Dystonia Updates: Definition, Nomenclature, Clinical Classification, and Etiology PDF

Summary

This article provides an overview of dystonia, a heterogeneous group of movement disorders. It discusses updates in the definition, nomenclature, and clinical classification of dystonia, along with etiological factors. The review highlights the need for consistent classifications and terminology across the scientific community and for patients.

Full Transcript

Journal of Neural Transmission (2021) 128:395–404
https://doi.org/10.1007/s00702-021-02314-2

NEUROLOGY AND PRECLINICAL NEUROLOGICAL STUDIES - REVIEW ARTICLE

Dystonia updates: definition, nomenclature, clinical classification,
and etiology
Karen Grütz1 · Christine Klein1
Received: 3 December 2020 / Accepted: 23 January 2021 / Published online: 19 February 2021
© The Author(s) 2021, corrected publication 2021

Abstract
A plethora of heterogeneous movement disorders is grouped under the umbrella term dystonia. The clinical presentation
ranges from isolated dystonia to multi-systemic disorders where dystonia is only a co-occurring sign. In the past, definitions, nomenclature, and classifications have been repeatedly refined, adapted, and extended to reflect novel findings and
increasing knowledge about the clinical, etiologic, and scientific background of dystonia. Currently, dystonia is suggested
to be classified according to two axes. The first axis offers precise categories for the clinical presentation grouped into age
at onset, body distribution, temporal pattern and associated features. The second, etiologic, axis discriminates pathological
findings, as well as inheritance patterns, mode of acquisition, or unknown causality. Furthermore, the recent recommendations regarding terminology and nomenclature of inherited forms of dystonia and related syndromes are illustrated in this
article. Harmonized, specific, and internationally widely used classifications provide the basis for future systematic dystonia
research, as well as for more personalized patient counseling and treatment approaches.
Keywords Dystonia · Clinical classification · Disease etiology · Nomenclature

Introduction
Dystonia is the third most common movement disorder
after Parkinson’s disease and essential tremor. International
efforts in patient recruitment, rating scale use and harmonization, increasing scientific background on etiology and
pathophysiology, novel therapeutic approaches, and, last
but not least, the engagement of patients themselves, have
(re-)shaped our understanding and awareness of dystonia
and related syndromes in recent years. In light of its broad
clinical and etiological heterogeneity, it becomes obvious
that suitable definitions, a widely accepted and commonly
used nomenclature, as well as uniform classifications of
dystonic syndromes are a key prerequisite to (i) effectively
communicate in the scientific community and with patients
and caregivers; (ii) aide in establishing a clinically and/or
etiologically defined diagnosis, and (iii) provide an important framework for the study of known and newly identified
forms of dystonia or syndromes with dystonia as a prominent
* Christine Klein
[email protected]‑luebeck.de
1

Institute of Neurogenetics, University of Lübeck,
Ratzeburger Allee 160, 23538 Lübeck, Germany

feature. The constant extension of knowledge and data
prompts the need for necessary adaptations to the current
nomenclature and classification schemes. In the following
sections, we will present the most recent definitions, nomenclature, and consensus updates regarding clinical classification and etiology.

Definition of dystonia
Patients suffering from “dystonia musculorum deformans”
were published in 1911 by Oppenheim (Oppenheim 1911;
Klein and Fahn 2013), who thus coined the term dystonia.
The aforementioned individuals presented with muscle
spasms leading to twisted postures that were more severe
upon walking. These spasms or movements were described
as rapid and rhythmic. Furthermore, the symptoms were
of progressive nature and the muscle tone fluctuated from
hypotonic to tonic (Oppenheim 1911; Klein and Fahn 2013).
Oppenheim even pointed out that all individuals shared the
same geographic and ethnic background (Ashkenazi Jews)
indicating an inherited disorder. Over the following years, a
multitude of patients were described with different forms of
what would today be called dystonia.

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Still, it took more than 60 years from Oppenheim’s first
description of dystonia for the First International Dystonia
Symposium to take place in 1975. This opportunity was used
to reassess the clinical presentations of focal dystonia, such
as blepharospasm, spasmodic dysphonia, torticollis, oromandibular dystonia, and writer’s cramp. In the following years,
it was suggested to define dystonia as the umbrella term for
these heterogeneous disorders (Marsden 1976a, b; Sheehy
and Marsden 1982). Still, a crucial issue was the development of a coherent and systematic definition of dystonia and
associated syndromes, especially upon the identification of
(novel) genetic contributions and complex phenotypes. The
first consensus definition of dystonia was established by
an assigned committee of the Dystonia Medical Research
Foundation in 1984. Here, the syndrome was defined to consist “of sustained muscle contractions, frequently causing
twisting and repetitive movements, or abnormal postures”
(Fahn et al. 1987). However, the quickly growing body of
information on clinical presentations and etiological factors
of dystonia required frequent adjustment of definitions. Over
the past ~ 35 years, several limitations of previous definitions have been identified and, based on a consensus statement of a Task Force of the International Parkinson and
Movement Disorder Society, the revised definition states
in 2013: “Dystonia is a movement disorder characterized
by sustained or intermittent muscle contractions causing
abnormal, often repetitive, movements, postures, or both.
Dystonic movements are typically patterned, twisting, and
may be tremulous. Dystonia is often initiated or worsened by
voluntary action and associated with overflow muscle activation” (Albanese et al. 2013). Identification of an increasing
number of dystonia genes led to further refinement of the
classification to facilitate establishing a specific diagnosis
and genetic testing and counseling of dystonia patients. This
most recent and currently used classification scheme reduces
the number of conceptional axes to two, combining age at
onset and body distribution as clinical characteristics, which
also includes the temporal pattern and further associated
features. The second axis concerns the etiology with respect
to pathology of the nervous system as well as inheritance
and other acquisitions of the disease (Albanese et al. 2013).

Nomenclature
Whenever a group of disorders, in this case dystonia, and
associated features reach a certain level of complexity in the
way they are presenting, it is inevitable to refer to these phenotypes with a precise and uniformly used terminology. This
is not only beneficial for the involved neurologists and other
physicians caring for patients with dystonia, but also for the
patients themselves. There are numerous ways to categorize
different subgroups of a disorder and these classifications
have the tendency and also necessity to evolve over time.

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K. Grütz, C. Klein

Classifications can be organized according to clinical presentation, etiology or any other nominator that is of relevance
for the respective disorder. The terms isolated, combined and
complex dystonia, for example, provide immediate insight
into the clinical picture and whether the dystonic presentation is the sole phenotype or connected with other features,
possibly even as part of a different underlying condition.
For types of dystonia with a suspected genetic etiology,
originally, the designation “DYT”, i.e. DYT1, was introduced to catalogue chromosomal regions that had been
linked to a familial disorder, while the actual underlying
gene was still unidentified (Kramer et al. 1990). Multiple
problems regarding this system of designation have accumulated over time, including, but not limited to, multiple
designations for the same disorder or no further confirmation of an identified locus or later gene (Marras et al. 2012).
To establish a reference list for all genetically determined
movement disorders, the International Parkinson and Movement Disorder Society (MDS) Task Force for Nomenclature
of Genetic Movement Disorders recommends the following
criteria for a designation assignment (Marras et al. 2016):
(i) Disorders should only receive a designation when genetic
testing of the known gene or haplotype is possible. (ii) The
phenotype prefix has to be appropriately chosen and the phenotype has to be confirmed by two independent groups. The
prefix should refer to the most prominent phenotype of the
disorder, i.e. DYT in the case of dystonia. In cases with two
equally prominent features, a double prefix can be chosen
as is the case for DYT/PARK-ATP1A3. (iii) With respect to
the errors in the numerical listing and the identification of
further increasing numbers of causative genes, the number
suffixes should be replaced with the gene name. As an example, for early-onset generalized dystonia caused by mutations
in the TOR1A gene, the designation has changed from DYT1
to DYT-TOR1A. (iv) A designation should only be assigned
for monogenic disorders, while risk factor genes are to be
listed separately. (v) A certain threshold of evidence for a
genotype–phenotype correlation has to be reached to assign
a locus symbol. Besides a designation system for the genetically confirmed cases, a uniform classification is of high
relevance for all forms of dystonia and, thus, the relevant
nomenclature will be explained in the following sections in
the respective classification context.

Clinical classification
A set of four descriptors can and should be used to illustrate the phenomenology of dystonia, i.e. age at onset, body
distribution, temporal pattern, and associated features. The
clinical classification or Axis I, as described by Albanese
et al. (2013), is schematically shown in Fig. 1. The clinical
descriptors will be detailed in the following paragraphs.

Dystonia updates: definition, nomenclature, clinical classification, and etiology

397

Fig. 1  Clinical characteristics
(Axis I) (adapted from Albanese
et al. 2013). In the upper part of
the scheme, the four descriptors
age at onset, body distribution,
temporal pattern, and associated features are depicted with
additional categories (temporal
pattern) and all recommended
subcategories. In the lower
part, below the dark blue line,
two sets of clinical descriptors
are given as examples that are
frequently seen in the clinic,
although all other combinations
of descriptions are possible, as
well

Age at onset
Broadly accepted, the age at onset is of great importance
for the establishment of the diagnosis of a specific form of
dystonia, as well as for patient counselling and care, due to
its prognostic value. Children suffering from dystonia are
more likely to have a detectable cause and a tendency of the
dystonia to generalize, whereas dystonic signs in adulthood
are more likely to remain focal (Fig. 2). These two examples
display the two most extreme examples in the broad spectrum of disease presentation in combination with phenotypic
progression.
The observation that different phenotypes present within
distinct age groups has led to the use of age at onset as a
nominal classification. In this sense, three age groups
had been suggested in earlier classifications: childhood
(0–12 years), adolescent (12–20 years), and adult onset
(> 20 years) (Fahn 1988). In the following adaptations,

even more refined categories seemed appropriate as, for
example, the appearance of dystonia before the age of
1 year is most likely due to an inherited disorder (Sanger
2003). Therefore, Albanese and colleagues have suggested
a scheme to cluster age at onset in a similar fashion as it
is being done for other neurological disorders: (i) infancy
(birth to 2 years), (ii) childhood (3–12 years), (iii) adolescence (13–20 years), (iv) early adulthood (21–40 years), (v)
late adulthood (> 40 years) (Albanese et al. 2013). For some
types of dystonia, the age at onset may be covering two (or
more) of these clusters, as the phenotypic variability cannot always be forced into such rather fixed borders. When
focusing on monogenic forms of dystonia, age clusters are
observed for individual forms of dystonia. DYT-TOR1A, for
instance, has a median age at onset of 9 years (childhood),
whereas age at onset in DYT-GNAL would be classified at
the upper end of the early adulthood group with a median
age at onset of 38 years (MDS Gene, www.mdsge​ne.org).

Fig. 2  Disease progression.
Dark blue indicates body
regions affected with dystonia.
Children presenting with focal
dystonia have a higher tendency
to progress to generalized dystonia (a), while individuals with a
late onset, in this case a woman
with blepharospasm, will commonly remain stable in their
dystonic presentation (b)

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When grouping the forms of monogenic isolated dystonia
together, the median age at onset ranges from 6 to 38 years,
while the combined forms range from 0 to 40 years in terms
of age at onset (MDS Gene, www.mdsge​ne.org). This additionally highlights how important it is to relate the clinical
description to age at onset of a patient to identify patterns
or certain characteristics that will help establish a specific
diagnosis or treatment.

Body distribution
Dystonic signs can present in any given region of the body.
Usually, the cranial and cervical region, the larynx and trunk
as well as the limbs are affected, either individually or in
any given combination. Diagnosis and also effective therapy
vastly depend on the classification of symptomatic body
regions. Despite the complexity and magnitude of dystonia
subtypes, effective treatments, including oral medications,
botulinum toxin, and surgical interventions are available for
the majority of patients (Jinnah 2020).
Furthermore, the clinical description of involved regions
might help predict motor symptoms in the course of the
disease. The pattern of distribution my change over time,
leading to involvement of additional dystonic regions. The
following classifications should be considered according to
the latest consensus update (Albanese et al. 2013):
“Focal Dystonia: Only one body region is affected. Typical examples of focal forms are blepharospasm, oromandibular dystonia, cervical dystonia, laryngeal dystonia, and
writer’s cramp. Cervical dystonia is considered a form of
focal dystonia, although by convention, the shoulder can be
included as well as the neck.
Segmental Dystonia: Two or more contiguous body
regions are affected. Typical examples of segmental forms
are: cranial dystonia (blepharospasm with lower facial and
jaw or tongue involvement) or bibrachial dystonia.
Multifocal Dystonia: Two noncontiguous or more (contiguous or not) body regions are involved.
Generalized Dystonia: The trunk and at least two other
sites are involved. Generalized forms with leg involvement
are distinguished from those without leg involvement.
Hemidystonia: More body regions restricted to one body
side are involved. Typical examples of hemidystonia are due
to acquired brain lesions in the contralateral hemisphere.”

Temporal pattern
Signs and severity can vary widely over time. For instance,
dystonia can spread, as mentioned in the previous section,
which allows for a distinction of static and progressive
forms. The phenomenology can show momentary and diurnal variability and fluctuate from day to day or during the
course of a single day, as seen in dopa-responsive dystonia.

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K. Grütz, C. Klein

The variability of the phenotype also allows distinguishing forms with a consistent occurrence, i.e. task or actionspecific dystonia or dystonia at rest, from trigger-induced
variable forms (e.g. paroxysmal dystonia). Further factors
modifying the phenotype in addition to voluntary actions
and external triggers are compensatory phenomena, gestes
antagonistes (or alleviating movements) or psychological
state (Albanese et al. 2013). Clinically, the temporal pattern
is especially important to define a specific diagnosis and also
treatment options. Temporal phenotypic variability can be
categorized into four groups:
Persistent: This describes dystonia present throughout the
day with roughly the same intensity.
Paroxysmal: Episodes of dystonia are self-limited and
typically induced by a trigger. After the episode, the patient
returns into the previous neurological state.
Diurnal fluctuations: Phenomenology, severity and presence of dystonia vary following obvious circadian rhythm.
Action-specific: Dystonic movements that are only present
while execution a very specific task.

Associated features
Dystonia can be the sole phenotype, or it might occur
in conjunction with other movement disorders. As such,
forms of dystonia combined with myoclonus, parkinsonism, or other movement disorders have been termed as
defined syndromes. Previously, syndromes manifesting
only with dystonia have been considered “primary” (Fahn
et al. 1998; Fahn 2011). The term “primary” is widely
used in other disorders, meaning either that the condition
presented as first sign, that it is the major subgroup, or to
describe that no other irregularity has been detected (Webster’s New World Medical Dictionary 2008). It is thus recommended to use terms that unambiguously describe the
clinical presentation without having a connotation regarding the etiology of the disease (Albanese et al. 2013). For
this reason and further extending beyond a dichotomous
scheme of isolated vs. combined dystonia, we would like
to suggest the use of three terms, i.e. isolated, combined,
and complex dystonia, each of which will be featured in
accompanying reviews of this issue (Domingo et al. 2020;
Weissbach et al. 2020; Herzog et al. 2020). Isolated dystonia describes phenotypes, where dystonia is the sole motor
feature, with the exception of tremor. In the case of combined dystonia, other movement disorders, i.e. parkinsonism, myoclonus, or dyskinesia, present in conjunction with
dystonia (Klein et al. 2017). Of note, the combination of
dystonia with non-motor features has also been reported
in multiple instances (Novaretti et al. 2019; Timmers et al.
2019; Ferrazzano et al. 2019). Complex dystonia describes
syndromes composed of dystonia in conjunction with other
neurologic or systemic presentations. In many of these

Dystonia updates: definition, nomenclature, clinical classification, and etiology

syndromes, dystonia may only be an inconsistent feature
or not the most prominent disease manifestation and there
is wide phenotypic variability with respect to dystonia
across individual patients. These syndromes include, but
are not limited to, a range of neurodegenerative diseases,
disorders leading to brain calcification, disorders of heavy
metal metabolism, neurodegeneration with brain iron

399

accumulation (NBIA), lipid storage disorders, mitochondrial disorders, organic acidurias, and disorders of thiamine metabolism (Klein et al. 2017). In Wilson disease,
for example, dystonia presents in conjunction with neurological or psychiatric features, as well as a dysfunctional
liver (Rosencrantz and Schilsky 2011).
Although the focus of the present article is on dystonia
and dystonic syndromes per se (i.e. isolated combined,
and complex forms of dystonia), it should be noted that,
when it comes to the mere frequency of dystonic signs
irrespective of the primary underlying condition, dystonia most commonly occurs as a clinical sign within other,
more common conditions, such as Parkinson’s disease, or
as a side effect of drugs used to treat psychiatric disorders
(Mulroy et al. 2020). This consideration is schematically
illustrated in Fig. 3.

Etiology

Fig.3  Schematic overview on the occurrence of dystonia as a clinical sign according to frequency regardless of the underlying primary
condition

The second axis of classification is based on the etiological background of dystonia. A schematic representation is
depicted in Fig. 4. Even though our understanding of the
etiology of dystonia has evolved over time, for most forms
it still cannot be fully explained. With new information,
clinical, genetic and from basic science, the classification
of dystonia based on etiology will have to be constantly
adapted. The term “primary” which was or still is used as
an etiological category for genetically confirmed isolated
dystonia without other pathological findings (Fahn et al.
1998), is no longer suggested (Albanese et al. 2013).

Fig. 4  Etiology (Axis II)
(adapted from Albanese et al.
2013). The etiological axis is
subdivided into the contribution
of the nervous system and the
presence of genetic or acquired
origin leading to development
of dystonia. As an example, an
etiological description of a dystonia case can be ‘evidence of
degeneration’ and an ‘X-linked
recessive inheritance pattern’, as
it the case for X-linked dystonia
parkinsonism (DYT/PARKTAF1)

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Pathological findings of the nervous system
in dystonia
In keeping with its heterogeneity and broad spectrum including both degenerative and (likely) non-degenerative conditions, there is no uniform anatomical description of dystonia.
Several studies suggest that there is no apparent macroscopic
degeneration or irregularity in the brain in isolated dystonia (Rostasy et al. 2003; Paudel et al. 2012, 2016). This
is different in forms of dystonia with a neurodegenerative
pattern, such as DYT/PARK-TAF1 (Hanssen et al. 2019).
Neuroimaging studies, on the other hand, have identified
more subtle alterations, with respect to cortical thickness
and gray matter volume differences in cortical regions, basal
ganglia, thalamus, hippocampus, and amygdala in focal dystonia (Tomić et al. 2020), as well as for the subthalamic area
of the brain stem in myoclonus-dystonia (van der Meer et al.
2012). Other studies have identified cellular alterations in
specific forms of dystonia, such as neuronal inclusions in
brainstem nuclei in patients with DYT-TOR1A (McNaught
et al. 2004), suggesting abnormalities on the cellular level.
These findings still need further replication and extension,
as is true for another line of research linking dystonia to
cerebellar dysfunction based on Purkinje cell loss and axonal
swelling in the cerebellum of patients suffering from cervical dystonia (Prudente et al. 2013). Recently, it has been
shown that the genetic reduction of Lpin1 in a Tor1a mouse
model had a positive effect on survival but also suppressed
motor dysfunction and nuclear membrane pathology (Cascalho et al. 2020). The molecular pathophysiological construct in dystonia will be more detailed in an accompanying
review (Gonzalez-Latapi et al. 2021).
With more studies possibly identifying cellular alterations with more specific deficits, the terminology of pathological changes will have to be reconsidered and adapted
in future classifications of dystonia. Nevertheless, the identification of degeneration, be it macroscopic, microscopic
or on a molecular basis, provides a valuable discriminator
for different forms of dystonia with respect to pathological
abnormalities. According to the latest consensus update,
the first subgroup is considered to show degeneration, with
a progressive abnormality, e.g. neuronal loss. The second
group shows static lesions, either non-progressive anomalies
or acquired lesions, and the third subgroup displays no evidence of degeneration or structural lesions (Albanese et al.
2013).

Inherited dystonia
Inherited forms of dystonia require a confirmed genetic origin and can again be subdivided into multiple groups according to the pattern of inheritance.

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K. Grütz, C. Klein

Autosomal dominant: Several forms, such as DYTTOR1A (Ozelius et al. 1997), DYT/PARK-GCH1 (Ichinose
et al. 1994; Segawa et al. 2003), DYT-THAP1 (Fuchs et al.
2009), DYT-SGCE (Zimprich et al. 2001), and DYT/PARKATP1A3 (De Carvalho Aguiar et al. 2004), fall into the category of autosomal dominantly inherited dystonia.
Autosomal recessive: This subgroup includes forms, such
as DYT-ATP7B, also known as Wilson disease (Bull et al.
1993), NBIA/DYT-PANK2 or pantothenate kinase-associated neurodegeneration (PKAN) (Zhou et al. 2001), and
NBIA/DYT/PARKa-PLA2G6 or PLA2G6-associated neurodegeneration (PLAN) (Morgan et al. 2006). Also, multiple
metabolic disorders can be found in this category.
X-linked recessive: This subgroup contains disorders,
such as DYT/PARK-TAF1 (Makino et al. 2007), DYT/
CHOR-HPRT or Lesch-Nyhan syndrome (Gibbs and Caskey
1987), and DYT-TIMM8A, also known as Mohr-Tranebjaerg
syndrome (Tranebjærg et al. 2000) which are all inherited in
an X-chromosomal fashion.
Mitochondrial: Inherited forms with mutations in the
mitochondrial genome are, for example, Leigh syndrome
or DYT-mt-ND6 (Leber optic atrophy and dystonia) (Kim
et al. 2010).
Notably, a large proportion of the recessive forms (autosomal and X-linked) as well as the mitochondrial forms are
classified as complex dystonia forms, whereas all isolated
dystonias with a known genetic causality are inherited in an
autosomal dominant fashion (Klein et al. 2017).

Acquired dystonia
Several causal factors for the acquisition of dystonia have
been documented so far. A useful categorization is illustrated in the following list adapted from (Albanese et al.
2013):
Perinatal brain injury: dystonic cerebral palsy, delayedonset dystonia.
Infection/inflammation: viral encephalitis, encephalitis lethargica, subacute sclerosing panencephalitis, human
immunodeficiency virus (HIV) infection, autoimmune
causes, other (tuberculosis, syphilis, etc.)
Drugs: levodopa and dopamine agonists, neuroleptics
(dopamine receptor blocking drugs), anticonvulsants, and
calcium channel blockers.
Toxic: manganese, cobalt, carbon disulfide, cyanide,
methanol, disulfiram, and 3-nitropropionic acid.
Vascular: ischemia, hemorrhage, and arteriovenous malformation (including aneurysm).
Neoplastic: brain tumor, and paraneoplastic encephalitis.
Brain injury: head trauma, brain surgery (including stereotactic ablations), and electrical injury.
Functional

Dystonia updates: definition, nomenclature, clinical classification, and etiology

Dystonia of unknown etiology
Dystonia with an unknown cause, can be further divided
into sporadic and familial forms. In case of familial forms,
it seems likely that there is a genetic contribution. With the
discovery of novel dystonia genes, such as GNAL, ANO3,
KCTD17, and KMT2B (Charlesworth et al. 2012; Fuchs et al.
2013; Mencacci et al. 2015; Meyer et al. 2017), these subtypes can now be allocated to the realm of inherited forms
of dystonia.

Additional observations and perspectives
The current classifications combine the most important
observations that have been made concerning dystonia. Nevertheless, not all pieces of information have been included or
even identified. As previously shown, an important point is
the constant adaptation of any classification scheme according to the most current knowledge. This also includes an
engaged exchange of information between clinicians, scientists, caregivers, and last but not least, patients, as they
benefit from as specific a diagnosis and refined a prognosis
of their disorder as possible. As an example, recent findings
have identified patterns of symptom spreading in adult-onset
isolated focal dystonia (Berman et al. 2020). However, even
with knowledge about the genetic origin of a disease, an
individual prognosis can be difficult, if not impossible due
to the broad phenotypic spectrum, sometimes even within
families. Still, at a group level, certain patterns with regard
to body distribution of dystonic features can be recognized
when comparing different monogenic forms of dystonia
(Fig. 5).
Of translational relevance, testing guidelines can be
refined upon identification of clinical patterns (Bressman
et al. 2000). First, a clinical categorization can lead to better defined genetic testing, second, a specific diagnosis can
help determine a progression pattern and, third, may also
allow for a better prediction of response to treatment, such

401

as deep brain stimulation, dopaminergic medication, etc.
(Jinnah et al. 2018). Thus, treatment response may offer yet
another aspect of classification.
In addition to already known genetic causes of dystonia,
genetic risk factors could also play a role in disease etiology
and may become important for classificational purposes in
the future. Due to the heterogeneity of dystonia and associated syndromes, as well as its overall rarity, no large genetic
association studies have been conducted to date. In more
defined groups of patients, i.e. isolated dystonia, several
studies, almost exclusively candidate-based, have been performed but no compelling association has been identified
(Ohlei et al. 2018). Furthermore, variants in several molecular pathways have been detected, however, with the necessity to confirm a robust association in larger cohorts (Siokas
et al. 2018).
Assembly of data on dystonia patients (on a national or
even international) level has evolved greatly over the years.
This has led to the ability to conduct large cross-sectional
studies that will enable the identification of factors influencing the prevalence and phenomenology of clinical characteristics, such as tremor, in dystonia (Shaikh et al. 2020).
Genetic forms, while being of great importance to disease modeling using basic science approaches, only explain
the disease in a minor proportion of cases. The majority
of patients will not have a monogenic origin of dystonia.
Importantly, however, there are patterns linking the likelihood of a genetic origin to certain phenotypic expressions.
For example, it is more likely to identify a genetic cause in
patients with dystonia of the extremities versus those suffering from a cranial form (Fig. 6a). Equally compelling
is the observation that, overall, more women are affected
with dystonia in comparison to men (Epidemiologic Study
of Dystonia in Europe (ESDE) Collaborative Group 1999)
(Fig. 6b). When analyzing individual subgroups of dystonia, however, also the reverse scenario is possible with an
excess of affected males in most focal task-specific dystonias
(Meoni et al. 2020), highlighting the as yet poorly understood influence of gender on the development of dystonia.

Fig. 5  Body distribution with
respect to genetic background.
Different shades of blue indicate
the different clinical presentations with darker tones relating
to more severe presentations.
The fractions are in accordance
with the numbers reported by
Lange et al. (2021)

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K. Grütz, C. Klein

Fig. 6  Distribution of signs and gender differences. a Affected body regions are shown in dark blue. Dystonia of the extremities is more likely to
have a genetic origin. b Dark blue represents affected individuals. Women are overall more likely to develop dystonic signs than men

Even more complex systems biology approaches may
lead to the development of further means of categorization
of dystonia patients. A recent study has modeled the contribution of dystonia-associated genes to dystonia pathology
(Mencacci et al. 2020). This study also highlights that both
types of studies, candidate-based genetic and functional
studies as well as hypothesis-free studies, will likely contribute to a more refined subgrouping of the dystonias in
the future.
In conclusion, all of the above-mentioned definitions,
terms, and classification schemes are of tremendous importance for three reasons: (i) They can be used to comprehensively and specifically describe the spectrum of signs and
related information of any (dystonia) patient to all involved
parties, i.e. the patient, clinicians, caregivers, but also

Fig. 7  Factors contributing to
the development and expression of dystonia. Several parts
of the puzzle have already been
assembled, whereas other pieces
of yet unknown entities still
need to be added

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geneticists and scientists. (ii) The classifications enable the
detection of certain patterns and thus facilitate the establishment of a specific diagnosis. (iii) Existing classifications can
be the starting point for future refinements and additions,
stemming from scientific discoveries in clinical research,
basic science and system biology approaches, genetic analyses, and treatment development. Ultimately, the identification and integration of all of these pieces of the puzzle
(Fig. 7) will lead to an improved understanding of dystonia
and patient care.
Author contributions Conceptualization: KG and CK. Literature search
and drafting: KG. Critical revision: CK.

Dystonia updates: definition, nomenclature, clinical classification, and etiology
Funding Open Access funding enabled and organized by Projekt
DEAL. The study was supported by the Deutsche Forschungsgemeinschaft (FOR 2488 to CK) and by the Dystonia Medical Research Foundation (to KG).

Compliance with ethical standards
Conflicts of interest CK serves as a medical advisor to Centogene for
genetic testing reports in the fields of movement disorders and dementia, excluding Parkinson’s disease.
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