and social connectivity via endorphin release.^[26] This adaptive utility is evidenced in cross-cultural universality, where lullabies—simple, soothing songs for infants—appear in every documented society, promoting caregiver-infant attachment and entrainment to rhythms that regulate arousal and sleep.^[27] Similarly, entrainment behaviors, such as synchronized clapping or dancing, are ubiquitous, supporting music's evolution as a mechanism for group cohesion across diverse cultures.^[28]

Psychological Dimensions

Musical Intelligence

In Howard Gardner's theory of multiple intelligences, musical-rhythmic intelligence is defined as the capacity to recognize and compose musical pitches, tones, and rhythms, encompassing sensitivity to sounds, vibrations, and musical structures.^[29] This intelligence involves core skills such as discriminating between musical elements like timbre and rhythm, performing music through instruments or voice, and creating original compositions that convey patterns and melodies.^[29] Gardner posits it as one of eight (later expanded) distinct intelligences, emerging early in development and evident in the ability to detect subtle auditory patterns.^[30] Individuals with high musical-rhythmic intelligence often demonstrate exceptional abilities, such as memorizing and recognizing complex melodies after a single exposure, improvising variations on existing tunes, and employing music to express or evoke emotions.^[29] For instance, Wolfgang Amadeus Mozart exemplified this through his prodigious composition of symphonies and operas from childhood, showcasing innate sensitivity to rhythm and harmony that allowed rapid musical innovation.^[31] Within Gardner's framework, this intelligence operates as a standalone competency but can integrate with others, such as linguistic intelligence in lyric writing or spatial intelligence in conducting orchestras, enhancing multifaceted creative processes without subsuming into them.^[30] Critics of Gardner's model argue that musical-rhythmic intelligence lacks true independence, as psychometric studies reveal strong correlations among abilities, suggesting overlap with general intelligence (g-factor) rather than modular separation.^[32] Factor analyses indicate that diverse cognitive tasks, including musical ones, load heavily on a unified g-factor, challenging claims of distinct neural modules.^[33] Post-2020 neuroimaging research has refined these debates by identifying specific brain correlates, such as enhanced frontoparietal network efficiency linked to musical perceptual aptitude, mediated by working memory and observable in structural and functional MRI data from non-musicians.^[34] These findings support refined views of musical cognition as involving integrated networks rather than isolated intelligences, while highlighting plasticity in auditory processing regions.^[34] Recent neuroscience evidence, as discussed by Gardner in 2025, provides new strands supporting multiple intelligences, with musical intelligence appearing as an exception enhanced by early exposure to music.^[35]

Perception and Emotional Response

Musicality in perception involves the brain's auditory pathway processing core elements of music, such as pitch, rhythm, and timbre, to form coherent auditory experiences. Pitch perception, a key aspect of melody recognition, relies on the encoding of fundamental frequency (F0) through tonotopic organization in the cochlea and phase-locking in auditory nerve fibers, with higher cortical areas in the temporal lobe, particularly the right hemisphere, detecting pitch changes like semitone intervals.^[36] Rhythm processing, including beat perception, engages premotor cortex and striatum interactions to synchronize internal timing with external pulses, enabling anticipation of rhythmic patterns even in nonmusicians.^[37] Timbre, which distinguishes instrument sounds beyond pitch and loudness, is shaped by spectral envelope analysis in early auditory stages, contributing to the perceptual richness of musical textures. A critical perceptual feature tied to musical tension is the violation of expectations, where deviations from predicted harmonic or structural patterns elicit heightened cognitive processing. Such violations, such as tonal inconsistencies at phrase or period levels, induce tension by generating predictive errors, as evidenced by increased frontal negativity (N5 component) in EEG and reduced alpha power, reflecting greater attentional demands and model updating in the brain.^[38] On the emotional front, musicality activates the limbic system to evoke profound affective responses; for instance, intense pleasure or "chills" from music correlates with nucleus accumbens activity in the ventral striatum, a reward hub, while amygdala modulation dampens negative emotions to amplify enjoyment.^[39] Recent fMRI studies from 2025 indicate that music-evoked emotions are dynamic and contextually dependent, with brain-state changes along the temporoparietal axis reflecting transitions between emotions.^[40] Nostalgia and emotional depth arise from hippocampus-amygdala interactions, linking music to autobiographical memory recall, whereas dopamine release in the basal ganglia during groove synchronization or harmony resolutions reinforces pleasurable anticipation and fulfillment.^[41] Individual differences in musicality influence emotional processing, with higher empathy traits enhancing neural connectivity during music listening. Functional MRI studies show that empathic individuals exhibit stronger eigenvector centrality in the ventromedial prefrontal cortex and increased functional connectivity between prefrontal areas, visual cortex, and reward regions like the putamen when engaging with sad music, facilitating deeper mood regulation and social inference.^[42] This correlates with broader affective openness, as empathic listeners display heightened activity in sensorimotor and limbic networks, promoting stronger emotional immersion.^[43] However, much research in music psychology relies on samples from Western, Educated, Industrialized, Rich, and Democratic (WEIRD) societies with limited musical diversity, underscoring the need for broader participant and musical backgrounds to improve generalizability.^[44] Disorders can alter these perceptual and emotional facets of musicality; in Williams syndrome, a genetic condition, individuals exhibit heightened musical engagement and emotional responsiveness, with 50-90% participating in musical activities and displaying intense, prolonged positive affect to music due to atypical auditory-limbic processing.^[45] Conversely, alexithymia, characterized by impaired emotion identification, leads to reduced sensitivity to music's affective qualities, as shown by diminished N400 event-related potentials during incongruent emotional music categorization, indicating blunted neural integration of musical valence.^[46]

Applications in Performance and Creation

Musicality in Musical Performance

Musicality in performance elevates technical execution by infusing music with emotional depth and interpretive nuance, allowing performers to communicate intent beyond mere accuracy. Expressive elements such as dynamics, tempo rubato, and phrasing are central to this process, enabling variations in loudness, timing, and articulation that shape the emotional contour of a piece. Dynamics involve deliberate shifts in volume to heighten tension or release, while rubato permits subtle tempo fluctuations to evoke intimacy or urgency, and phrasing contours melodic lines to mimic natural speech patterns, fostering a sense of narrative flow. These techniques, when applied stylistically, transform a literal rendition into a compelling artistic statement, as performers deviate from notated scores to personalize the music while respecting genre conventions.^[47] In classical music, conductors like Leonard Bernstein exemplified this emphasis on emotional essence over rote notation, advocating for performances that capture the "heart and soul" of the composition through vivid gestural and sonic interpretation. Bernstein's approach highlighted how expressive timing and dynamic swells could reveal underlying themes, prioritizing affective communication in orchestral settings. In contrast, improvisational genres such as jazz and folk demand even greater musicality, where performers spontaneously craft phrasing to respond to the moment. Jazz trumpeter Miles Davis mastered intuitive phrasing in improvisations, using space, melodic fragments, and rhythmic displacement to convey introspection and innovation, as heard in his seminal recordings like Kind of Blue, where phrasing prioritized emotional resonance over harmonic complexity. This contrasts with the more structured classical tradition, where musicality manifests through interpretive fidelity to the score, yet both underscore the performer's ability to internalize and project groove and nuance.^[48]^[49] Developing musicality in performance often involves hallmarks like ear training and ensemble playing, which cultivate an intuitive grasp of musical elements. Ear training enhances the ability to discern pitches, intervals, and timbres internally, allowing performers to anticipate and adapt phrasing in real-time, thereby deepening expressive control. Ensemble play further refines this by fostering synchronization and responsive interaction, where musicians internalize collective groove through active listening, leading to cohesive yet individualized expressions of nuance. Research indicates these practices strengthen auditory processing and perceptual acuity, enabling performers to embody musicality as an integrated skill rather than isolated technique.^[50] Judging musicality remains inherently subjective, particularly in competitions, where evaluators' personal aesthetics and biases influence assessments of expressiveness. Studies reveal that while technical criteria provide structure, intangible factors like perceived charisma or emotional delivery often sway outcomes, as judges prioritize holistic impact over quantifiable metrics. This subjectivity can disadvantage performers whose style deviates from adjudicators' preferences, highlighting ongoing debates about standardizing evaluations in professional contexts.^[51]^[52]

Musicality in Dance and Movement

Musicality in dance refers to the dancer's ability to synchronize movements with musical elements such as rhythm, accent, and phrasing, creating an expressive alignment between gesture and sound. This involves interpreting the music's structure to shape bodily responses, where gestures are timed to match rhythmic pulses, emphasized on accents for dynamic impact, and extended or suspended to echo phrasing. In ballet, for instance, partnering often leverages musical swells to enhance emotional depth, as seen in the pas de deux from Kenneth MacMillan's Romeo and Juliet, where dancers pause in mutual gaze as the orchestra builds tension before a descending movement releases the crescendo.^[53] In contrast, hip-hop freestyling emphasizes improvisational responses to beats, where dancers layer personal flair onto the underlying groove, adapting gestures to syncopated rhythms and breaks for spontaneous expression.^[54] Sensory integration plays a crucial role in translating auditory cues into motion, with proprioception providing internal feedback on body position and vestibular senses detecting balance and orientation during movement. These systems enable dancers to align physical actions with music without visual reliance, fostering fluid synchronization. Studies on entrainment highlight how group dances amplify this process, as participants' movements converge on shared rhythms, enhancing collective timing through interpersonal coordination. For example, research on ecologically valid settings shows that synchronized swaying to music strengthens vestibular-proprioceptive coupling, promoting harmonious group dynamics.^[55]^[56]^[57] Cultural variations in musicality reflect diverse approaches to musical response, with African dance traditions often centering polyrhythmic structures that demand multifaceted bodily engagement. In West African forms like those of the Ewe people, dancers respond to layered rhythms—such as interlocking drum patterns—through polycentric movements that isolate limbs to echo multiple temporal streams simultaneously, embodying a communal rhythmic dialogue.^[58]^[59] Western contemporary dance, however, frequently adopts an abstract musicality, prioritizing interpretive freedom over literal synchronization; choreographers like Merce Cunningham decoupled movement from music's narrative, allowing dancers to explore phrasing and dynamics in non-literal ways that evoke emotional or conceptual states rather than direct rhythmic mimicry.^[60] In therapeutic contexts, musicality-driven dance enhances motor skills for individuals with Parkinson's disease by leveraging rhythmic cues to improve coordination and gait. Dance therapy programs, such as those incorporating partnered improvisation to music, have demonstrated reductions in motor impairment severity, with participants showing better balance and fluidity after regular sessions. These interventions harness entrainment to rhythmic beats, aiding neural reorganization and motor control without focusing solely on symptom measurement.^[61]^[62]

Assessment and Development

Measuring Musicality

Measuring musicality involves a range of empirical methods designed to quantify aspects such as pitch discrimination, rhythm processing, and expressive performance, applicable in clinical diagnostics, educational settings, and artistic evaluations.^[63] Standardized tests represent foundational tools for assessing core perceptual abilities. The Montreal Battery of Evaluation of Amusia (MBEA), developed in 2003, evaluates six components of music processing—melody contour, interval, scale, rhythm, meter, and memory—through tasks requiring discrimination and recognition of musical elements, making it the gold standard for diagnosing congenital amusia. Earlier benchmarks, such as the Seashore Measures of Musical Talent from 1919, assess innate aptitudes like pitch, intensity, rhythm, and timbre via auditory comparisons, influencing subsequent aptitude testing despite limitations in ecological validity.^[64] Performance-based assessments shift focus to applied skills, often used in auditions and ensemble placements to evaluate technical proficiency and interpretive depth. These typically employ rubrics scoring elements like intonation accuracy, tempo stability, and expressiveness from live or recorded performances, with systematic reviews identifying common criteria such as articulation and phrasing as key indicators of overall musicality.^[65] For instance, judges rate recordings on scales that quantify subjective qualities like emotional conveyance, providing a holistic measure beyond isolated perception.^[65] Contemporary methods leverage technology for objective, scalable analysis. AI-driven tools analyze singing accuracy by extracting acoustic features like pitch deviation and vibrato consistency from audio inputs, enabling automated scoring without human raters, as demonstrated in systems using support vector machines for multi-level evaluation.^[66] Biofeedback from wearables, such as inertial sensors, tracks physiological responses like movement synchronization to rhythm—known as entrainment—during musical activities, offering real-time metrics of engagement and coordination in performance contexts. Despite these advances, measuring musicality faces significant limitations, including cultural biases embedded in test stimuli and norms. For example, the MBEA's reliance on Western tonal structures can disadvantage individuals from non-Western musical traditions, necessitating adaptations like the Greek Battery of Evaluation of Amusia to account for differing scales and rhythms.^[67] Additionally, subjective elements such as "feel" or artistic intuition resist quantification, as they involve personal and contextual interpretations not fully captured by perceptual or biometric data.^[63]

Enhancing Musicality Through Training

Educational programs such as Dalcroze eurhythmics emphasize the integration of body movement with musical elements to foster musicality from an early age. Developed by Émile Jaques-Dalcroze in the early 20th century, this approach uses rhythmic exercises, improvisation, and physical responses to music to enhance perceptual and expressive skills, enabling learners to internalize rhythm, phrasing, and dynamics through kinesthetic experiences.^[68] Research supports its effectiveness in promoting musical development, with systematic reviews indicating improvements in cognitive and motor coordination among participants, particularly in vulnerable populations like children with special needs, where music-movement integration boosts self-regulation and phonological awareness.^[69] Complementing Dalcroze methods, the Orff Schulwerk approach, created by Carl Orff and Gunild Keetman, encourages improvisational play in children to build musical intuition and creativity. This child-centered method incorporates speech, movement, singing, and simple percussion instruments to explore rhythm and melody, treating music as an extension of natural play. Studies demonstrate that Orff-based activities enhance executive functions, such as inhibitory control, alongside musical skills like rhythmic accuracy and improvisational fluency, with interventions showing significant behavioral improvements in preschoolers after short-term engagement.^[70] Evidence from systematic reviews further confirms its role in developing foundational musical competencies in resource-limited settings, using everyday objects to facilitate inclusive learning.^[71] Neuroplasticity underpins the potential for training to enhance musicality across the lifespan, with auditory and instrumental practice inducing structural brain changes. Longitudinal studies reveal that six months of musical training, such as piano lessons, increases gray matter volume in regions like the cerebellum and caudate nucleus, correlating with improved auditory working memory and tonal processing.^[72] These adaptations, observed in older adults, extend to musicians generally, where consistent practice over similar durations promotes expressiveness by refining neural pathways for rhythm and pitch discrimination, as evidenced by enhanced gray matter in auditory-motor areas.^[73] For adults, mindfulness-based listening exercises offer a targeted technique to deepen musical engagement and expressivity. These practices involve focused, non-judgmental attention to musical elements like timbre and phrasing during sessions, often guided by meditation protocols. Research indicates that brief mindfulness interventions improve musical aesthetic emotion processing, heightening sensitivity to nuances in performance and reducing distractions during listening or playing.^[74] Digital tools, such as apps providing real-time feedback on phrasing and intonation, complement these exercises by simulating teacher guidance; for instance, platforms like Yousician deliver interactive lessons that adapt to user input, supporting skill refinement in rhythm and expression for self-directed learners.^[75] Longitudinal data highlight tangible outcomes from such training, including mitigation of congenital amusia and elevated professional performance. Case studies of vocal training in individuals with amusia show temporary improvements in pitch perception and singing accuracy during active training periods, though gains often fade without continued practice, suggesting some plasticity in auditory processing even in persistent deficits.^[76]

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Conclusions. Our results suggest a reduced sensitivity for the emotional qualities of speech and music in alexithymia during affective categorization. This ...
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(PDF) Introduction: Expressiveness in music performance
What does it mean to be expressive in music performance in diverse historical and cultural domains? What are the means at the disposal of a performer in ...
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Passing the Baton, the Curiosity, and the Passion | Classical.org
Jan 31, 2018 · Imparting the Heart and Soul of a Craft. Leonard Bernstein, for me, was the greatest risk-taker in 20th century classical music. Seeing him ...
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Miles Davis and the Semiotics of Improvised Performance - jstor
His musical innovations, perfor- mance conduct, and public persona excited extensive comment, imitation, and castigation. Moreover, a vast majority of the ...
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Playing Music for a Smarter Ear: Cognitive, Perceptual and ...
In this review, we provide neurobiological evidence that music training shapes human auditory function not only as it relates to music, but also as it relates ...
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[PDF] The Subjectivity of Musical Performance - DiVA portal
The Subjectivity of Musical Performance: An Exploratory Music-Psychological Real World Enquiry. Into the Determinants and Education of Musical Reality.
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Sight over sound in the judgment of music performance - PNAS
Professional musicians and competition judges consciously value sound as central to this domain of performance, yet they arrive at different winners depending ...
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Pas de Deux: It Takes Two - The Kennedy Center
The “Love Dance” The two lovers fix their eyes on one another and remain still while the music builds and swells. Juliet, transfixed by Romeo, descends the ...
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Elements of musical and dance sophistication predict musical ... - NIH
Nov 17, 2022 · Musical groove is recognized as a characteristic of songs encompassing genres such as jazz, pop, rock, hip hop, R&B, soul, and funk, made ...
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Vestibular System Eletrophysiology: An Analysis of the Relationship ...
Dance practice provides greater development of the vestibular system, but musical training also contributes to the magnitude of these responses.
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The primal role of the vestibular system in determining musical rhythm
A major source of proprioceptive information concerning whole body movement comes from the vestibular system. Passive movement of the legs on either every ...
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Exploring movement entrainment in an ecologically valid concert ...
Aug 29, 2025 · Moving to the beat is one of the most natural human reactions while listening to music and can be defined as movement entrainment.
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[PDF] West African Polyrhythm: culture, theory, and representation
West African polyrhythm involves complex rhythmic structures, layering different rhythms in music, dance, and percussion, with unity of rhythm and melody.Missing: musicality | Show results with:musicality
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Expertise in Contemporary Dance: The Roles of Cognition, Talent ...
Jan 26, 2022 · ABSTRACT. This paper examines the link between cognitive processes and superior performance in contemporary dance. In the first study, ...Introduction · Cognition And Dance... · Study 2
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The efficacy of dance for improving motor impairments, non ... - PMC
Aug 5, 2020 · Dance may help individuals living with Parkinson's disease (PD) improve motor and non-motor symptoms that impact quality of life (QOL).
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Benefits of dance for Parkinson's: The music, the moves, and the ...
Nov 21, 2022 · Our second hypothesis predicted that the dance classes improved motor control for people with Parkinson's. This was confirmed by the significant ...Missing: musicality | Show results with:musicality
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Revising the diagnosis of congenital amusia with the Montreal ...
Mar 31, 2015 · This article presents a critical survey of the prevalent usage of the Montreal Battery of Evaluation of Amusia (MBEA; Peretz et al., 2003) to assess congenital ...
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The measurement of musical talent - Internet Archive
Aug 21, 2008 · This document, 'The measurement of musical talent', by Carl E. Seashore, published in 1915, covers psychological aspects of music and ...
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Solo music performance assessment criteria: a systematic review
Oct 8, 2024 · We aimed to delimit and analyze solo music performance assessment systems found in the literature to date, including their corresponding evaluation categories ...Missing: auditions | Show results with:auditions
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https://pmc.ncbi.nlm.nih.gov/articles/PMC7406058/
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Cultural aspects of music perception: Validation of a Greek version ...
May 5, 2010 · Instead, our version of the MBEA, the Greek Battery of Evaluation of Amusia (GBEA) should be preferred in assessing music perception in cultures ...Missing: bias | Show results with:bias
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Dalcroze, the body, movement and musicality - Jay A. Seitz, 2005
The Swiss composer and music educator, Emile Jaques-Dalcroze, believed that bodily processes, rhythm, and physical motion were the basis of musical expressivity ...
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The effectiveness of music–movement integration for vulnerable ...
This systematic literature review summarizes and synthesizes the evidence for the effectiveness of Dalcroze-based (or similar) music–movement integration ...
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Self-directed music play to improve executive function in young children using NIRS - Scientific Reports
### Summary of Evidence on Orff-Schulwerk Enhancing Executive Functions and Musical Development in Children through Improvisation
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The impact of Kodály, Orff Schulwerk, and Suzuki music teaching ...
In resource-limited settings, Orff Schulwerk can facilitate rhythm and improvisation learning using simple percussion instruments or everyday objects. The ...
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Music interventions in 132 healthy older adults enhance cerebellar ...
6-month music training led to robust increases in grey matter in healthy older adults. Transfer effect: auditory working memory performance improved after ...
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Musical training, neuroplasticity and cognition - PMC
According to the researchers, these results indicate that long-term piano practicing may lead to gray matter and white matter adaptation in movement-related ...
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Mindfulness Meditation Improves Musical Aesthetic Emotion ... - MDPI
This study explored the behavioral and neural correlates of mindfulness meditation improvement in musical aesthetic emotion processing (MAEP) in young adults.Missing: musicality | Show results with:musicality
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Yousician Review for Teachers | Common Sense Education
Rating 5.0 (1) Yousician is a feedback-rich tool for building musical skills, with videos, hands-on practice, and game-based hooks. Teachers can enroll and use the Edu tab. ...Missing: phrasing musicality evidence
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(PDF) Effects of vocal training in a musicophile with congenital amusia
Some studies show that deficits in pitch perception in amusia cannot be altered through broad-brush music training methods, e.g., daily song listening over 4 ...