Abstract
The current study examined the prevalence and subtypes of Mild Cognitive Impairment (MCI) in an Australian sample of people with Parkinson’s Disease (PD). Seventy participants with PD completed neuropsychological assessments of their cognitive performance, using MDS Task Force Level II diagnostic criteria for PD-MCI. A cut-off score of less than one standard deviation (SD) below normative data determined impaired performance on a neuropsychological test. Of 70 participants, 45 (64%) met Level II diagnostic criteria for PD-MCI. Among those with PD-MCI, 42 (93%) were identified as having multiple domain impairment (28 as amnestic multiple domain and 14 as nonamnestic multiple domain). Single domain impairment was less frequent (2 amnestic/1 nonamnestic). Significant differences were found between the PD-MCI and Normal Cognition groups, across all cognitive domains. Multiple domain cognitive impairment was more frequent than single domain impairment in an Australian sample of people with PD. However, PD-MCI is heterogeneous and current prevalence and subtyping statistics may be an artifact of variable application methods of the criteria (e.g., cut off scores and number of tests). Future longitudinal studies refining the criteria will assist with subtyping the progression of PD-MCI, while identifying individuals who may benefit from pharmacological and nonpharmacological interventions.
Similar content being viewed by others
Introduction
Parkinson’s disease (PD) is now understood as a multifaceted neurodegenerative disorder with heterogeneous motor and non-motor symptoms1. Approximately 30% of people with PD demonstrate cognitive impairment and up to 50% of those progress to PD-Dementia after more than 10 years of disease duration2,3. Cognitive impairments in PD comprise four subtypes; amnestic single, amnestic multiple, nonamnestic single and nonamnestic multiple. The four subtypes reflect deficits across five cognitive domains, including: memory, attention/working memory, language, visuospatial and executive functions4,5.
Several biological and epidemiological risk factors are associated with cognitive deficits in PD, with some studies reporting cognitive impairment is present even at time of diagnosis6,7. To standardize assessment, the Movement Disorder Society (MDS) Task Force developed new diagnostic criteria for PD-Mild Cognitive Impairment (PD-MCI)8. Preceding the criteria, most studies adopted the method proposed by Petersen et al.9 which specifies a decline in memory. PD-MCI is, however, heterogeneous and many people demonstrate impairments across the spectrum of cognitive domains10. Recent studies adopting the new MDS diagnostic criteria report variable results11,12. These studies also applied varying diagnostic cut off scores and weighting of tests per cognitive domain, which may influence the reported prevalence of cognitive impairment in PD.
The high prevalence and significant impact of cognitive impairment on quality of life for people with PD13, indicate that any standardised criteria developed for international use needs to be validated and examined across multiple populations of PD. To date, no study has applied the MDS criteria for PD-MCI to an Australian sample. This study provided a novel application of the MDS Task Force PD-MCI Level II diagnostic criteria to an Australian sample of people with PD. This study also examined PD-MCI frequency differentials at varying diagnostic cut off scores to explore subtype classifications and advance our understanding of cognitive impairments in PD.
Results
Seventy participants completed neuropsychological assessments, with 64.3% (N = 45) classified as ‘PD-MCI’ and the remaining participants classified as ‘PD-Normal Cognition (PD-NC)’ (N = 25). For demographic variables, there were no statistically significant group differences. There were significant differences between groups on all cognitive outcomes (excluding SOC). Table 1 provides demographic and neuropsychological test results for participants in the PD-MCI and PD-NC groups.
Internal reliability varied between adequate (0.40 to 0.50) to excellent (>0.90) and was computed for 10 outcomes: UPDRS-II (α = 0.80) TISC (KR-20 = 0.47), MMSE (KR-20 = 0.54); PD-CRS (α = 0.84), LNS (KR-20 = 0.92), Stroop (Colour-Word) Test (KR-20 = 0.96), BNT (KR-20 = 0.54), Similarities (α = 0.68), JLO (KR-20 = 0.90) and HVLT (KR-20 = 0.78). Low internal reliability scores were identified for the TISC, MMSE, BNT and Similarities outcomes. However, due to the diversity of cognitive constructs, using cut off scores for Cronbach’s α may subtract from the scale’s primary purpose in the context of the research14. All outcomes were therefore reported in this study and the current authors suggest interpreting the outcomes with low reliability with caution.
PD-MCI subtypes according to MDS criteria
Among participants who met the MDS Task Force criteria for PD-MCI (N = 45), 93.4% demonstrated multiple domain impairment and only 6.6% showing single domain impairment (4.4% memory and 2.2% visuospatial; Fig. 1).
Cognitive deficits were heterogeneous among participants with multiple domain PD-MCI. In total, 62.2% (N = 28) of participants were classified as amnestic multiple domain with 11 different patterns of impairments identified (Table 2). Moreover, 31.2% (N = 14) of participants were classified as nonamnestic multiple domain and nine different patterns of impairments identified. When comparing individual cognitive domains for all PD-MCI (Fig. 2), executive function was impaired in 62.2% (N = 28) of participants, attention/working memory in 66.7% (N = 30), memory in 66.7% (N = 30), visuospatial in 31.2% (N = 14) and language in 44.4% (N = 20).
Post-hoc analyses
Following the high frequency of PD-MCI (64.3%) when using a 1 SD cut-off below normative data, post-hoc analyses were conducted to examine whether using a 2 SD cut off would result in frequency differentials (Table 3). The frequency of PD-MCI decreased from 64.3% to 28.6% (N = 20). Among participants with PD-MCI, however, the frequency of subtype classifications remained relatively stable. Overall, 90% (N = 18) of participants with PD-MCI demonstrated multiple domain impairment and only 10% showed single domain impairment (N = 1 for memory and N = 1 for attention/working memory). Amnestic multiple domain remained most frequent (N = 10, 50%) with five different patterns of impairments, followed by nonamnestic multiple domain (N = 8, 40%) with five different patterns of impairments. Both amnestic single and nonamnestic single domains showed the least frequency of impairment (N = 1, 5% individually). Following the 2 SD cut off, executive function was impaired in 75% (N = 15) of participants, attention/working memory in 45% (N = 9), memory in 50% (N = 10), visuospatial in 45% (N = 9) and language in 10% (N = 2).
Discussion
This study was the first application of MDS Task Force criteria for PD-MCI in an Australian sample. Using the criteria at the 1 SD cut off score, 64.3% of participants were diagnosed as PD-MCI. Among those with PD-MCI, 93.4% presented with multiple domain impairments (i.e., deficit test results in more than one cognitive domain) and 6.6% with single domain impairment. Attention/working memory, executive function and memory impairments were the most frequently impaired cognitive domains. Language and visuospatial domains demonstrated less impairment. These results support those of Cholerton et al.12 and Goldman et al.10 who found that 63–67% of their samples had PD-MCI and that 91.5–95% of those participants had multiple domain impairments. Marras et al.11 reported that 93% of their sample with PD-MCI had multiple domain impairment, despite an overall PD-MCI prevalence of only 33%. Recent application of the new criteria also revealed that attention/working memory, executive function and memory domains were most frequently impaired in PD-MCI10,12. These results, however, conflict with prevalence statistics preceding the new diagnostic criteria. Studies predating the criteria indicate a significantly lower prevalence (19% to 38%) of PD-MCI and some studies identified single domain impairment as more common than multiple domain impairment2,15,16.
Several reasons have been proposed for the varying frequency of PD-MCI across studies. Compared to previous methods, the new MDS criteria is less stringent when diagnosing multiple domain (i.e., impairment on one test per domain) compared to single domain (i.e., impairment on two tests in one domain) subtypes, which will invariably identify more people with multiple domain impairment10. Introducing a more conservative criterion for the multiple domain subtype (e.g., impairment on two tests per domain) will likely reduce the biased frequency of multiple domain impairment. In addition, several verbal memory, visuospatial and attention tests have demonstrated appropriate diagnostic specificity for PD-MCI17 and administering these tests in future research may provide a more accurate estimate of the multiple domain subtype.
In studies preceding the MDS Task Force criteria, variable use of SD cut offs increased the heterogeneity of the frequency of PD-MCI and this issue is yet to be resolved18. The new diagnostic criteria suggest 1 to 2 SD cut offs for establishing cognitive impairment with normative data8, but Liepelt-Scarfone et al.18 have shown that PD-MCI diagnoses vary between 56.4% (using <1 SD) and 9.9% (using <2 SDs). Having said this, a recent study identified 2 SDs as the most sensitive and specific cut off for diagnosing PD-MCI using the new criteria10. Using a 2 SD cut off in the current study reduced the frequency of PD-MCI from 64.3% (using 1 SD) to 28.6%, but the frequency of subtype classifications remained relatively stable (i.e., multiple domain impairment remained more frequent than single domain). Language impairment, however, reduced from 44.4% (N = 20) using a 1 SD cut off to 10% (N = 2) using a 2 SD cut off. Compared to other cognitive domains, this result suggests that language impairment may be less frequent in PD-MCI. Impairment across all cognitive domains was prevalent among 11.1% (N = 5) of participants using a 1 SD cut off, but this reduced to nil participants using a 2 SD cut off. This finding supports the current characterisation of PD-MCI, with most individuals demonstrating impairment within multiple, but not all, cognitive domains (e.g., executive function and memory)12. Using a 1 SD cut off may, however, be too liberal and not sufficiently specific for identification of PD-MCI subtypes10. Overall, the reduction in the frequency of PD-MCI is similar to previous prevalence estimates that adopted more conservative 1.5 SD11 and 2 SD19 cut off scores. The MDS Task Force, however, suggest using a 1 SD cut off to detect impaired cognition in higher functioning individuals, who may have noticed a decline in their cognitive functioning but do not meet the stricter criteria of 1.5 to 2 SDs8.
The inconsistent use of and weighting of, cognitive tests per domain may also bias diagnosis and subtyping of PD-MCI. The MDS Task Force recommends two tests per cognitive domain to ensure consistency across studies and the reliable external validity of results8. Recent studies adopting the criteria have used between 3 and 7 tests/subtests per domain, which is more than recommended10,12. Inclusion of more tests in any one domain increases the risk of a Type I error and may falsely inflate the prevalence of PD-MCI20. A recent study showed that when using MDS Task Force recommendations (10 or more neuropsychological tests), approximately 13% of people with PD and normal cognition will demonstrate impaired performance on two or more tests20. The recent increase in prevalence of PD-MCI may, therefore, be associated with the inclusion of more neuropsychological tests in the assessment of PD-MCI, which may lead to more false-positive diagnoses. As previously noted, a more conservative use of tests (e.g., impairment on two tests per domain) when diagnosing multiple domain PD-MCI and applying a more stringent cut off score (e.g., <2 SDs below normative data) may reduce the risk of Type 1 errors in research and clinical settings. While acknowledging these issues, further refinement of the PD-MCI criteria will determine the ideal classification method, appropriate cut off scores and the optimal number and selection of tests for diagnosis.
Although recent studies have used varying cut off scores, subtype classifications in this study are consistent with recent findings21. Most participants were identified as multiple domain PD-MCI, which comprised 20 different combinations of impaired domains. Cholerton et al.12 also reported 19 combinations of impaired domains within their multiple domain subtype. Although this may be an artefact of the MDS diagnostic criteria (i.e., 1 SD cut off has shown low specificity10), this heterogeneous distribution across multiple domains is a hallmark feature of PD-MCI4. Research has identified diverse pathophysiological changes and characteristics that may underlie the heterogeneous presentation of PD-MCI3.
Most participants in this study demonstrated memory and executive function impairments, but there were considerable concomitant deficits across domains. The variability of PD-MCI has been associated with protein/neurotransmitter abnormalities and genetic characteristics3. Catecholaminergic changes involving frontostriatal dopaminergic deficits are associated with executive function impairment and deficiency of acetylcholine is associated with impaired posterior cortical function of memory, language and visuospatial abilities3,7,22. Alpha-synuclein infiltration (as Lewy based pathology) of the limbic system and neocortex has also been associated with amnestic cognitive impairment in PD23. The range of neurotransmitter changes demonstrate the complex pathology of different cognitive impairments in PD.
Kehagia et al.4 suggest that genetic characteristics may account for patterns of decline in PD-MCI. The ‘dual syndrome hypothesis’ proposes two distinct genetic syndromes (executive and posterior cortical) that affect executive function and memory/visuospatial abilities in PD and often present early in the disease4. A recent study tested this hypothesis and found associations between a genetic variation (rs4680 polymorphism of the COMT gene) which modulated executive function and two genetic variations (APOE allelic and MAPT haplotype) which independently modulated posterior cortical functions of memory and visuospatial abilities, respectively24. These studies provide initial evidence that frontal or posterior cortical cognitive deficits are associated with specific genetic and neurotransmitter abnormalities. Neuroimaging was beyond the scope of the present study, but the heterogeneity of multiple domain PD-MCI in this study does not support the ‘dual syndrome hypothesis’ (e.g., participants demonstrated many patterns of impairment across all cognitive domains). Having said this, research shows considerable overlap between the executive and posterior cortical syndromes and further clinical trials combining neuroimaging and neuropsychological testing are required25.
Participants with PD-MCI performed significantly worse (compared to participants with PD-NC) across all cognitive domains, including global cognition. Similar results were reported by Goldman et al.10 and Marras et al.11 In both of these studies, PD-MCI groups performed significantly worse on cognitive outcomes compared to the unimpaired groups. Group allocation was determined by cognitive performance and as such, significant differences between group scores were to be expected. In this study, however, a conflicting result was reported for executive function. Compared to the Controlled Oral Word Association Test (COWAT), scores on the Stockings of Cambridge (SOC) test demonstrated no difference between groups, indicating comparative performance between those with and without PD-MCI. A recent systematic review and meta-analysis highlighted the multifaceted nature of executive function and the challenges faced when researching this cognitive domain in PD26. Executive function is often referred to as an ‘umbrella’ concept used to describe many subcomponent abilities, including purposive action (execution), volition, planning, effective performance, attentional control, set-shifting, inhibition and managing behaviour27,28,29. Consequently, individual neuropsychological tests are often unable to capture and measure the full spectrum of executive function. Predominantly, the SOC test involves rule learning, planning and execution, whereas the COWAT requires set shifting (between trials) and attentional control. In addition, studies have shown separation of ‘hot’ and ‘cold’ executive function abilities. ‘Cold’ cognitive tasks are described as neutrally affective and involve cognitive flexibility, while ‘hot’ cognitive tasks are influenced by emotion and motivated reasoning30. Due to the complexity of executive function and the inherent specificity of neuropsychological tests, people with PD may show impaired performance on individual tests which do not represent impairment across the entire domain26. Therefore it is important that the exact tests used for diagnosis are standardised.
When examining demographic variables, there were no significant differences between groups. Participants in the PD-MCI group were slightly older and had slightly less years of education, but these differences were not significant. Recent studies have reported no educational difference between people with and without cognitive impairments in PD10,11,12,15. Some studies, however, reported older age and less years of education associated with cognitive decline in PD7,31,32. These conflicting results suggest future longitudinal research is required to determine the long-term relationship between years of education and cognitive impairment in PD. Due to participant burden, motor symptom severity was not directly measured in the current study. Levodopa equivalent dose and disease duration were measured and the findings indicate no group differences, which suggests severity of motor symptoms were similar across groups33.
Limitations and recommendations for future research
The main limitation of this study was the cross sectional design, which involved only baseline cognitive assessments. Collecting data at one time-point limits examination of which neuropsychological tests are most appropriate and of which domains of impairment are most predictive of cognitive decline in PD. This sample had relatively high educational levels and low years of disease duration. These characteristics are comparable to cohorts from recent studies11,12, but may limit the generalisability of the results to the wider PD population. Lastly, there was low internal consistency for some cognitive measures, which must be noted when interpreting the results.
Future studies should adopt longitudinal designs to validate and provide suggestions for the refinement of the MDS Task Force diagnostic criteria for PD-MCI. Future studies need to determine which neuropsychological tests are most reliable and valid over time, the most appropriate number of tests per cognitive domain (to control inflation of Type I errors) and the most sensitive and specific cut off scores for diagnostic purposes. The MDS criteria also needs to be applied to different age groups with varying degrees of cognitive impairment, disease severity and cognitive reserve (educational/occupational attainment). Recent and ongoing longitudinal studies are examining biomarker, epidemiological and neuropsychological risk factors associated with cognitive decline in PD7,20,24,32,34. However, future studies need to adopt an interdisciplinary approach by integrating clinical neuroscience, neuroimaging and neurobiology with the MDS criteria, to provide a greater understanding of PD-MCI. Moreover, studies must be transparent in their reporting of the normative datasets used to establish diagnoses of PD-MCI. As explained by Strauss et al.35, selection of appropriate normative data is equally as important as choosing a reliable and valid neuropsychological test. Using a normative dataset that is not a demographical match to a participant’s characteristics is problematic, given that norm-referenced scores are directly related to clinical and research consequences such as prevalence rates, diagnosis and pharmacological/nonpharmacological interventions36.
The etiology and profile of PD-MCI is heterogeneous, with some people reverting back to normal cognition and many others progressing to PD-Dementia6. There is no current therapeutic intervention to halt or delay cognitive decline in PD37. Clinical trials are examining the potential of pharmacological treatments, but two recent studies found no improvements in cognition38,39. The limited empirical support of pharmacological treatment for PD-MCI has led to an increase in research assessing nonpharmacological interventions for cognition in PD40. Specifically, cognitive training and non-invasive brain stimulation have improved cognition in PD41,42. However, most studies included participants without cognitive impairment and significant methodological heterogeneity limits the reliability of results37. Despite current limitations, nonpharmacological interventions may be a therapeutic alternative for people with PD-MCI who are already burdened by dopaminergic medications.
When applying the MDS Task Force diagnostic criteria for PD-MCI, this study found 64% of participants (using a 1 SD cut off) were cognitively impaired (i.e., demonstrated PD-MCI) and this figure reduced to 28% with PD-MCI when using a 2 SD cut off. Despite the change in frequency of impairments, most participants with PD-MCI were classified as multiple domain subtype which is consistent with recent findings21. Although further validation and refinement of the diagnostic criteria is required, the significant prevalence and heterogeneous nature of PD-MCI is well documented. Future studies need to integrate the MDS criteria with longitudinal designs of interdisciplinary research, to identify subtypes of PD-MCI and individuals most likely to develop PD-Dementia. Subtyping PD-MCI may also allow researchers to determine which subtypes will benefit from pharmacological and nonpharmacological interventions that may delay or halt progression of cognitive decline.
Method
This study used a cross-sectional design to measure cognition in people with PD, using the MDS diagnostic criteria for PD-MCI8. Neuropsychological assessments were completed at Curtin University’s Neuroscience Laboratory between March and September, 2015.
Participants
Participants were adults with PD living in Western Australia. The following inclusion criteria were used: (1) diagnosed with idiopathic PD by a neurologist or geriatrician in accordance with the United Kingdom Parkinson’s Disease Society Brain Bank Clinical Diagnostic Criteria, (2) a stable response to antiparkinsonian medication for a minimum period of 2 months and (3) cognitive deficits that do not interfere with functional independence. Exclusion criterion was presence of PD-Dementia.
Neuropsychological assessment
Neuropsychological assessments were conducted in two phases. Participants were first screened over the telephone for the presence of dementia (using the TISC-30)43. Participants then completed an extensive neuropsychological assessment at Curtin University. In accordance with the MDS Task Force Level II diagnostic criteria for PD-MCI, two measures were selected to assess each of the five cognitive domains impacted in PD-MCI8. The following measures have been recommended by the MDS Task Force for use in PD and were used to assess functioning. Executive function was assessed using the Stockings of Cambridge (SOC) subtest from the Cambridge Neuropsychological Test of Automated Batteries (CANTABTM) and the phonemic verbal fluency subtest of the Controlled Oral Word Association Task (COWAT)44. Attention and working memory was assessed using the Letter-Number Sequencing (LNS) subtest from the Wechsler Adult Intelligence Scale-IV (WAIS-IV)45 and the Stroop (Colour-Word) Test46. Memory was assessed using the Hopkins Verbal Learning Test-Revised (HVLT-R)47 immediate recall subtest and the Paragraph Recall subtest of the Rivermead Behavioural Memory Test (RMBT)48. Visuospatial abilities were assessed using the Judgement of Line Orientation (JLO) test49 and the Hooper Visual Organisation Test (HVOT)50. Language was assessed using the Boston Naming Test-Short Form (BNT-Short Form)51 and the Similarities subtest from the WAIS-IV battery45.
Global cognition was assessed using the Parkinson’s Disease – Cognitive Rating Scale (PD-CRS)52 and the Mini Mental State Examination (MMSE)53. Premorbid intelligence and activities of daily living were assessed by the Australian version of the National Adult Reading Test (AUSNART)54 and Unified Parkinson’s Disease Rating Scale (section II)55, respectively. A UPDRS-II55 summary index score greater than 3 was used to exclude participants with impaired activities of daily living (i.e., cognitive deficits that significantly impact functional independence). Demographic information including age, disease duration (years) and current daily levodopa dopaminergic medication were also collected56. This study was approved by Curtin University’s Research Ethics Committee prior to contact with participants (approval number: HR 189/2014). All research methods were carried out in accordance with ethics committee guidelines and all participants provided informed consent prior to completing neuropsychological assessments. All assessments were conducted during participants’ ‘ON’ stage of medication use.
Cognitive diagnosis
Following each assessment, results were scored and interpreted using standardised normative data from healthy older adults (Supplementary Table 1). PD-MCI was diagnosed as less than one standard deviation (SD) below normative scores on two or more neuropsychological tests8. The MDS Task Force suggest the use of 1 to 2 SD cut offs below normative scores. Raw scores were used to determine impairment on all tests, excluding the LNS and Similarities tests. The LNS and Similarities raw scores were converted into scaled scores (as per WAIS-IV instructions) and then compared to normative data45. In accordance with the MDS criteria8, a cut off of 1 SD was used in this study to accommodate the likelihood that the community based cohort may include higher functioning adults living independently, who may not report cognitive deficits but demonstrate impairment during formal neuropsychological assessment. Also, subjective report of cognitive decline has shown low accuracy in PD57. Therefore, individuals in this study were not required to meet the criteria of reporting cognitive decline. For participants who met the Level II criteria, the following PD-MCI subtype classifications were applied: (1) amnestic single domain (impairment on two memory tests); (2) nonamnestic single domain (impairment on two or more non-memory tests); (3) amnestic multiple domain (impairment on two or more tests, including memory) and (4) nonamnestic multiple domain (impairment on two or more tests, not including memory). Participants who did not meet the Level II criteria were classified as having ‘Normal Cognition’.
Statistical analysis
Statistical Package for the Social Sciences (SPSS) 22.0 was used for statistical analyses. Descriptive statistics for demographic data and neuropsychological test scores were computed and frequency estimates were calculated to describe the prevalence of cognitive impairment and PD-MCI subtypes. Independent samples t tests and a Mann-Whitney U test (for a non-parametric outcome) were used to examine if there were statistically significant differences between the ‘PD-MCI’ and ‘Normal Cognition’ (i.e., those without PD-MCI) groups on demographic variables and neuropsychological outcomes58,59. An alpha level of 0.05 was applied to demographic variables and a Bonferroni-adjusted alpha level was applied to cognitive outcomes, where there were multiple comparisons per domain (i.e., p < 0.025). Where possible, the internal reliability of outcomes were computed using two methods: (1) the Kuder-Richardson 20 (KR-20) and (2) Cronbach’s α60,61. Both methods produce estimates of internal consistency, though the KR-20 assesses tests with dichotomous response items (e.g., ‘correct’ or ‘incorrect’) and Cronbach’s α examines tests with any response scale62. For cognitive tests, internal consistency of ≥0.70 is acceptable for research purposes59.
Additional Information
How to cite this article: Lawrence, B. J. et al. Prevalence and Subtypes of Mild Cognitive Impairment in Parkinson’s Disease. Sci. Rep. 6, 33929; doi: 10.1038/srep33929 (2016).
References
Williams-Gray, C. H. et al. The CamPaIGN study of Parkinson’s disease: 10-year outlook in an incident population-based cohort. J Neurol Neurosurg Psychiatry. 84, 1258–1264 (2013).
Litvan, I. et al. MDS task force on mild cognitive impairment in Parkinson’s disease: critical review of PD‐MCI. Mov Disord. 26, 1814–1824 (2011).
Cosgrove, J., Alty, J. E. & Jamieson, S. Cognitive impairment in Parkinson’s disease. Postgrad Med J. 91, 212–220 (2015).
Kehagia, A. A., Barker, R. A. & Robbins, T. W. Neuropsychological and clinical heterogeneity of cognitive impairment and dementia in patients with Parkinson’s disease. Lancet Neurol. 9, 1200–1213 (2010).
Muslimovic, D., Schmand, B., Speelman, J. D. & De Haan, R. J. Course of cognitive decline in Parkinson’s disease: a meta-analysis. JINS. 13, 920–932 (2007).
Pedersen, K. F., Larsen, J. P., Tysnes, O. & Alves, G. Prognosis of mild cognitive impairment in early Parkinson disease: the Norwegian ParkWest study. JAMA. 70, 580–586 (2013).
Williams-Gray, C. H. et al. The distinct cognitive syndromes of Parkinson’s disease: 5 year follow-up of the CamPaIGN cohort. Brain. 132, 2958–2969 (2009).
Litvan, I. et al. Diagnostic criteria for mild cognitive impairment in Parkinson’s disease: Movement Disorder Society Task Force guidelines. Mov Disord. 27, 349–356 (2012).
Petersen, R. C. Mild cognitive impairment. N Engl J Med. 364, 2227–2234 (2011).
Goldman, J. G. et al. Defining optimal cutoff scores for cognitive impairment using Movement Disorder Society Task Force criteria for mild cognitive impairment in Parkinson’s disease. Mov Disord. 28, 1972–1979 (2013).
Marras, C. et al. Measuring mild cognitive impairment in patients with Parkinson’s disease. Mov Disord. 28, 626–633 (2013).
Cholerton, B. A. et al. Evaluation of mild cognitive impairment subtypes in Parkinson’s disease. Mov Disord. 29, 756–764 (2014).
Hely, M. A., Reid, W. G. J., Adena, M. A., Halliday, G. M. & Morris, J. G. L. The Sydney multicenter study of Parkinson’s disease: the inevitability of dementia at 20 years. Mov Disord, 23, 837–844 (2008).
Kline, P. The Handbook of Psychological Testing, 2nd ed. (Routledge, 1999).
Caviness, J. N. et al. Defining mild cognitive impairment in Parkinson’s disease. Mov Disord. 22, 1272–1277 (2007).
Goldman, J. G., Weis, H., Stebbins, G., Bernard, B. & Goetz, C. G. Clinical differences among mild cognitive impairment subtypes in Parkinson’s disease. Mov Disord. 27, 1129–1136 (2012).
Biundo, R. et al. Diagnostic and screening power of neuropsychological testing in detecting mild cognitive impairment in Parkinson’s disease. J Neural Transm. 120, 627–633 (2013).
Liepelt-Scarfone, I. et al. Influence of different cut-off values on the diagnosis of mild cognitive impairment in Parkinson’s disease. Parkinsons Dis. 2011, 1–7 (2011).
Muslimović, D., Post, B., Speelman, J. D. & Schmand, B. Cognitive profile of patients with newly diagnosed Parkinson disease. Neurology. 65, 1239–1245 (2005).
Loftus, A. M. et al. Retrospective assessment of Movement Disorder Society Criteria for mild cognitive impairment in Parkinson’s disease. JINS. 21, 137–145 (2015).
Geurtsen, G. J. et al. Parkinson’s disease mild cognitive impairment: application and validation of the criteria. J Parkinsons Dis. 4, 131–137 (2014).
Svenningsson, P., Westman, E., Ballard, C. & Aarsland, D. Cognitive impairment in patients with Parkinson’s disease: diagnosis, biomarkers and treatment. Lancet Neurol. 11, 697–707 (2012).
Compta, Y. et al. Lewy-and Alzheimer-type pathologies in Parkinson’s disease dementia: which is more important? Brain. 134, 1493–1505 (2011).
Nombela, C. et al. Genetic impact on cognition and brain function in newly diagnosed Parkinson’s disease: ICICLE-PD study. Brain. 10, 2743–2758 (2014).
Kehagia, A. A., Barker, R. A. & Robbins, T. W. Cognitive impairment in Parkinson’s disease: the dual syndrome hypothesis. Neurodegener Dis. 11, 79–92 (2013).
Kudlicka, A., Clare, L. & Hindle, J. V. Executive functions in Parkinson’s disease: systematic review and meta‐analysis. Mov Disord. 26, 2305–2315 (2011).
Lezak, M., Howieson, D. & Loring, D. Neuropsychological Assessment, 5th ed. (Oxford University Press, 2012).
Stuss, D. T. & Alexander, M. P. Is there a dysexecutive syndrome? Philos Trans R Soc Lond B Biol Sci. 362, 901–915 (2007).
Smith, E. E. & Jonides, J. Storage and executive processes in the frontal lobes. Science. 283, 1657–1661 (1999).
Zelazo, P. D. & Carlson, S. M. Hot and cool executive function in childhood and adolescence: development and plasticity. Child Dev Per. 6, 354–360 (2012).
Elgh, E. et al. Cognitive function in early Parkinson’s disease: a population-based study. Eur J Neurol. 16, 1278–1284 (2009).
Hu, M. et al. Predictors of cognitive impairment in an early stage Parkinson’s disease cohort. Mov Disord. 29, 351–359 (2014).
Fahn, S. et al. Levodopa and the progression of Parkinson’s disease. N Engl J Med. 351, 2498–2508 (2004).
Dujardin, K. et al. Cognitive disorders in Parkinson’s disease: confirmation of a spectrum of severity. Parkinsonism Relat Disord. 21, 1299–1305 (2015).
Strauss, E., Sherman, E. & Spreen, O. A Compendium of Neuropsychological Tests: Administration, Norms and Commentary. (Oxford University Press, 2006).
Mitrushina, M., Boone, K. B., Razani, J. & Delia, L. F. Handbook of Normative Data for Neuropsychological Assessment. (Oxford University Press, 2005).
Goldman, J. G. & Weintraub, D. Advances in the treatment of cognitive impairment in Parkinson’s disease. Mov Disord. 30, 1471–1489 (2015).
Mamikonyan, E., Xie, S. X., Melvin, E. & Weintraub, D. Rivastigmine for mild cognitive impairment in Parkinson disease: a placebo-controlled study. Mov Disord. 30, 912–918 (2015).
Frakey, L. & Friedman, J. A-31 the effects of rasagiline on cognition in mild to moderate stage Parkinson’s disease, a double-blind placebo controlled study. Arch Clin Neuropsychol. 29, 514–514 (2014).
Hindle, J. V., Petrelli, A., Clare, L. & Kalbe, E. Nonpharmacological enhancement of cognitive function in Parkinson’s disease: a systematic review. Mov Disord. 28, 1034–1049 (2013).
Pal, E., Nagy, F., Aschermann, Z., Balazs, E. & Kovacs, N. The impact of left prefrontal repetitive transcranial magnetic stimulation on depression in Parkinson’s disease: a randomized, double-blind, placebo-controlled study. Mov Disord. 25, 2311–2317 (2010).
París, A. P. et al. Blind randomized controlled study of the efficacy of cognitive training in Parkinson’s disease. Mov Disord. 26, 1251–1258 (2011).
Brandt, J., Spencer, M. & Folstein, M. The telephone interview for cognitive status. Cog Behav Neurol. 1, 111–118 (1988).
Benton, A. L. Differential behavioral effects in frontal lobe disease. Neuropsychologia. 6, 53–60 (1968).
Wechsler, D. Wechsler Adult Intelligence Scale– Fourth Edition (WAIS–IV). (Pearson, 2008).
Golden, C. J. & Freshwater, S. Stroop Colour and Word test: Revised Examiner’s Manual. (Stoelting Co, 2002).
Brandt, J. & Benedict, R. H. Hopkins Verbal Learning Test-Revised: Professional Manual. (Psychological Assessment Resources, 2001).
Wilson, B., Cockburn, J., Baddeley, A. & Hiorns, R. The development and validation of a test battery for detecting and monitoring everyday memory problems. J Clin Exp Neuropsychol. 11, 855–870 (1989).
Benton, A. L., Hamsher, K. D. & Sivan, A. B. Multilingual Aphasia Examination: Manual of Instructions, 3rd ed. (AJA, 1994).
Hooper, H. Hooper Visual Organisation Test: Manual. (Western Psychological Services, 1983).
Kaplan, E., Goodglass, H. & Weintraub, S. Boston Naming Test, 2nd ed. (Pro-Ed, 2001).
Pagonabarraga, J. et al. Parkinson’s disease-cognitive rating scale: a new cognitive scale specific for Parkinson’s disease. Mov Disord. 23, 998–1005 (2008).
Folstein, M. F., Folstein, S. E. & McHugh, P. R. “Mini-mental state”: a practical method for grading the cognitive state of patients for the clinician. J Psychiatr Res. 12, 189–198 (1975).
Hennessy, M. & Mackenzie, B. AUSNART: the development of an Australian version of the NART. The 18th Annual Brain Impairment Conference, Hobart, Australia (1995).
Goetz, C. G. et al. Movement Disorder Society-sponsored revision of the Unified Parkinson’s Disease Rating Scale (MDS-UPDRS): scale presentation and clinimetric testing results. Mov Disord. 23, 2129–2170 (2008).
Tomlinson, C. L. et al. Systematic review of levodopa dose equivalency reporting in Parkinson’s disease. Mov Disord. 25, 2649–2653 (2010).
Copeland, J. N., Lieberman, A., Oravivattanakul, S. & Troster, A. I. Accuracy of patient and care partner identification of cognitive impairments in Parkinson’s disease–mild cognitive impairment. Mov Disord, 31, 693–698 (2016).
Howell, D. Statistical Methods for Psychology, 8th ed. (Cengage Learning, 2013).
Field, A. Discovering statistics using IBM SPSS statistics, 4th ed. (Sage, 2013).
Cronbach, L. J. Coefficient alpha and the internal structure of tests. Psychometrika. 16, 297–334 (1951).
Anastasi, A. & Urbina, S. Psychological Testing, 7th ed. (Prentice Hall, 1997).
Cortina, J. M. What is coefficient alpha? An examination of theory and applications. J Appl Psychol. 78, 98–104 (1993).
Author information
Authors and Affiliations
Contributions
B.J.L., N.G. and A.M.L designed the study. B.J.L recruited the participants, conducted neuropsychological assessments, analyzed the data and wrote the initial manuscript. All authors discussed the results and edited the final manuscript.
Ethics declarations
Competing interests
The authors declare no competing financial interests.
Electronic supplementary material
Rights and permissions
This work is licensed under a Creative Commons Attribution 4.0 International License. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder to reproduce the material. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/
About this article
Cite this article
Lawrence, B., Gasson, N. & Loftus, A. Prevalence and Subtypes of Mild Cognitive Impairment in Parkinson’s Disease. Sci Rep 6, 33929 (2016). https://doi.org/10.1038/srep33929
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/srep33929
- Springer Nature Limited
This article is cited by
-
Memantine for the patients with mild cognitive impairment in Parkinson’s disease: a pharmacological fMRI study
BMC Neurology (2022)
-
Meta-Analysis of Cognition in Parkinson’s Disease Mild Cognitive Impairment and Dementia Progression
Neuropsychology Review (2022)
-
TOMM40 ‘523’ poly-T repeat length is a determinant of longitudinal cognitive decline in Parkinson’s disease
npj Parkinson's Disease (2021)
-
Donepezil for mild cognitive impairment in Parkinson’s disease
Scientific Reports (2021)
-
Evaluating Mild Cognitive Dysfunction in Patients with Parkinson’s Disease in Clinical Practice in Taiwan
Scientific Reports (2020)