metricas
covid
Buscar en
Neurología (English Edition)
Toda la web
Inicio Neurología (English Edition) Degenerative dementias: a question of syndrome or disease?
Información de la revista
Vol. 37. Núm. 6.
Páginas 480-491 (julio - agosto 2022)
Visitas
2546
Vol. 37. Núm. 6.
Páginas 480-491 (julio - agosto 2022)
Review article
Open Access
Degenerative dementias: a question of syndrome or disease?
Demencias degenerativas: ¿un dilema de síndromes o de enfermedades?
Visitas
2546
A. Robles Bayón
Unidad de Neurología Cognitiva, Hospital HM Rosaleda, Santiago de Compostela, La Coruña, Spain
Este artículo ha recibido

Under a Creative Commons license
Información del artículo
Resumen
Texto completo
Bibliografía
Descargar PDF
Estadísticas
Abstract
Background

Neurologists refer to numerous “syndromes,” consisting of specific combinations of clinical manifestations, following a specific progression pattern, and with the support of blood analysis (without genomic-proteomic parameters) and neuroimaging findings (MRI, CT, perfusion SPECT, or 18F-FDG-PET scans). Neurodegenerative “diseases,” on the other hand, are defined by specific combinations of clinical signs and histopathological findings; these must be confirmed by a clinical examination and a histology study or evidence of markers of a specific disorder for the diagnosis to be made. However, we currently know that most genetic and histopathological alterations can result in diverse syndromes. The genetic or histopathological aetiology of each syndrome is also heterogeneous, and we may encounter situations with pathophysiological alterations characterising more than one neurodegenerative disease. Sometimes, specific biomarkers are detected in the preclinical stage.

Development

We performed a literature review to identify patients whose histopathological or genetic disorder was discordant with that expected for the clinical syndrome observed, as well as patients presenting multiple neurodegenerative diseases, confirming the heterogeneity and overlap between syndromes and diseases. We also observed that the treatments currently prescribed to patients with neurodegenerative diseases are symptomatic.

Conclusions

Our findings show that the search for disease biomarkers should be restricted to research centres, given the lack of disease-modifying drugs or treatments improving survival. Moreover, syndromes and specific molecular or histopathological alterations should be managed independently of one another, and new “diseases” should be defined and adapted to current knowledge and practice.

Keywords:
Biomarkers
Dementia
Disease
Neurodegenerative diseases
Syndrome
Resumen
Introducción

En Neurología cognitiva se identifican múltiples «síndromes», consistentes en combinaciones específicas de manifestaciones clínicas, con una evolución determinada y con el apoyo de un análisis de sangre (sin parámetros de genómica-proteómica) y pruebas de neuroimagen (TAC, resonancia, SPECT de perfusión, PET con 18F-fluorodesoxiglucosa). Por otra parte, las «enfermedades» neurodegenerativas demenciantes representan combinaciones clínico-histopatológicas concretas, cuya presencia debe comprobarse en la exploración del enfermo, junto con un estudio histológico o evidencia de marcadores del trastorno molecular específico. No obstante, actualmente se sabe que la manifestación sindrómica de cada alteración histopatológica o genética es variada, que el sustrato histopatológico o genético de cada síndrome también lo es y que a veces coexisten alteraciones fisiopatológicas de más de una enfermedad neurodegenerativa. Además, ocasionalmente se detectan biomarcadores específicos en la fase preclínica.

Desarrollo

Tras realizar una búsqueda bibliográfica de casos con alteración histopatológica o genética discordante con la esperada para el síndrome observado, y de casos con coexistencia de enfermedades degenerativas, resulta evidente la heterogeneidad y solapamiento entre síndromes y enfermedades neurodegenerativas. Además, en la revisión se comprueba que los tratamientos que se prescriben a pacientes con enfermedades degenerativas son sintomáticos.

Conclusiones

De la revisión se desprende que, mientras no existan tratamientos modificadores de la progresión o la supervivencia, la búsqueda de marcadores de enfermedad debe quedar reservada a Centros investigadores. Además, deberían manejarse de modo independiente los síndromes y las alteraciones moleculares e histopatológicas específicas, con definición de nuevas «enfermedades», adaptada a los conocimientos y la práctica actuales.

Palabras clave:
Biomarcadores
Demencia
Enfermedad
Enfermedades neurodegenerativas
Síndrome
Texto completo
Introduction

In the latter quarter of the 19th century, Ramón y Cajal and other histologists established the basis for the development of microscopic anatomical pathology, enabling the study of the cellular substrate of healthy and diseased organic tissues. As a result, in the following decades, some neurologists and psychiatrists who also practised neuropathology described histopathological alterations in the brains of patients who developed dementia with specific clinical manifestations. After an initial publication (or communication), if other researchers reported similar cases (with the same combination of clinical and pathological signs), then a new nosological concept was introduced; the new entity was frequently assigned the name “disease” plus the name of the author of the first description (e.g., Pick disease, Alzheimer disease [AD], Steele-Richardson-Olszewski disease).

The laboratory and neuroimaging techniques invented and developed in the 20th century led to huge advances in our understanding of the molecular and genetic substrates of the neurodegenerative diseases that cause dementia. Furthermore, the description of patterns of cognitive impairment and other associated neurological alterations, together with neuroimaging findings, enabled the definition of specific phenotypes (e.g., corticobasal syndrome, semantic variant primary progressive aphasia, posterior cortical atrophy).

This expansion of medical knowledge resulted in the modification of diagnostic algorithms. In fact, criteria for the diagnosis of degenerative diseases that cause dementia need to be updated with ever-increasing frequency. Until several decades ago, a patient displaying progressive dementia with predominant amnestic disorder, changes in social behaviour, choreic dyskinesia, or recurrent falls and supranuclear ophthalmoparesis, and no neuroimaging evidence of hydrocephalus, tumours, or relevant vascular lesions, would be diagnosed with AD, frontotemporal degeneration (FTD; or Pick disease), Huntington disease, or progressive supranuclear palsy (PSP; or Steele-Richardson-Olszewski disease), respectively, with the assumption that the anatomopathological substrate would be that considered specific to each disease. Subsequently, diagnostic criteria included specific signs of the corresponding degenerative disease (e.g., atrophy of the medial temporal lobe in AD, or in the prefrontal and anterior temporal regions in frontotemporal dementia), which are not pathognomonic of the suspected causal entity but which do increase the probability of correct clinical diagnosis. With the arrival of functional neuroimaging in clinical settings, and the availability of some biochemical and genetic markers, some degenerative diseases (such as Huntington disease or AD) can be diagnosed in the prodromal and even in the presymptomatic phase.1–3 More complete understanding of the chronology of syndromic patterns also resulted in new proposed criteria for aetiological diagnosis in the pre-dementia phase in the absence of molecular markers (Lewy body dementia,4 frontotemporal dementia5).

The emergence of markers of the molecular substrate of degenerative diseases represents a historic step in their diagnosis. Diagnostic criteria for AD have followed this trend, with the 2018 National Institute on Aging-Alzheimer’s Association (NIA-AA) diagnostic criteria6 requiring the detection of altered levels of β-amyloid 42 (Aβ42; measured with positron emission tomography [PET] with amyloid tracers or through determination of Aβ42 in the cerebrospinal fluid [CSF]) and phosphorylated tau protein (measured using PET with tau tracers or determination in the CSF). With a view to ensuring high specificity, the 2014 IWG-1 criteria7 no longer consider medial temporal lobe atrophy or temporoparietal hypometabolism on 18F-FDG PET images to be pathognomonic of AD, despite these being markers of probable neurodegeneration, and the 2018 NIA-AA criteria6 do not allow for diagnosis based solely on the presence of the typical mutations associated with the disease. Following this line of reasoning, other neurodegenerative “diseases” may not be diagnosed unequivocally until markers of specific underlying molecular alterations can be established.8–13

This subject is further complicated by the fact that many patients presenting biomarkers of the molecular and/or genetic substrate of given disease eventually develop a clinical syndrome other than that expected, or show different combinations of only some parts of the syndrome. In other words, phenotypic heterogeneity has been demonstrated in association with specific proteinopathies or mutations. Likewise, patients with a specific syndrome may present diverse molecular or genetic substrates. Occasionally, patients initially present one syndrome and subsequently develop signs of one or more other syndromes, or switch between syndromes.14,15 Moreover, some patients with a particular syndrome present neuropathological alterations characteristic of more than one disease. This historical development eventually led to the term “Pick disease” being replaced with “frontotemporal degeneration,” as many patients with classical symptoms of the disease (changes in personality and progressive dysphasia due to frontal lobe dysfunction) did not present the expected tauopathy with intraneuronal Pick bodies.16 At least 3 phenotypes of FTD have since been described (behavioural variant frontotemporal dementia, nonfluent/agrammatic primary progressive aphasia, and semantic variant primary progressive aphasia); a clinical and neuropathological overlap has also been observed between these phenotypes and those attributed to corticobasal degeneration (CBD) and PSP. As a result, these entities were grouped together in a new construct, the “Pick complex.”14 The problem is compounded by the fact that CBD and PSP also display diverse phenotypes.17,18 Furthermore, the heterogeneity and overlaps also extend to other diseases considered to be mutually independent. For this reason, criteria have had to allow for the clinical diagnosis of a “disease” (a nosological construct with a specific molecular substrate) to be classified as possible, probable, or definite, thereby acknowledging the fact that, without autopsy findings or unequivocal biomarkers pointing to specific underlying pathophysiological phenomena, no syndrome in and of itself is sufficient to securely diagnose a given degenerative disease as the cause.6,7

Given that the clinicopathological overlaps between syndromes and diseases extend to a significant part of degeneration in cognitive neurology, and the fact that we are yet to discover efficacious drugs targeting phenomena closely linked to the molecular pathologies that define these “diseases,” it is unclear whether we should dedicate time, effort, and resources to the diagnosis of these “diseases” in purely clinical settings.

Methods

Based on the hypothesis that diagnosis of a degenerative dementia disorder is non-specific in the absence of markers of the underlying molecular pathology, a literature search was performed to identify cases of discrepancies between the clinical picture observed (syndrome) and the underlying molecular alteration (specific to the disease): in other words, situations in which the aetiological diagnosis differed from that expected based on the syndrome observed. The review also included reports of cases of simultaneous presentation of at least 2 different types of neurodegenerative dementia.

Another literature search reviewed the pharmacological treatments currently prescribed to patients with neurodegenerative dementias. These drugs are intended to control specific clinical manifestations caused by the loss of activity of neuronal circuits, resulting in a progressive reduction in the subpopulation of diseased cells, which leads to an imbalance in the activity of certain neurotransmitters. In other words, symptomatic treatments are currently prescribed due to the lack of disease-modifying treatments.

Results

Table 1 shows the diseases (entities with specific molecular or histopathological features) diagnosed in patients who in life showed specific clinical syndromes. It also includes the clinical expressions observed in patients with specific genetic mutations.

Table 1.

Degenerative diseases and genetic alterations reported as the cause of various clinical syndromes.

Syndromea  Degenerative disease responsible  Mutated gene 
Alzheimer syndromeb  AD,#;19,20 LBD,19,20 FTD,20 CBD,20 CJD,21, AGD,19,20 PSP20  PSEN1,#APP, PSEN2, C9orf72,22MAPT,23GRN23 
“Posterior cortical atrophy” syndrome  AD,#;24 CBD,24,25 LBD,24 CJD24  PRNP,26GRN,26HTT,27MAPT,26PSEN1,26PSEN2,26TREM2,26 trisomy 21 (Down syndrome)28 
Logopenic variant PPA  AD,#;29 FTD29  GRN30 
Nonfluent variant PPA  FTD,#;29 AD,29 CBD,29 PSP,29 LBD,29 CJD,31 MSA32  C9orf72,22CSF1R,33GRN,34MAPT35 
Semantic variant PPA  FTD,#;29 AD,29 LBD36  C9orf72,22,37GRN37 
Dementia with apathy or abulia  FTD,#;38,39 PDD,#;40 PSP,#;38,41 LBD,38 CBD,38,42 AD39  GRN,#;34,43HTT,#;44DCTN1,45C9orf72,46MAPT,47PRNP,48,49PSEN1,50SNCA51 
Dementia with early or intense behavioural disinhibition and/or changes in personality  FTD,#;52,53 AD,52–54 AGD,55 CBD,56 PSP,57 Tourette Sd.58  C9orf72,#;46HTT,53,59MAPT,60TBK143 
Progressive dysexecutive syndrome  AD,54 PSP,61 FTD,52 CBD62  SCA36,63SNCA,51PSEN150 
Dementia with MNDc  FTD,#;64,65 AD,66 CJD67  C9orf72,#;46,64ATXN2,68FUS,69GRN,64HTT,70OPTN,64SQSTM1,64TARDBP,64TBK1,60SOD1,71,72SPG11 or SPG4,73UBQLN2,64VCP64 
Dementia with early or marked psychotic symptoms  LBD,# FTD,74 AD,52,74 CJD,74,75 HD74  C9orf72,22,23,76CLN3,77GRN,23HTR2A,78NPC1 or NPC2,79PSEN280 
Dementia with marked primary parkinsonism  PDD,# LBD,# PSP,#;81 MSA,82 Guam parkinsonism–dementia complex,83 CBD,81 AD,84 CJD,21,85 Guadaloupean parkinsonism86  ATP13A2,87ATP7B,88C9orf72,81CHMP2B,81DCTN1,23,89FXTAS,90GBA,87,91GRN,81HTT,92JPH3,93MAPT,81LRRK2,94PRNP,95PSEN1,87SNCA87 
Corticobasal syndrome  CBD,#;25,56,96 PSP,25,56,96 FTD,25,96 AD,19,25,96 CJD,97 MSA,32 PDD96  GRN,#;60,98MAPT,23,98C9orf72,22,98PSEN199 
Steele–Richardson–Olszewski syndrome (classical PSP)  PSP,#;55 CBD,55,96 FTD,100 LBD,35 CJD84  MAPT,#;23,98C9orf72,98GRN,98TBK1101 
Dementia with choreic dyskinesia (Huntington syndrome or HD phenocopy)  Primary Huntington syndrome without known mutation102  HTT,#C9orf72,#;22,103ATN1,103,104ATXN2,105ATXN8,103CP,106FTL1,107GM2A,108JPH3,103PPP2R2B,109PRNP,103RNF216,110TARDBP,111TBP,103TREM2,112VPS13A,103XPA113 
Dementia with cerebellar ataxia  MSA,114 CJD,115 mitochondrial disease,116 PSP117  mtDNA,118ATN1,104ATXN2,119CP,106EPM2A,120EPM2B,121HTT,122NPC1 or NPC2,78PRNP,123TBP124 
Dementia with marked alteration of the autonomic nervous system  MSA,125 LBD,125,126 PDD,126 FTD,127 AD,127 CJD128,129  HTT,130DCTN1,23PRNP131 
Suspected CJD  CJD,#;21 LBD,74 FTD132  PRNP,133C9orf7222 

AD: Alzheimer disease; AGD: argyrophilic grain disease; CBD: corticobasal degeneration; CJD: Creutzfeldt-Jakob disease; FTD: frontotemporal degeneration (in Tables 1 and 2, the abbreviation encompasses all categories [FTD-tau, FTD-TDP; FTD-FUS, and FTD secondary to ubiquitin-proteasome system alterations] and their elements, with the exception of PSP, CBD, and AGD, which are considered separately); HD: Huntington disease; LBD: Lewy body dementia; MND: motor neuron disease (including amyotrophic lateral sclerosis, primary lateral sclerosis, and hereditary spastic paraplegia); MSA: multiple system atrophy; PDD: Parkinson’s disease dementia; PPA: primary progressive aphasia; PSP: definite progressive supranuclear palsy.

#

Most frequent reported cause according to the literature search.

a

In the field of cognitive neurology.

b

Typical Alzheimer syndrome consists of progressive amnestic syndrome of hippocampal type, presenting early in the course of the disease, either in isolation or associated with other cognitive or behavioural alterations characteristic of cognitive impairment or dementia. Amnestic syndrome of hippocampal type causes significant difficulties solving tests of episodic memory that include hints for coding when information is recorded, or cues to assist with retrieval. Medical history interviews, examination, and complementary tests (at least one blood analysis and one neuroimaging study) may not identify potential causes of the symptoms, whether they are characteristic of non-Alzheimer degenerative disease and/or non-degenerative disorders.

Table 2 summarises cases of patients with co-presence of more than one neurodegenerative disease potentially causing dementia.

Table 2.

Cases presenting anatomical pathology findings suggesting more than one of the classical degenerative diseases that cause dementia.

  AD  FTD  PSP  CBD  PDD/LBD  MSA  HD  CJD 
FTD  x19,134               
PSP  x19,134  x19             
CBD  x19,134  x135  x136           
PDD/LBD  x19,134,137  x19,134  x134,138  x19,138         
MSA  x134    x139    x138       
HD  x140  x141    x142         
CJD  x19,134        x143,144  x145     
AGD  x19,146,147  x147  x146,147  x146,147  x143,146  x148    x143,149 

Abbreviations: see footnote to Table 1.

Table 3 lists the treatments currently prescribed for patients with degenerative dementia and the clinical manifestations they target.

Table 3.

Drugs habitually prescribed to treat cognitive symptoms.

Syndrome  Drugs indicated or with recognised efficacy  References 
Alzheimer syndromea  Cholinesterase inhibitors, memantine  150 
Corticobasal syndrome and Steele-Richardson-Olszewski syndrome  Levodopa,b rotigotine,b baclofen,c clonazepam,c,d diazepam,c,d zolpidem,c,d levetiracetamd  151 
Huntington syndrome or HD phenocopy  Tetrabenazine,e deutetrabenazine,e antipsychoticse,f  152,153 
Suspected CJD  Clonazepamd  154 
Apathy syndrome  Cholinesterase inhibitors,g methylphenidate, ginkgo biloba  155,156 
Behavioural disinhibition (social, sexual, dietary)  SSRIs, quetiapine, gabapentin, carbamazepine, medroxyprogesterone  157 
Primary psychotic symptoms in degenerative dementia  Second-generation antipsychotics, rivastigmine,g donepezilg  158–161 
Primary parkinsonism in patients with cognitive-affective disorder of degenerative origin  Levodopa, non-ergot dopaminergic agonists,h MAO-B inhibitors  162–164 
Ataxia in patients with neurodegeneration and dementia  Miglustat,i riluzole  165,166 
Dementia with marked alteration of the autonomic nervous system  Symptomatic treatment for each dysautonomic symptomj  167 

CJD: Creutzfeldt-Jakob disease; HD: Huntington disease; MAO-B: monoamine oxidase B; SSRI: selective serotonin reuptake inhibitors.

a

See description for b in the footnote to Table 1.

b

Improve rigidity and hypokinesia.

c

Improve dystonia.

d

Improve myoclonus.

e

Improve chorea.

f

Improve psychotic symptoms, aggressiveness, and impulsivity.

g

In patients with Alzheimer disease, Lewy body dementia, or Parkinson’s disease dementia.

h

Greater benefit in patients presenting apathy or depression; not indicated in patients with psychotic symptoms or impulse control disorders.

i

For patients with Niemann-Pick disease type C.

j

Neurogenic orthostatic hypotension; neurogenic supine hypertension, dysphagia, sialorrhoea, gastroparesis, constipation, neurogenic detrusor overactivity or underactivity, erectile or ejaculatory dysfunction, anorgasmia.

Discussion

The literature review revealed great heterogeneity (Table 1), both in the aetiology of each syndrome (the left column of the table lists the most relevant syndromes in cognitive neurology) and in the clinical presentation of each disease (many entities in the central and right columns are repeated for various different syndromes). Therefore, while some sporadic syndromes may predominantly be caused by a specific disease, or mutations in specific genes may be more common in the aetiology of certain familial syndromes (the most frequent causes are marked with a hash sign [#]), it is clear that observing a given syndrome is not sufficient to establish the underlying disease or genetic mutation.

The fact that neurodegenerative diseases with potential to cause dementia are not mutually exclusive (Table 2) further complicates the task of establishing an aetiological diagnosis. For each patient, we must study biomarkers for a broad range of diseases potentially involved in the appearance of clinical signs. For example, detecting AD biomarkers in a patient with dementia does not rule out the possibility that the patient may simultaneously present another type of neurodegenerative dementia.

In accordance with the recommendations of the expert panel established by the NIA-AA, which in 2018 published its diagnostic criteria for AD,6 diagnosis of a degenerative “disease” may only be established if presence of the characteristic histopathological lesions can be confirmed in the brain (generally in an autopsy study) or if biomarkers unequivocally indicate the presence of the proteinopathy (or combination of proteinopathies, or occasionally another type of molecular pathology) needed to identify the disease. These markers have been studied more for AD than for other neurodegenerative diseases, and require CSF analysis or brain PET scans with very specific tracers. These tests are currently somewhat invasive (lumbar puncture) or costly, and are not included in routine diagnostic work-up for dementia. Furthermore, demonstrating the presence or absence of markers of AD in a patient does not confirm or rule out the presence of other potentially co-present neuropathological processes (Table 2).

It is important to recognise the value of the currently available markers (in our setting), such as marked atrophy (observed with CT or MRI studies) and hypometabolism (18F-FDG PET) in specific brain regions; while not highly specific, these markers assist in detecting neurodegenerative processes. In research contexts, they are valuable in establishing a specific phenotype in patients whose clinical manifestations are minimal or are characteristic of more than one disease, whereas in clinical settings they show (or help to rule out) the presence of a neurodegenerative process in some cases in which the clinical expression, progression, or comorbidities may give rise to doubt. In fact, structural neuroimaging, like comprehensive blood analysis (not including special markers), should be performed in all patients with cognitive alterations presenting progression or with no clear cause, as some potentially reversible causes may not be suspected after medical history-taking and clinical examination, and cannot be ruled out without these complementary tests. In other words, determination of disease-specific biomarkers may be performed in addition to structural neuroimaging, but should not replace these studies. The authors of a series of international recommendations on the use of CSF biomarkers of AD describe their value for the diagnosis of AD, especially during the prodromal phase of dementia or in patients with uncertain clinical diagnosis.168 In turn, they also acknowledge that CSF biomarkers have not been demonstrated to be superior to imaging biomarkers and that their use does not improve patient well-being or reduce overall expenditure related to these patients. Another recent article, reviewing the usefulness of AD biomarkers, highlighted their value for research into new drugs, noting the current lack of treatments that effectively modify the pathophysiological alterations caused by the disease.169

The treatments currently prescribed to treat cognitive or behavioural disorders secondary to neurodegeneration aim to relieve symptoms. Treatments intended to interfere in aetiological and pathogenic processes, in order to modify the course of neurodegenerative diseases, are currently being researched. The drugs recommended in the clinical setting alter the activity of the brain’s functional circuitry. Some increase or decrease the production or reuptake of specific neurotransmitters or activate or inhibit the corresponding receptors. Through a range of mechanisms, these changes increase or reduce activity in neuronal circuits with stimulatory or inhibitory action that, due to their topographical location in the brain, affect the control or modulation of specific functions (Table 3, left column). Of all the active ingredients listed in Table 3, only miglustat aims to increase survival times (in patients with Niemann-Pick disease type C), in addition to its symptomatic effect.165 Among treatments for degenerative dementia, cholinesterase inhibitors are specifically prescribed to patients with suspected AD or Lewy body dementia, as they partially counteract the acetylcholine deficiency in the brain; memantine is indicated for patients with suspected AD to reduce the abnormal accumulation of glutamate in affected brain regions (a paraphenomenon of the degenerative process). Nonetheless, they have not been shown to modify the course of the disease (e.g., they do not slow the progression from mild cognitive impairment to dementia170), and only improve the cognitive and behavioural symptoms of “Alzheimer syndrome”; more than half of patients do not present any significant improvement, either due to inefficacy or intolerance.150 It is unclear whether treatment inefficacy in these patients may be because the underlying disease differs from the working diagnosis based on the clinical syndrome (Table 1), or explained by the co-presence of another degenerative disease (Table 2) or the presence of a non-degenerative comorbidity. It has been suggested in some settings that trials of new drugs should take into account the possible co-presence of different degenerative diseases.137

In line with the main hypotheses, it seems reasonable to consider that in everyday clinical practice, searching for biomarkers to establish the specific neurodegenerative disease (nosological entity associated with a specific molecular pathophysiological process) is not relevant. Rather, we should identify the functional modules that are altered in the patient, which are responsible for the clinical manifestations, in order to identify the most effective of the available symptomatic treatments. According to the 2018 American Academy of Neurology (AAN) clinical practice guidelines,170 starting at the stage of mild cognitive impairment, we should aim to identify causes to which corrective measures can be applied (changing harmful medications, reducing sleep apnoea, treating depression or other comorbidities [vascular disease, cancer, infections, inflammation, metabolic/toxic disorders, etc.]).170 In terms of establishing a prognosis, we need to determine whether aetiology is neurodegenerative. If the cognitive disorder progresses and no non-degenerative cause is detected (or after effective treatment of potential causes), and especially in the presence of some non-specific paraclinical marker of neurodegeneration (e.g., excessive or rapidly progressive atrophy of specific brain areas on neuroimaging studies, or marked hypometabolism in specific regions, as observed in 18F-FDG PET scans), then the patient is considered to be developing a degenerative disease. In these cases, the AAN guidelines emphasise the benefit of informing patients and family members about the lack of approved drugs that may halt or slow the progression of dementia and the possibility of directing interested patients to centres conducting therapeutic trials. It should be noted that the current, theoretically disease-specific, drugs (cholinesterase inhibitors and memantine) were tested and approved at a time when the diagnosis of “Alzheimer disease” would correspond to what the most recent diagnostic criteria (the 2018 NIAA-AA criteria6) classify as “Alzheimer syndrome.” When presence of a degenerative dementia disorder is established, patients are also offered counselling regarding the progressive loss of functional and decision-making capacity. For example, patients should be advised of the progressive increase in the risks associated with driving or continuing to assume certain professional or family responsibilities, as well as the possibility of certain personal or financial decisions (such as drafting a will or advance directives, granting power of attorney to a trusted individual, etc.). The counselling offered may differ according to the patient’s specific clinical syndrome, not as a function of the histopathological substrate according to which the underlying disease is defined.

Based on the previous observations, it may be reasonable for national health systems to include referral services providing comprehensive testing for disease markers for all patients who agree to undergo this test, and to conduct thorough analysis of the pattern of neuropsychological, neurological, and systemic alterations, in order to further advance in the identification of phenotypes and in the search for highly efficacious treatments. We should determine the highest possible number of markers of mutations and proteinopathies, both in patients and in healthy controls, with a view to optimising the characterisation of phenotypes. This would enable us to reduce the risk of misdiagnosis, with the patient potentially presenting a different disease in a preclinical phase, or a combination of neurodegenerative diseases. In the absence of treatments with the capacity to substantially modify specific neuropathological molecular phenomena, delaying or significantly slowing the course of neurodegenerative diseases, it does not seem reasonable to dedicate time and resources to the routine performance of certain complementary tests (to search for specific markers of these diseases) in purely clinical settings.

We should also consider whether there is a need to update the terminology used in cognitive neurology. Some of the concepts of disease currently used in medicine correspond to specific, mutually exclusive clinicopathological constructs. We now know that each “syndrome” may have a range of genetic and neuropathological substrates, and each mutation and histopathological alteration can give rise to diverse clinical phenotypes; therefore, many of the clinicopathological combinations observed do not fit the accepted definitions of “diseases” described in the medical literature. There seems to be a need for change, with a separation of syndromes and specific molecular alterations (genetic and other types). For example, rather than being considered a clinicopathological concept, AD is now defined according to the presence of markers of a pathophysiological alteration6; this shift may also occur for other neurodegenerative dementias in the coming years. This development would lead to communication problems, with each disease known by a given name having different meanings according to the diagnostic criteria applied. In addition, there is a need for precise definitions of syndromes diagnosed prior to identification of the pathophysiological substrate, when this is known to be variable.

Before asserting that a symptomatic treatment is efficacious “for AD,” we must verify its efficacy in patients with Alzheimer syndrome, frontal lobe syndrome, posterior cortical atrophy, or logopenic primary progressive aphasia who also present biomarkers of AD. In the case of symptomatic treatments for progressive nonfluent aphasia, we must also verify their effectiveness in patients with markers of FTD, AD, CBD, PSP, Lewy body dementia, Creutzfeldt-Jakob disease, and multiple system atrophy (Table 3). Research into treatments targeting the proteinopathies involved in degenerative diseases (or other treatments intended to modify the course of the disease) should assess their level of efficacy in patients in presymptomatic, prodromal, and more advanced phases; in the latter group, we need to know whether or not these treatments are effective independently of the patient’s clinical syndrome.

In conclusion, medical advances will enable the detection of biomarkers of neurodegenerative dementias at any time from the presymptomatic stage; patients with specific biomarkers can develop a range of syndromes; the aetiology of each syndrome is heterogeneous; and syndromes should be assessed over a time interval from the prodromal stage to very advanced dementia. This results in a need for new concepts and a new terminology to avoid confusion, constantly adapting to the present situation. The use of these new concepts in clinical, research, and teaching activities should be helpful and enlightening, unlike the present situation.

Funding

No funding was received for this study.

Conflicts of interest

The author has no conflicts of interest to declare.

References
[1]
B. Dubois, H. Hampel, H.H. Feldman, P. Scheltens, P. Alsen, S. Andrieu, et al.
Preclinical Alzheimer’s disease: definition, natural history, and diagnostic criteria.
Alzheimers Dement., 12 (2016), pp. 292-323
[2]
B. Dubois, H.H. Feldman, C. Jacova, J.L. Cummings, S.T. Dekosky, P. Barberger-Gateau, et al.
Revising the definition of Alzheimer’s disease: a new lexicon.
Lancetr Neurol., 9 (2010), pp. 1118-1127
[3]
American Psychiatric Association.
Diagnostic and statistical manual of mental disorders.
5th edition, American Psychiatric Publishing, (2013),
[4]
I. McKeith, J.P. Taylor, A. Thomas, P. Donaghy, J. Kane.
Revisiting DLB diagnosis: a consideration of prodromal DLB and of the diagnostic overlap with Alzheimer disease.
J Geriatr Psychiatry Neurol., 29 (2016), pp. 249-253
[5]
B. Borroni, M. Cosseddu, A. Pilotto, E. Premi, S. Archetti, R. Gasparotti, et al.
Early stage of behavioral variant frontotemporal dementia: clinical and neuroimaging correlates.
Neurobiol Aging., 36 (2015), pp. 3108-3115
[6]
C.R. Jack Jr, D.A. Bennett, K. Blennow, M.C. Carrillo, B. Dunn, S.B. Haeberlein, et al.
NIA-AA Research Framework: Toward a biological definition of Alzheimer’s disease.
Alzheimers Dement., 14 (2018), pp. 535-562
[7]
B. Dubois, H.H. Feldman, C. Jacova, H. Hampel, J.L. Molinuevo, K. Blennow, et al.
Advancing research diagnostic criteria for Alzheimer’s disease: the IWG-2 criteria.
Lancet Neurol., 13 (2014), pp. 614-629
[8]
P. Körtvelyessy, H.J. Heinze, J. Prudio, D. Bittner.
CSF biomarkers of neurodegeneration in progressive non-fluent aphasia and other forms of frontotemporal dementia: clues for pathomechanisms?.
Front Neurol., 9 (2018), pp. 504
[9]
D. Galimberti, G.G. Fumagalli, C. Fenoglio, S.M.G. Cioffi, A. Arighi, M. Serpente, et al.
Progranulin plasma levels predict the presence of GRN mutations in asymptomatic subjects and do not correlate with brain atrophy: results from the GENFI study.
Neurobiol Aging., 62 (2018),
[10]
S. Morimoto, M. Takao, H. Hatsuta, Y. Nishina, T. Komiya, R. Sengoku, et al.
Homovanillic acid and 5-hydroxyindole acetic acid as biomarkers for dementia with Lewy bodies and coincident Alzheimer’s disease: an autopsy-confirmed study.
[11]
I. van Steenoven, N.K. Majbour, N.N. Vaikath, H.W. Berendse, W.M. van der Flier, W.D.J. van de Berg, et al.
α-synuclein species as potential cerebrospinal fluid biomarkers for dementia with Lewy bodies.
Mov Disord., 33 (2018), pp. 1724-1733
[12]
I. Illán-Gala, D. Alcolea, V. Montal, O. Dols-Icardo, L. Muñoz, N. de Luna, et al.
CSF sAPPβ, YKL—40, and NfL along the ALS-FTD spectrum.
Neurology., 91 (2018), pp. e1619-28
[13]
M. Schmitz, A. Villar-Piqué, F. Llorens, K. Gmitterová, P. Hermann, D. Varges, et al.
Cerebrospinal fluid total and phosphorylated α-synuclein in patients with Creutzfeldt-Jakob disease and synucleinopathy.
Mol Neurobiol., 56 (2019), pp. 3476-3483
[14]
A. Kertesz, P. McMonagle, M. Blair, W. Davidson, D.G. Munoz.
The evolution and pathology of frontotemporal dementia.
Brain., 128 (2005), pp. 1996-2005
[15]
R.W. Paterson, C.C. Torres-Chae, A.L. Kuo, T. Ando, E.A. Nguyen, K. Wong, et al.
Differential diagnosis of Jakob-Creutzfeldt disease.
Arch Neurol., 69 (2012), pp. 1578-1582
[16]
D.C. Perry, J.A. Brown, K.L. Possin, S. Datta, A. Trujillo, A. Radke, et al.
Clinicopathological correlations in behavioural variant frontotemporal dementia.
Brain., 140 (2017), pp. 3329-3345
[17]
M.J. Armstrong, I. Litvan, A.E. Lang, T.H. Bak, K.P. Bhatia, B. Borroni, et al.
Criteria for the diagnosis of corticobasal degeneration.
Neurology., 80 (2013), pp. 496-503
[18]
G.U. Hoglinger, G. Respondek, M. Stamelou, C. Kurz, K.A. Josephs, A.E. Lang, et al.
Clinical diagnosis of progressive supranuclear palsy: the movement disorder society criteria.
Mov Disord., 32 (2017), pp. 853-864
[19]
C. Echávarri, S. Burgmans, M.C. Caballero, F. García-Bragado, F.R.J. Verhey, H.B.M. Uylings.
Co-occurrence of different pathologies in dementia: implications for dementia diagnosis.
J Alzheimers Dis., 30 (2012), pp. 909-917
[20]
T.G. Beach, S.E. Monsell, L.E. Phillips, W. Kukull.
Accuracy of the clinical diagnosis of Alzheimer disease at National Institute on Aging Alzheimer’s Disease Centers, 2005-2010.
J Neuropathol Exp Neurol., 71 (2012), pp. 266-273
[21]
B.S. Appleby, T.D. Rincon-Beardsley, K.K. Appleby, B.J. Crain, M.T. Wallin.
Initial Diagnoses of patients ultimately diagnosed with prion disease.
J Alzheimers Dis., 42 (2014), pp. 833-839
[22]
J. Cooper-Knock, P.J. Shaw, J. Kirby.
The widening spectrum of C9ORF72-related disease; genotype/phenotype correlations and potential modifiers of clinical phenotype.
Acta Neuropathol., 127 (2014), pp. 333-345
[23]
A. Benussi, A. Padovani, B. Borroni.
Phenotypic heterogeneity of monogenic frontotemporal dementia.
Front Aging Neurosci., 7 (2015), pp. 171
[24]
S.J. Crutch, J.M. Schott, G.D. Rabinovici, M. Murray, J.S. Snowden, W.M. van der Flier, et al.
Consensus classification of posterior cortical atrophy.
Alzheimers Dement., 13 (2017), pp. 870-884
[25]
M.M. Carrasquillo, I. Barber, S.J. Lincoln, M.E. Murray, G.B. Camsari, Q. ul Ain, et al.
Evaluating pathogenic dementia variants in posterior cortical atrophy.
Neurobiol Aging., 37 (2016), pp. 38-44
[26]
L. Caixeta.
Huntington’s disease presenting as posterior cortical atrophy.
Arq Neuropsiquiatr., 69 (2011), pp. 407-408
[27]
C. Boutoleau-Bretonnière, A. Pallardy.
Down syndrome with posterior cortical atrophy.
[28]
M. Grossman.
Primary progressive aphasia: clinicopathological correlations.
Nat Rev Neurol., 6 (2010), pp. 88-97
[29]
K.A. Josephs, J.R. Duffy, E.A. Strand, M.M. Machulda, P. Vemuri, M.L. Senjem, et al.
Progranulin-associated PiB-negative logopenic primary progressive aphasia.
J Neurol., 261 (2014), pp. 604-614
[30]
C. Kobylecki, J.C. Thompson, M. Jones, S.J. Mills, S. Shaunak, J.W. Ironside, et al.
Sporadic Creutzfeldt-Jakob disease presenting as progressive nonfluent aphasia with speech apraxia.
Alzheimer Dis Assoc Disord., 27 (2013), pp. 384-386
[31]
N. Aoki, P.J. Boyer, C. Lund, W.L. Lin, S. Koga, O.A. Ross, et al.
Atypical multiple system atrophy is a new subtype of frontotemporal lobar degeneration: frontotemporal lobar degeneration associated with α-synuclein.
Acta Neuropathol., 130 (2015), pp. 93-105
[32]
K. Daida, K. Nishioka, Y. Li, S. Nakajima, R. Tanaka, N. Hattori.
CSF1R mutation p.G589R and the distribution pattern of brain calcification.
Intern Med., 56 (2017), pp. 2507-2512
[33]
F. Moreno, B. Indakoetxea, M. Barandiaran, A. Alzualde, A. Gabilondo, A. Estanga, et al.
“Frontotemporoparietal” dementia: clinical phenotype associated with the c.709-1G&A PGRN mutation.
Neurology., 73 (2009), pp. 1367-1374
[34]
D.G. Munoz, R. Ros, M. Fatas, F. Bermejo, J.G. de Yebenes.
Progressive nonfluent aphasia associated with a new mutation V363I in tau gene.
Am J Alzheimers Dis Other Demen., 22 (2007), pp. 294-299
[35]
J. Lagarde, L. Hamelin, V. Hahn, M.O. Habert, D. Seilhean, C. Duyckaerts, et al.
Progressive supranuclear palsy syndrome and semantic dementia in neuropathologically proven Lewy body disease: a report of two cases.
J Alzheimers Dis., 47 (2015), pp. 95-101
[36]
R. Landín-Romero, R. Tan, J.R. Hodges, F. Kumfor.
An update on semantic dementia: genetics, imaging, and pathology.
Alzheimers Res Ther., 8 (2016), pp. 52
[37]
S. Ishii, N. Weintraub, J.R. Mervis.
Apathy: a common psychiatric syndrome in the elderly.
J Am Med Dir Assoc., 10 (2009), pp. 381-393
[38]
F. Kumfor, A. Zhen, J.R. Hodges, O. Piguet, M. Irish.
Apathy in Alzheimer’s disease and frontotemporal dementia: distinct clinical profiles and neural correlates.
Cortex., 103 (2018), pp. 350-359
[39]
K. Dujardin, P. Sockeel, M. Delliaux, A. Destée, L. Defebvre.
Apathy may herald cognitive decline and dementia in Parkinson’s disease.
Mov Disord., 24 (2009), pp. 2391-2397
[40]
M. Ječmenica-Lukić, T. Pekmezović, I.N. Petrović, A. Tomić, M. Svetel, V.S. Kostić.
Use of the Neuropsychiatric Inventory to characterize the course of neuropsychiatric symptoms in progressive supranuclear palsy.
J Neuropsychiatry Clin Neurosci., 30 (2018), pp. 38-44
[41]
C. Ikeda, O. Yokota, S. Nagao, H. Ishizu, Y. Morisada, S. Terada, et al.
Corticobasal degeneration initially developing motor versus non-motor symptoms: a comparative clinicopathological study.
Psychogeriatrics., 14 (2014), pp. 152-164
[42]
S. Van Mossevelde, J. van der Zee, I. Gijselinck, S. Engelborghs, A. Sieben, T. van Langenhove, et al.
Clinical features of TBK1 carriers compared with C9orf72, GRN and non-mutation carriers in a Belgian cohort.
Brain., 139 (2016), pp. 452-467
[43]
M. Camacho, R.A. Barker, S.L. Mason.
Apathy in Huntington’s disease: a review of the current conceptualization.
J Alzheimers Dis Parkinsonism., 8 (2018), pp. 431
[44]
T. Mishima, S. Fujioka, H. Tomiyama, I. Yabe, R. Kurisaki, N. Fujii, et al.
Establishing diagnostic criteria for Perry syndrome.
J Neurol Neurosurg Psychiatry., 89 (2018), pp. 482-487
[45]
L.T. Takada, S.J. Sha.
Neuropsychiatric features of C9orf72-associated behavioral variant frontotemporal dementia and frontotemporal dementia with motor neuron disease.
Alzheimers Res Ther., 4 (2012), pp. 38
[46]
T. Miki, O. Yokota, S. Takenoshita, Y. Mori, K. Yamazaki, Y. Ozaki, et al.
Frontotemporal lobar degeneration due to P301L tau mutation showing apathy and severe frontal atrophy but lacking other behavioral changes: a case report and literatura review.
Neuropathology., 38 (2018), pp. 268-280
[47]
J. Ye, J. Han, Q. Shi, B.Y. Zhang, G.R. Wang, C. Tian, et al.
Human prion disease with a G114V mutation and epidemiological studies in a Chinese family: a case series.
J Med Case Rep., 2 (2008), pp. 331
[48]
E. Oldoni, G.G. Fumagalli, M. Serpente, C. Fenoglio, M. Scarioni, A. Arighi, et al.
PRNP P39L variant is a rare cause of frontotemporal dementia in Italian population.
J Alzheimers Dis., 50 (2016), pp. 353-357
[49]
A.C. Bruni, L. Bernardi, R. Colao, E. Rubino, N. Smirne, F. Frangipane, et al.
Worldwide distribution of PSEN1 Met146Leu mutation.
Neurology., 74 (2010), pp. 798-806
[50]
A. Bougea, C. Koros, M. Stamelou, A. Simitsi, N. Papagiannakis, R. Antonelou, et al.
Frontotemporal dementia as the presenting phenotype of p.A53T mutation carriers in the alpha-synuclein gene.
Parkinsonism Relat Disord., 35 (2017), pp. 82-87
[51]
M.F. Mendez, A. Joshi, K. Tassniyom, E. Teng, J.S. Shapira.
Clinicopathologic differences among patients with behavioral variant frontotemporal dementia.
Neurology., 80 (2013), pp. 561-568
[52]
G. Cipriani, M. Ulivi, S. Danti, C. Lucetti, A. Nuti.
Sexual disinhibition and dementia.
Psychogeriatrics., 16 (2016), pp. 145-153
[53]
R. Ossenkoppele, Y.A.L. Pijnenburg, D.C. Perry, B.I. Cohn-Sheehy, N.M.E. Scheltens, J.W. Vogel, et al.
The behavioural/dysexecutive variant of Alzheimer’s disease: clinical, neuroimaging and pathological features.
Brain., 138 (2015), pp. 2732-2749
[54]
K. Ishihara, S. Araki, N. Ihori, J. Shiota, M. Kawamura, M. Yoshida, et al.
Argyrophilic grain disease presenting with frontotemporal dementia: a neuropathological and pathological study of an autopsied case with presenile onset.
Neuropathology., 25 (2005), pp. 165-170
[55]
A. Eusebio, L. Koric, O. Félician, E. Guedj, M. Ceccaldi, J.P. Azulay.
Progressive supranuclear palsy and corticobasal degeneration: Diagnostic challenges and clinicopathological considerations.
Rev Neurol (Paris)., 172 (2016), pp. 488-502
[56]
A. Hassan, J.E. Parisi, K.A. Josephs.
Autopsy-proven progressive supranuclear palsy presenting as behavioral variant frontotemporal dementia.
Neurocase., 18 (2012), pp. 478-488
[57]
S.M. Darrow, M.E. Hirschtritt, L.K. Davis, C. Illmann, L. Osiecki, M. Grados, et al.
Identification of two heritable cross-disorder endophenotypes for Tourette syndrome.
Am J Psychiatry., 174 (2017), pp. 387-396
[58]
K. Duff, J.S. Paulsen, L.J. Beglinger, D.R. Langbehn, C. Wang, J.C. Stout, et al.
“Frontal” behaviors before the diagnosis of Huntington’s disease and its relationship to markers of disease progression: evidence of early lack of awareness.
J Neuropsychiatry Clin Neurosci., 22 (2010), pp. 196-207
[59]
I.O.C. Woollacott, J. Rohrer.
The clinical spectrum of sporadic and familial forms of frontotemporal dementia.
J Neurochem., 138(suppl 1) (2016), pp. 6-31
[60]
A. Gerstenecker, B. Mast, K. Duff, T.J. Ferman, I. Litvan, for the ENGENE-PSP study group.
Executive dysfunction is the primary cognitive impairment in progressive supranuclear palsy.
Arch Clin Neuropsychol., 28 (2013), pp. 104-113
[61]
R. Moretti, P. Torre, R.M. Antonello, T. Cattaruzza, G. Cazzato.
Cognitive impairment in the lateralized phenotype of corticobasal degeneration.
Dement Cogn Disord., 20 (2005), pp. 158-162
[62]
K. Abe, Y. Ikeda, T. Kurata, Y. Ohta, Y. Manabe, M. Okamoto, et al.
Cognitive and affective impairments of a novel SCA/MND crossroad mutation Asidan.
Eur J Neurol., 19 (2012), pp. 1070-1078
[63]
J.R. Burrell, G.M. Halliday, J.J. Kril, L.M. Ittner, J. Götz, M.C. Kiernan, et al.
The frontotemporal dementia-motor neuron disease continuum.
Lancet., 388 (2016), pp. 919-931
[64]
Z. Kobayashi, K. Tsuchiya, T. Arai, O. Yokota, M. Yoshida, Y. Shimomura, et al.
Clinicopathological characteristics of FTLD-TDP showing corticospinal tract degeneration but lacking lower motor neuron loss.
J Neurol Sci., 298 (2010), pp. 70-77
[65]
R. Rusina, K. Sheardová, I. Rektorová, P. Ridzon, P. Kulist’ák, R. Matej.
Amyotrophic lateral sclerosis and Alzheimer’s disease. Clinical and neuropathological considerations in two cases.
Eur J Neurol., 14 (2007), pp. 815-818
[66]
H. Yaguchi, A. Takeuchi, K. Horiuchi, I. Takahashi, S. Shirai, S. Akimoto, et al.
Amyotrophic lateral sclerosis with frontotemporal dementia (ALS-FTD) syndrome as a phenotype of Creutzfeldt-Jakob disease (CJD)? A case report.
J Neurol Sci., 372 (2017), pp. 444-446
[67]
S. Lattante, S. Millecamps, G. Stevanin, S. Rivaud-Péchoux, C. Moigneu, A. Camuzar, et al.
Contribution of ATXN2 intermediary polyQ expansions in a spectrum of neurodegenerative disorders.
Neurology., 83 (2014), pp. 990-995
[68]
J. Yan, H.X. Deng, N. Siddique, F. Fecto, W. Chen, Y. Yang, et al.
Frameshift and novel mutations in FUS in familial amyotrophic lateral sclerosis and ALS/dementia.
Neurology., 75 (2010), pp. 807-814
[69]
M. Tada, E.A. Coon, A.P. Osmand, P.A. Kirby, W. Martin, M. Wieler, et al.
Coexistence of Huntington’s disease and amyotrophic lateral sclerosis: a clinicopathologic study.
Acta Neuropathol., 124 (2012), pp. 749-760
[70]
J.S. Katz, H.D. Katzberg, S.C. Wooley, S.L. Marklund, P.M. Andersen.
Combined fulminant frontotemporal dementia and amyotrophic lateral sclerosis associated with an I113T SOD1 mutation.
Amyotroph Lateral Scler., 13 (2012), pp. 567-569
[71]
M. Nakamura, K.F. Bieniek, W.L. Lin, N.R. Graff-Radford, M.E. Murray, M. Castanedes-Casey, et al.
A truncating SOD1 mutation, p.Gly141X, is associated with clinical and pathologic heterogeneity, including frontotemporal lobar degeneration.
Acta Neuropathol., 130 (2015), pp. 145-157
[72]
I. Faber, L.M.T. Branco, M.C. França Jr.
Cognitive dysfunction in hereditary spastic paraplegias and other motor neuron disorders.
Dement Neuropsychol., 10 (2016), pp. 276-279
[73]
K.A. Jellinger.
Cerebral correlates of psychotic syndromes in neurodegenerative diseases.
J Cell Mol Med., 16 (2012), pp. 995-1012
[74]
M.C. Tartaglia, D.Y. Johnson, J.N. Thai, T. Cattaruzza, K. Wong, P. Garcia, et al.
Clinical overlap between Jakob-Creutzfeldt disease and Lewy body disease.
Can J Neurol Sci., 39 (2012), pp. 304-310
[75]
S. Ducharme, S. Bajestan, B.C. Dickerson, V. Voon.
Psychiatric presentations of C9orf72 mutation: what are the diagnostic implications for clinicians?.
J Neuropsychiatry Clin Neurosci., 29 (2017), pp. 195-205
[76]
J.R. Ostergaard.
Juvenile neuronal ceroid lipofuscinosis (Batten disease): current insights.
Degener Neurol Neuromuscul Dis., 6 (2016), pp. 73-83
[77]
L. Tang, Y. Wang, Y. Chen, L. Chen, S. Zheng, M. Bao, et al.
The association between 5HT2A T102C and behavioral and psychological symptoms of dementia in Alzheimer’s disease: a meta-analysis.
Biomed Res Int., 2017 (2017),
[78]
C.J. Hendriksz, M. Anheim, P. Bauer, O. Bonnot, A. Chakrapani, J.C. Corvol, et al.
The hidden Niemann-Pick type C patient: clinical niches for a rare inherited metabolic disease.
Curr Med Res Opin., 33 (2017), pp. 877-890
[79]
M. Canevelli, P. Piscopo, G. Talarico, N. Vanacore, A. Blasimme, A. Crestini, et al.
Familial Alzheimer’s disease sustained by presenilin 2 mutations: systematic review of literature and genotype-phenotype correlation.
Neurosci Biobehav Rev., 42 (2014), pp. 170-179
[80]
H.K. Park, S.J. Chung.
New perspective on Parkinsonism in frontotemporal lobar degeneration.
J Mov Disord., 6 (2013), pp. 1-8
[81]
E. Gatto, I. Demey, A. Sanguinetti, V. Paris, J.L. Etcheverry, G. Rojas, et al.
Cognition in a multiple system atrophy series of cases from Argentina.
Arq Neuropsiquiatr., 72 (2014), pp. 773-776
[82]
J.C. Steele.
Parkinsonism-dementia complex of Guam.
Mov Disord., 20 (suppl 12) (2005), pp. S99-S107
[83]
C.A. Mangone.
Heterogeneidad clínica de la enfermedad de Alzheimer. Diferentes perfiles clínicos pueden predecir el intervalo de progresión.
Rev Neurol., 38 (2004), pp. 675-681
[84]
I.N. Petrovic, A. Martin-Bastida, L. Massey, H. Ling, S.S. O’Sullivan, D.R. Williams, et al.
MM2 subtype of sporadic Creutzfeldt-Jakob disease may underlie the clinical presentation of progressive supranuclear palsy.
J Neurol., 260 (2013), pp. 1031-1036
[85]
D. Caparros-Lefebvre, N. Sergeant, A. Lees, A. Camuzat, S. Daniel, A. Lannuzel, et al.
Guadaloupean parkinsonism: a cluster of progressive supranuclear palsy-like tauopathy.
Brain., 125 (2002), pp. 801-811
[86]
C. Klein, S.A. Schneider, A.E. Lang.
Hereditary Parkinsonism: Parkinson disease look-alikes. An algorithm for clinicians to “PARK” genes and beyond.
Mov Disord., 24 (2009), pp. 2042-2058
[87]
N.A. Ferreira Frota, P. Caramelli, E. Reis Barbosa.
Cognitive impairment in Wilson’s disease.
Dement Neuropsychol., 3 (2009), pp. 16-21
[88]
T. Konno, O.A. Ross, H.A.G. Teive, J. Sławek, D.W. Dickson, Z.K. Wszolek.
DCTN1-related neurodegeneration: Perry syndrome and beyond.
Parkinsonism Relat Disord., 41 (2017), pp. 14-24
[89]
E. Berry-Kravis, L. Abrams, S.M. Coffey, D.A. Hall, C. Greco, L.W. Gane, et al.
Fragile X-associated tremor/ataxia syndrome: clinical features, genetics, and testing guidelines.
Mov Disord., 22 (2007), pp. 2018-2030
[90]
M.J. Farrer, L.N. Williams, A.A. Algom, J. Kachergus, M.M. Hulihan, O.A. Ross, et al.
Glucosidase-beta variations and Lewy body disorders.
Parkinsonism Relat Disord., 15 (2009), pp. 414-416
[91]
A. Ciammola, J. Sassone, B. Poletti, N. Mencacci, R. Benti, V. Silani.
Atypical parkinsonism revealing a late onset, rigid and akinetic form of Huntington’s disease.
Case Rep Neurol Med., 2011 (2011), pp. 696953
[92]
L.F.R. Vasconcellos, P.J.O.M. Macêdo, J.B. Franck, V. Tumas, W. Marques Júnior, M. Spitz.
Huntington’s disease like 2 presenting with isolated Parkinsonism.
J Neurol Sci., 373 (2017), pp. 105-106
[93]
M.G. Heckman, A.I. Soto-Ortolaza, M.Y. Sanchez Contreras, M.E. Murray, O. Pedraza, N.N. Diehl, et al.
LRRK2 variation and dementia with Lewy bodies.
Parkinsonism Relat Disord., 31 (2016), pp. 98-103
[94]
L.T. Takada, M.O. Kim, R.W. Cleveland, K. Wong, S.A. Forner, I.I. Gala, et al.
Genetic prion disease: Experience of a rapidly progressive dementia Center in the United States and a review of the literature.
Am J Med Genet Part B Neuropsychiatr Genet., 174 (2017), pp. 36-69
[95]
S.E. Lee, G.D. Rabinovici, M.C. Mayo, S.M. Wilson, W.W. Seeley, S.J. DeArmond, et al.
Clinicopathological correlations in corticobasal degeneration.
Ann Neurol., 70 (2011), pp. 327-340
[96]
H. Ling, S.S. O’Sullivan, J.L. Holton, T. Revesz, L.A. Massey, D.R. Williams, et al.
Does corticobasal degeneration exist? A clinicopathological re-evaluation.
Brain., 133 (2010), pp. 2045-2057
[97]
D.A. González, J.R. Soble.
Corticobasal syndrome due to sporadic Creutzfeldt-Jakob disease: a review and neuropsychological case report.
Clin Neuropsychol., 31 (2017), pp. 676-689
[98]
C. Gasca-Salas, M. Masellis, E. Khoo, B.B. Shah, D. Fisman, A.E. Lang, et al.
Characterization of movement disorder phenomenology in genetically proven, familial frontotemporal Lobar degeneration: a systematic review and meta-analysis.
[99]
B. Lam, A. Khan, J. Keith, E. Rogaeva, J. Bilbao, P. St George-Hyslop, et al.
Characterizing familial corticobasal syndrome due to Alzheimer’s disease pathology and PSNE1 mutations.
Alzheimers Dement., 13 (2017), pp. 520-530
[100]
D.C. Paviour, A.J. Lees, K.A. Josephs, T. Ozawa, M. Ganguly, C. Strand, et al.
Frontotemporal lobar degeneration with ubiquitin-only-immunoreactive neuronal changes: broadening the clinical picture to include progressive supranuclear palsy.
Brain., 127 (2014), pp. 2441-2451
[101]
C. Wilke, J. Baets, J.L. De Bleecker, T. Deconinck, S. Biskup, S.N. Hayer, et al.
Beyond ALS and FTD: the phenotypic spectrum of TBK1 mutations includes PSP-like and cerebellar phenotypes.
Neurobiol Aging., 62 (2018),
[102]
G.R. Rodrigues, R.H. Walker, B. Bader, A. Danek, A. Brice, C. Cazeneuve, et al.
Clinical and genetic analysis of 29 Brazilian patients with Huntington’s disease-like phenotype.
Arq Neuropsiquiatr., 69 (2011), pp. 419-423
[103]
S.A. Schneider, T. Bird.
Huntington’s disease, Huntington’s disease look-alikes, and benign hereditary chorea.
What’s new? Mov Disord Clin Pract., 3 (2016), pp. 342-354
[104]
Veneziano L, Frontali M. DRPLA. En: Adam MP, Ardinger HH, Pagon RA, Wallace SE, Bean LJH, Stephens K, et al., editores. Gene Reviews. Seattle, WA: University of Washington, Seattle; 1993–2018.
[105]
N. Baine FKm Peerbhai, A. Krause.
A study of Huntington disease-like syndromes in black South African patients reveals a single SCA2 mutation and a unique distribution of normal alleles across five repeat loci.
J Neurol Sci., 390 (2018), pp. 200-204
[106]
L.H.P. Vroegindeweij, J.G. Langendonk, M. Langeveld, M. Hoogendoorn, A.J.A. Kievit, D. Di Raimondo, et al.
New insights in the neurological phenotype of aceruloplasminemia in Caucasian patients.
Parkinsonism Relat Disord., 36 (2017), pp. 33-40
[107]
N. Kumar, P. Rizek, M. Jog.
Neuroferritinopathy: pathophysiology, presentation, differential diagnosis and management.
Tremor Other Hyperkinet Mov (N Y)., 6 (2016), pp. 355
[108]
M.A. Salih, M.Z. Seidahmed, H.Y. El Khashab, M.H.A. Hamad, T.M. Bosley, S. Burn, et al.
Mutation in GM2A leads to a progressive chorea-dementia syndrome.
Tremor Other Hyperkinet Mov (N Y)., 5 (2015), pp. 306
[109]
E. Groppo, A. Armaroli, R. Selvatici, F. Gualandi, M. Sensi.
Huntington’s disease-like presentation in spinocerebellar ataxia type 12.
Mov Disord., 31 (2016), pp. 1248-1249
[110]
P. Santens, T. Van Damme, W. Steyaert, A. Willaert, B. Sablonnière, A. De Paepe, et al.
RNF216 mutations as a novel cause of autosomal recessive Huntington-like disorder.
Neurology., 84 (2015), pp. 1760-1766
[111]
G.G. Kovacs, J.R. Murrell, S. Horvath, L. Haraszti, K. Majtenyi, M.J. Molnar, et al.
TARDBP variation associated with frontotemporal dementia, supranuclear gaze palsy, and chorea.
Mov Disord., 24 (2009), pp. 1843-1847
[112]
V. Redaelli, E. Salsano, L. Colleoni, P. Corbetta, G. Tringali, A. Del Sole, et al.
Frontotemporal dementia and chorea associated with a compound heterozygous TREM2 mutation.
J Alzheimers Dis., 63 (2008), pp. 195-201
[113]
H. Garcia-Moreno, H. Fassihi, R.P.E. Sarkany, J. Phukan, T. Warner, A.R. Lehmann, et al.
Xeroderma pigmentosum is a definite cause of Huntington’s disease-like syndrome.
Ann Clin Transl Neurol., 5 (2018), pp. 102-108
[114]
L.B. Barcelos, F. Saad, C. Giacominelli, R.A. Saba, P.M. de Carvalho Aguiar, S.M.A. Silva, et al.
Neuropsychological and clinical heterogeneity of cognitive impairment in patients with multiple system atrophy.
Clin Neurol Neurosurg., 164 (2018), pp. 121-126
[115]
S.A. Cooper, K.L. Murray, C.A. Heath, C.A. Will, R.S.G. Knight.
Sporadic Creutzfeldt-Jakob disease with cerebellar ataxia at onset in the UK.
J Neurol Neurosurg Psychiatry., 77 (2006), pp. 1273-1275
[116]
D. Bargiela, P. Shanmugarajah, C. Lo, E.L. Blakely, R.W. Taylor, R. Horvath, et al.
Mitochondrial pathology in progressive cerebellar ataxia.
Cerebellum Ataxias., 2 (2015), pp. 16
[117]
S. Koga, K.A. Josephs, K. Ogaki, C. Labbé, R.J. Uitti, N. Graff-Radford, et al.
Cerebellar ataxia in progressive supranuclear palsy: an autopsy study of PSP-C.
Mov Disord., 31 (2016), pp. 653-662
[118]
J.A. Morgan-Hughes, M.G. Sweeney, J.M. Cooper, S.R. Hammans, M. Brockington, A.H. Schapira, et al.
Mitochondrial DNA (mtDNA) diseases: correlation of genotype to phenotype.
Biochem Biophys Acta., 1271 (1995), pp. 135-140
[119]
T.L. Monte, F.S. Pereira, E.D.R. Reckziegel, M.C. Augustin, L.D. Locks-Coelho, A.S.P. Santos, et al.
Neurological phenotypes in spinocerebellar ataxia type 2: Role of mitochondrial polymorphism A10398G and other risk factors.
Parkinsonism Relat Disord., 42 (2017), pp. 54-60
[120]
A. Jara-Prado, A. Ochoa, M.E. Alonso, G.A. Lima Villeda, F. Fernández-Valverde, L. Ruano-Calderón, et al.
Late onset Lafora disease and novel EPM2A mutations: breaking paradigms.
Epilepsy Res., 108 (2014), pp. 1501-1510
[121]
S. Singh, I. Sethi, S. Francheschetti, C. Riggio, G. Avanzini, K. Yamakawa, et al.
Novel NHLRC1 mutations and genotype-phenotype correlations in patients with Lafora’s progressive myoclonic epilepsy.
J Med Genet., 43 (2006), pp. e48
[122]
U. Rüb, F. Hoche, E.R. Brunt, H. Heinsen, K. Seidel, D. Del Turco, et al.
Degeneration of the cerebellum in Huntington’s disease (HD): Possible relevance for the clinical picture and potential gateway to pathological mechanisms of the disease process.
Brain Pathol., 23 (2013), pp. 165-177
[123]
Y. Taniwaki, H. Hara, K. Doh-ura, I. Murakami, H. Tashiro, T. Yamasaki, et al.
Familial Creutzfeldt-Jakob disease with D178N-129M mutation of PRNP presenting as cerebellar ataxia without insomnia.
J Neurol Neurosurg Psychiatry., 68 (2000), pp. 388
[124]
H. Fujigasaki, J.J. Martin, P.P. De Deyn, A. Camuzat, D. Deffond, G. Stevanin, et al.
CAG repeat expansion in the TATA box-binding protein gene causes autosomal dominant cerebellar ataxia.
Brain., 124 (2001), pp. 1939-1947
[125]
P. Thaisetthawatkul, B.F. Boeve, E.E. Benarroch, P. Sandroni, T.J. Ferman, R. Petersen, et al.
Autonomic dysfunction in dementia with Lewy bodies.
Neurology., 62 (2004), pp. 1804-1809
[126]
K. Stubendorff, D. Aarsland, L. Minthon, E. Londos.
The impact of autonomic dysfunction on survival in patients with dementia with Lewy bodies and Parkinson’s disease with dementia.
[127]
W. Struhal, A. Javor, C. Brunner, T. Benesch, V. Schmidt, M.R. Vosko, et al.
The phoenix from the ashes: cardiovascular autonomic dysfunction in behavioral variant of frontotemporal dementia.
J Alzheimers Dis., 42 (2014), pp. 1041-1046
[128]
E. Nomura, T. Harada, K. Kurokawa, Y. Murata, F. Ishizaki, Y. Mimori, et al.
Creutzfeldt-Jakob disease associated with autonomic nervous system dysfunction in the early stage.
Internal Med., 36 (1997), pp. 492-496
[129]
R.K. Khurana, J.H. Garcia.
Autonomic dysfunction in subacute spongiform encephalopathy.
[130]
J. Andrich, T. Schmitz, C. Saft, T. Postert, P. Kraus, J.T. Epplen, et al.
Autonomic nervous system function in Huntington’s disease.
J Neurol Neurosurg Psychiatry., 72 (2002), pp. 726-731
[131]
S. Mead, S. Gandhi, J. Beck, D. Caine, D. Gallujipali, C. Carswell, et al.
A novel prion disease associated with diarrhea and autonomic neuropathy.
N Engl J Med., 369 (2013), pp. 1904-1914
[132]
Y. Hayashi, Y. Iwasaki, A. Takekoshi, N. Yoshikura, T. Asano, M. Mimuro, et al.
An autopsy-verified case of FTLD-TDP type A with upper motor neuron-predominant motor neuron disease mimicking MM2-thalamic-type sporadic Creutzfeldt-Jakob disease.
[133]
S. Eigenbrod, P. Frick, A. Giese, G. Schelzke, I. Zerr, H.A. Kretzschmar.
Comprehensive neuropathologic analysis of genetic prion disease associated with the E196K mutation in PRNP reveals phenotypic heterogeneity.
J Neuropathol Exp Neurol., 70 (2011), pp. 192-200
[134]
G.G. Kovacs, I. Alafuzoff, S. Al-Sarraj, T. Arzberger, N. Bogdanovic, S. Capellari, et al.
Mixed brain pathologies in dementia: the BrainNet Europe Consortium Experience.
Dement Geriatr Cogn Disord., 26 (2008), pp. 343-350
[135]
K. Uryu, H. Nakashima-Yasuda, M.S. Forman, L.K. Kwong, C.M. Clark, M. Grossman, et al.
Concomitant TAR-DNA-binding protein 43 pathology is present in Alzheimer disease and corticobasal degeneration but not in other tauopathies.
J Neuropathol Exp Neurol., 67 (2008), pp. 555-564
[136]
C.F. Tan, Y.S. Piao, A. Kakita, M. Yamada, H. Takano, M. Tanaka, et al.
Frontotemporal dementia with co-occurrence of astrocytic plaques and tufted astrocytes, and severe degeneration of the cerebral white matter: a variant of corticobasal degeneration?.
Acta Neuropathol., 109 (2005), pp. 329-338
[137]
G.D. Rabinovici, M.C. Carrillo, M. Forman, S. DeSanti, D.S. Miller, N. Kozauer, et al.
Multiple comorbid neuropathologies in the setting of Alzheimer’s disease neuropathology and implications for drug development.
Alzheimers Dement (N Y)., 3 (2017), pp. 83-91
[138]
T.B. Ahn.
Clinicopathological correlates of Lewy body disease: fundamental issues.
J Mov Disord., 3 (2010), pp. 11-14
[139]
H. Uchikado, A. DelleDonne, R. Uitti, D.W. Dickson.
Coexistence of PSP and MSA: a case report and review of the literature.
Acta Neuropathol., 111 (2006), pp. 186-192
[140]
M.Y. Davis, C.D. Keene, S. Jayadev, T. Bird.
The co-occurrence of Alzheimer’s disease and Huntington’s disease: a neuropathological study of 15 elderly Huntington’s disease subjects.
J Huntingtons Dis., 3 (2014), pp. 209-217
[141]
C. Schwab, T. Arai, M. Hasegawa, S. Yu, P.I. Mcgeer.
Colocalization of transactivation-responsive DNA-binding protein 43 and huntingtin in inclusions of Huntington disease.
J Neuropathol Exp Neurol., 67 (2008), pp. 1159-1165
[142]
D. Caparros-Lefebvre.
Association of corticobasal degeneration and Huntington’s disease: can tau aggregates protect huntingtin toxicity?.
Mov Disord., 24 (2009), pp. 1089-1090
[143]
I. Fernández-Vega, J. Ruiz-Ojeda, R.A. Juste, M. Geijo, J.J. Zarranz, J.L. Sánchez Menoyo, et al.
Coexistence of mixed phenotype Creutzfeldt-Jakob disease, Lewy body disease and argyrophilic grain disease plus histological features of possible Alzheimer’s disease: a multi-protein disorder in an autopsy case.
Neuropathology., 35 (2015), pp. 56-63
[144]
M.G. Vita, D. Tiple, A. Bizzarro, A. Ladogana, E. Colaizzo, S. Capellari, et al.
Patient with rapidly evolving neurological disease with neuropathological lesions of Creutzfeldt-Jakob disease, Lewy body dementia, chronic subcortical vascular encephalopathy and meningothelial meningioma.
Neuropathology, 37 (2017), pp. 110-115
[145]
V. Chelban, A. Manole, L. Pihlstrøm, L. Schottlaender, S. Efthymiou, E. OConnor, et al.
Analysis of the prion protein gene in multiple system atrophy.
Neurobiol Aging., 49 (2017),
[146]
O. Yokota, T. Miki, C. Ikeda, S. Nagan, S. Takenoshita, H. Ishizu, et al.
Neuropathological comorbidity associated with argyrophilic grain disease.
Neuropathology., 38 (2018), pp. 82-97
[147]
M.J. Gil, M.S. Manzano, M.L. Cuadrado, C. Fernández, E. Góméz, C. Matesanz, et al.
Argyrophilic grain pathology in frontotemporal lobar degeneration: Demgraphic, clinical, neuropathological, and genetic features.
J Alzheimers Dis., 63 (2018), pp. 1109-1117
[148]
K. Wakabayashi, I. Kawachi, Y. Toyoshima, H. Takahashi.
Occurrence of argyrophilic grains in multiple system atrophy: histopathological examination of 26 autopsy cases.
No To Shinkei., 51 (1999), pp. 433-437
[149]
A.S. Berghoff, A. Trummert, U. Unterberger, T. Ströbel, T. Hortobágyi, G.G. Kovacs.
Atypical sporadic CJD-MM phenotype with white matter kuru plaques associated with intranuclear inclusion body and argyrophilic grain disease.
Neuropathology., 35 (2015), pp. 336-342
[150]
L.M. Waite.
Treatment for Alzheimer’s disease: has anything changed?.
Aust Prescr., 38 (2015), pp. 60-63
[151]
R. Lamb, J.D. Rohrer, A.J. Lees, H.R. Morris.
Progressive supranuclear palsy and corticobasal degeneration: pathophysiology and treatment options.
Curr Treat Options Neurol., 18 (2016), pp. 42
[152]
M. Dean, V.W. Sung.
Review of deutetrabenazine: a novel treatment for chorea associated with Huntington’s disease.
Drug Des Devel Ther., 12 (2018), pp. 313-319
[153]
R. Reilman.
Pharmacological treatment of chorea in Huntington’s disease. Good clinical practice versus evidence-based guideline.
Mov Disord., 28 (2013), pp. 1030-1033
[154]
M. Manix, P. Kalakoti, M. Henry, J. Thakur, R. Menger, B. Guthikonda, et al.
Creutzfeldt-Jakob disease: updated diagnostic criteria, treatment algorithm, and the utility of brain biopsy.
Neurosurg Focus., 39 (2015), pp. E2
[155]
R. Rea, A. Carotenuto, A.M. Fasanaro, E. Traini, F. Amenta.
Apathy in Alzheimer’s disease: any effective treatment?.
ScientificWorldJournal., 2014 (2014),
[156]
E. Savaskan, H. Mueller, R. Hoerr, A. von Gunten, S. Gauthier.
Treatment effects of Ginkgo biloba extract EGb 761® on the spectrum of behavioral and psychological symptoms of dementia: meta-analysis of randomized controlled trials.
Int Psychogeriatr., 30 (2018), pp. 285-293
[157]
R. De Giorgi, H. Series.
Treatment of inappropiate sexual behavior in dementia.
Curr Treat Options Neurol., 18 (2016), pp. 41
[158]
Reus VI, Fochtmann LJ, Eyler E, Hilty DM, Horvitz-Lennon M, Jibson MD, et al. The American Psychiatric Association Practice Guideline on the use of antipsychotics to treat agitation or psychosis in patients with dementia. 2016 (Acceso al texto completo: https://psychiatryonline.org/doi/pdf/10.1176/appi.books.9780890426807.
[159]
J. Cummings, T.J. Lai, S. Hemrungrojn, E. Mohandas, S.Y. Kim, G. Nair, et al.
Role of donepezil in the management of neuropsychiatric symptoms in Alzheimer’s disease and dementia with Lewy bodies.
CNS Neurosci Ther., 22 (2016), pp. 159-166
[160]
S.I. Finkel.
Effects of rivastigmine on behavioral and psychological symptoms of dementia in Alzheimer’s disease.
Clin Ther., 26 (2004), pp. 980-990
[161]
J.H. Friedman.
Pharmacological interventions for psychosis in Parkinson’s disease patients.
Expert Opin Pharmacother., 19 (2018), pp. 499-505
[162]
N.R. McFarland, C.W. Hess.
Recognizing atypical Parkinsonisms: “Red flags” and therapeutic approaches.
Semin Neurol., 37 (2017), pp. 215-227
[163]
M.L.E. Bianchi, G. Riboldazzi, M. Mauri, M. Versino.
Efficacy of safinamide on non-motor symptoms in a cohort of patients affected by idiopathic Parkinson’s disease.
Neurol Sci., 40 (2019), pp. 275-279
[164]
H.A. Hanagasi, H. Gurvit, P. Unsalan, H. Horozoglu, N. Tuncer, A. Feyzioglu, et al.
The effects of rasagiline on cognitive déficits in Parkinson’s disease patients without dementia: a randomized, double-blind, placebo-controlled, multicenter study.
Mov Disord., 26 (2011), pp. 1851-1858
[165]
M. Pineda, J.E. Wraith, E. Mengel, F. Sedel, W.L. Hwu, M. Rohrbach, et al.
Miglustat in patients with Niemann-Pick disease type C (NP-C): A multicenter observational retrospective cohort study.
Mol Genet Metab., 98 (2009), pp. 243-249
[166]
T.A. Zesiewicz, G. Wilmot, S.H. Kuo, S. Perlman, P.E. Greenstein, S.H. Ying, et al.
Comprehensive systematic review summary: treatment of cerebellar motor dysfunction and ataxia.
Neurology., 90 (2018), pp. 464-471
[167]
J.A. Palma, H. Kaufmann.
Treatment of autonomic dysfunction in Parkinson disease and other synucleinopathies.
Mov Disord., 33 (2018), pp. 372-390
[168]
R.C. Petersen, O. Lopez, M.J. Armstrong, T.S.D. Getchius, M. Ganguli, D. Gloss, et al.
Practice guideline update summary: mild cognitive impairment. Report of the Guideline development, dissemination, and implementation subcommittee of the American Academy of Neurology.
Neurology., 90 (2018), pp. 126-135
[169]
A.H. Simonsen, S.K. Herukka, N. Andreasen, I. Baldeiras, M. Bjerke, K. Blennow, et al.
Recommendations for CSF AD biomarkers in the diagnostic evaluation of dementia.
Alzheimers Dement., 13 (2017), pp. 274-284
[170]
J.L. Molinuevo, S. Ayton, R. Batrla, M.M. Bednar, T. Bittner, J. Cummings, et al.
Current state of Alzheimer’s fluid bioarkers.
Acta Neuropathol., 136 (2018), pp. 821-853

Please cite this article as: Robles Bayón A. Demencias degenerativas: ¿un dilema de síndromes o de enfermedades? Neurología. 2022;37:480–491.

Copyright © 2019. Sociedad Española de Neurología
Descargar PDF
Opciones de artículo
es en pt

¿Es usted profesional sanitario apto para prescribir o dispensar medicamentos?

Are you a health professional able to prescribe or dispense drugs?

Você é um profissional de saúde habilitado a prescrever ou dispensar medicamentos