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Mild cognitive impairment: How can you be sure?

Mr. R, age 67, presents with what he describes as uncharacteristic “memory loss” that is affecting his ability to run his accounting business. He and his wife relate that he was doing well until approximately 9 months ago, when he started showing difficulties remembering clients’ names and addresses.

His wife became extremely concerned when he made serious accounting errors in a 1-month period that resulted in the loss of a longtime customer. Mr. R has become easily distracted and absentminded as well, and his wife reports he is misplacing things around the house.

Screening for mild cognitive impairment (MCI) is not recommended for asymptomatic, cognitively healthy older persons, but memory complaints in individuals age >50—especially when corroborated by a reliable informant—warrant further assessment. Your challenge is to determine whether subtle cognitive changes in patients such as Mr. R are part of normal aging, caused by medical or mental illnesses, or a harbinger of Alzheimer’s disease (AD) or another dementia.

Although no treatments can yet prevent dementia, substantial new research is defining the MCI diagnosis for clinicians. This article describes:

  • the evolving understanding of MCI and its subtypes
  • risk factors for converting from MCI to AD
  • an evidence-based work-up (including functional, cognitive, and neuropsychological testing)
  • neuroprotective strategies for patients with an MCI diagnosis, including evidence on cholinesterase inhibitors, vitamin E, and anti-inflammatory agents.

MCI’s evolving definition

MCI is characterized by subjective and objective cognitive decline greater than expected for an individual’s age and education but less than the functional deficit required for a dementia diagnosis. MCI is proposed to identify persons with early but pathologic cognitive impairment that has a high risk to progress to AD and possibly other dementias.

MCI is thought to be a transitional state between normal aging and dementia.1 Its estimated prevalence in the general population is 19% among individuals age 85.2

MCI subtypes. Some experts view MCI as a single entity, whereas others suggest amnestic (aMCI) and nonamnestic (nMCI) subtypes.1,3 Each subtype is further divided into single and multiple cognitive domains. So, for example, the diagnosis would be:

  • aMCI-single cognitive domain for memory impairment only
  • aMCI-multiple cognitive domains for memory impairment plus nonmemory deficits, such as in language, executive function, or visuospatial function
  • nMCI-single or multiple cognitive domains for nonmemory deficits without memory impairment.
MCI subtypes may have different outcomes for progression to dementia, and all progressive dementias may have their own predementia states.4 Vascular MCI, for instance, is thought to result from cerebrovascular disease and is proposed to describe a prodrome of vascular dementia.5

Determining a patient’s MCI subtype is still a research activity and calls for comprehensive neuropsychological testing. MCI patients perform at least 1.5 standard deviations below the average for age- and education-matched healthy individuals on objective measures of memory.1

Conversion to dementia

In longitudinal population studies patients with MCI have shown an 11% to 33% risk of developing dementia within 2 years, whereas 44% reverted to normal 1 year later. Reasons for reversibility may include variable definitions of MCI among the longitudinal studies and the possibility that patients who recovered or improved may have had reversible causes of dementia.1

When patients with MCI are followed over time, they progress not only to AD but also to non-AD dementias. For example, patients with Parkinson’s disease (PD) and MCI may be at higher risk of progressing to dementia than cognitively intact PD patients.6 MCI patients with the e4 allele of the apolipoprotein E gene (ApoE e4) are at increased risk to convert from MCI to AD.7

Individuals with aMCI (Table 1)8 progress to AD at a rate of 10% to 15% per year, compared with 1% to 2% per year in normal elderly persons. The Mayo AD research center studies reported a conversion rate of up to 80% from aMCI to AD within 6 years.9

Research focuses on identifying preclinical AD states and potential targets for intervention using disease-modifying therapies. Some experts consider MCI to be the earliest clinical manifestation of AD, at least in a subgroup of patients.

Identifying markers to predict which patients are likely to convert from MCI to dementia also is a major research objective. In addition to ApoE status (Table 2),7,9-15 predictors of conversion may include:

 

 

  • hippocampal atrophy13
  • reduced metabolism in the temporoparietal cortex and posterior cingulum14
  • elevated CSF tau and the 42 amino acid form of ß-amyloid (Aß 42).15
Research techniques such as structural neuroimaging, positron-emission tomography, functional magnetic resonance imaging (fMRI), and cerebrospinal fluid biomarkers have not been defined for clinical use, however.

Neuropsychiatric symptoms. Individuals with MCI and neuropsychiatric symptoms may be at particular risk for progressing to dementia. Agitation or depression are more prevalent in persons with MCI than in normal elderly but less prevalent than in those with dementia (Table 3).10,16

The cross-sectional, community-based Cardiovascular Health Study showed one or more neuropsychiatric symptom in:

  • 16% of normal healthy elderly
  • 43% of MCI patients
  • 75% of dementia patients.16
Depression (20%), apathy (15%), and irritability (15%) were the neuropsychiatric symptoms reported most frequently in MCI patients, compared with apathy (36%), depression (32%), and agitation/aggression (30%) in dementia patients.

Sleep disturbances and anxiety in persons with MCI may predict progression to AD.10 A baseline high frequency of apathy in aMCI patients has been associated with progression to AD within 1 year.11

Table 1

Amnestic MCI: Proposed diagnostic criteria

Subjective memory impairment, preferably corroborated by a reliable informant
Reduced performance on objective memory tests, compared with persons of similar age and educational background
Typical general cognitive function
Intact basic activities of daily living and intact or minimally impaired instrumental activities of daily living
Absence of dementia
MCI: mild cognitive impairment
Source: Reference 8
Table 2

Factors shown to predict conversion from MCI to dementia

CategoryPredictors of conversion
ClinicalCognitive: Amnestic MCI
Neuropsychiatric: Depression, apathy, and possibly nighttime behaviors and anxiety
Neuropsychological testsClock-drawing test, Trail-Making Test B, Symbol Digit Modalities Test, Delayed 10-Word List Recall, New York University Paragraph Recall Test (Delayed), ADAS-Cog total score
NeuroimagingMRI: Entorhinal cortex and hippocampal atrophy
PET: Medial temporal region, parietotemporal association cortex, and posterior cingulate hypometabolism
fMRI: Abnormal hippocampal, posterior cingulate, and medial temporal region activation on memory tasks
CSF markersIncrease: t-tau, p-tau
Decrease: Aß 42
Genetic markersApoE e4 carriers
ADAS-Cog: Alzheimer’s Disease Assessment Scale-Cognitive subscale; ApoE e4: apolipoprotein E gene, e4 allele; CSF: cerebrospinal fluid; MCI: mild cognitive impairment; MRI: magnetic resonance imaging; fMRI: functional MRI; PET: positron-emission tomography
Source: References 7,9-15
Table 3

Neuropsychiatric symptoms: Rising prevalence mirrors cognitive deterioration in elderly patients*

Neuropsychiatric symptomsNormal elderlyMCIMild AD
Depressed mood/dysphoria++++++
Nighttime behaviors/sleep++++++
Irritability++++++
Anxiety+/-+++++
Apathy/indifference+/-+++++
Agitation/aggression+/-+/+++++
Eating/appetite disturbance+/-+++
Disinhibition+/-+/-++
Aberrant motor behavior0+++
Delusions0+/-++
Euphoria0+/-+/-
Hallucinations00+
* 0 = 0%; +/- = 1% to 5%; + = 6% to 10%; ++ = 11% to 20%; +++ = 21% to 40%
MCI: mild cognitive impairment; AD: Alzheimer’s disease
Source: References 10,16

Depression and MCI

Depression and cognitive complaints overlap considerably in older adults. Depressed patients without dementia show persistent cognitive deficits even after depression remits. In some patients, new-onset geriatric depression is considered a prodrome of MCI and AD. Given that AD neuropathologic changes precede clinical symptoms by many years, depression and AD have been proposed as different clinical manifestations of AD pathology.17

Among patients with MCI, 20% meet criteria for major depression and 26% for minor depression. Symptoms often include sadness, poor concentration, inner tension, pessimistic thoughts, lassitude, and insomnia.18

Depressed MCI patients are at higher risk of developing dementia than those without depression, especially if cognitive measures do not improve after depression is treated.12 Similarly, cognitively intact older persons who develop depression are at increased risk for MCI, particularly if they carry the ApoE e4 genotype.19

In the only study in which MCI patients’ neuropsychiatric symptoms have been treated, 39 elderly patients with depression and MCI received open-label sertraline, ≤200 mg/d, for 12 weeks. Among the 26 patients who completed the trial, 17 showed moderate improvement in depressive symptoms, attention, and executive function, and 9 showed no response.20

Recommendation. In clinical practice, antidepressant treatment—usually a selective serotonin reuptake inhibitor (SSRI), with or without psychotherapy—is recommended for the MCI patient with comorbid major depression.

CASE CONTINUED: No signs of depression

Mr. R’s medical, neurologic, and substance use history is unremarkable. Family history includes AD in a paternal aunt diagnosed at age 82. Mr. R reports no history of mood, sleep, or appetite changes and no psychotic symptoms. He shows no deficits in activities of daily living (ADL), although his wife recently took over paying household bills after he forgot to make a payment.

Evidence-based workup

Functional assessment. In the differential diagnosis of MCI, give special attention to functional impairment, which points toward dementia. ADL generally are preserved in MCI, and minimal deterioration is seen in instrumental activities of daily living (IADL). A relatively easy way to assess function is to use the Alzheimer’s Disease Functional Assessment and Change Scale (ADFACS), which is based on 16 ADL and IADL items (Table 4).21

 

 

A substantial functional decline precludes an MCI diagnosis, although the degree of functional decline can be difficult to assess in older adults with physical limitations caused by medical comorbidities.

Cognitive assessment. Because most individuals with MCI score in the normal range on the Folstein Mini-Mental State Examination (MMSE), the modified MMSE (3MS)22 may be more sensitive for detecting MCI. The 3MS retains the MMSE’s brevity (≤10 minutes to administer) but incorporates 4 additional items, has more graded scoring responses, and broadens the score range to 0 to 100. The clock-drawing test also is sensitive for MCI, especially in detecting early visuoconstructional dysfunction.

The Montreal Cognitive Assessment (MoCA) is a 10-minute, 30-point scale designed to help clinicians detect MCI (see Related Resources). The MoCA usually is given with the modified MMSE for a comprehensive cognitive assessment.

Nasreddine et al23 administered the MoCA and MMSE to 94 patients who met clinical criteria for MCI, 93 patients with mild AD, and 90 healthy cognitively normal elderly persons, using a cutoff score of 26. MoCA showed:

  • 90% sensitivity for detecting MCI (compared with 18% for the MMSE)
  • 87% specificity to exclude normal elderly persons.
The average MoCA score in patients with AD was much lower than in individuals with MCI, but score ranges of these 2 groups overlapped. Therefore, a score

Neuropsychological testing can be more sensitive than office-based screening tools in defining MCI subtypes. In the Alzheimer’s Disease Cooperative Study (ADCS), the neuropsychological measures that most accurately predicted progression of patients with aMCI to AD within 36 months were the:

  • Symbol Digit Modalities Test
  • New York University Paragraph Recall Test (Delayed)
  • Delayed 10-Word List Recall
  • Alzheimer’s Disease Assessment Scale-cognitive subscale (ADAS-Cog) total score.24
Laboratory tests, imaging. Use laboratory studies (Table 5) to rule out reversible causes of MCI symptoms.8 Reserve CSF studies for suspected CNS infection (such as meningitis, human immunodeficiency virus, or neurosyphilis) and brain imaging for suspected cerebral pathology (such as infarct, subdural hematoma, normal pressure hydrocephalus, or tumor).

Table 4

Alzheimer’s Disease Functional Assessment and Change Scale (ADFACS)

Basic ADLInstrumental ADL (IADL)
ToiletingUse of telephone
FeedingHousehold tasks
DressingUsing household appliances
Personal hygiene and groomingManaging money
 Shopping
BathingFood preparation
WalkingAbility to get around inside and outside home
 Hobbies and leisure activities
 Handling personal mail
 Grasp of situations and explanations
The 16-item ADFACS total score ranges from 0 to 54 (best to worst):
  • Rate basic ADLs from 0 (no impairment) to 4 (very severe impairment), for a total score range of 0 to 24.
  • Rate IADLs from 0 (no impairment) to 3 (severe impairment), for a total score range of 0 to 30.
Use total scores to assess for functional decline from baseline. A decline from 0 to 1 on individual ADL and IADL items is not considered clinically significant.
ADL: activities of daily living
Source: Reprinted with permission from reference 21
Table 5

Lab studies to rule out reversible causes of MCI

Complete blood count with differential
Basic metabolic panel
Liver function tests
Serum calcium
Serum vitamin B12 and folate
Thyroid function tests
Rapid plasma reagin
HIV in high-risk individuals
CSF studies if CNS infection is suspected
CSF: cerebrospinal fluid; HIV: human immunodeficiency virus; MCI: mild cognitive impairment
Source: Reference 8

CASE CONTINUED: Subtle cognitive deficits

Mr. R scores 27/30 on the MMSE (losing 3 points on recall) and 25/30 on the MoCA (losing points on visuospatial/executive function, fluency, and delayed recall). Thyroid stimulating hormone, vitamin B12, folate, and rapid plasma reagin tests are unremarkable; brain MRI shows no significant abnormalities.

You refer Mr. R for neuropsychological testing, and most cognitive domains are normal. Exceptions include moderate impairment in immediate and delayed verbal and visual memory and mild executive dysfunction.

Based on your clinical evaluation and neuropsychological testing, you diagnose amnestic MCI. Mr. R shows abnormalities in memory and executive functioning without significant decline in basic and instrumental ADLs, is not taking medications, and has no other medical or psychiatric condition that could explain his cognitive deficits.

You discuss the diagnosis with him and his wife, including evidence on his risk for progression to dementia, neuroprotective strategies, and medications.

After an MCI diagnosis

Neuroprotection. Eliminate medications with anticholinergic effects, including:

  • tricyclic antidepressants
  • conventional antipsychotics
  • antihistamines
  • drugs used to treat urinary incontinence, such as oxybutynin
  • muscle relaxants, such as cyclobenzaprine
  • certain antiparkinsonian drugs, such as benztropine.
Encourage patients to avoid alcohol and sedatives. Collaborate with primary care providers to control cerebrovascular risk factors such as hyperlipidemia, diabetes mellitus, hypertension, and obesity. Treat depression, which may be a risk factor for developing dementia.
 

 


Monitoring. The American Academy of Neurology recommends monitoring patients diagnosed with MCI every 6 to 12 months for cognitive and functional decline.

In these visits, include:

  • repeat office-based cognitive assessment, especially the modified MMSE, clock-drawing test, and MoCA
  • careful history-taking from the patient and reliable informant
  • repeat neuropsychological testing annually or when dementia is suspected
  • assessment of the caregiver for distress.
Compensating for memory loss. Many individuals with MCI have insight into their cognitive deficits and are interested in making lifestyle changes. Experts recommend:

  • moderate exercise (at least 30 minutes per session, 3 times a week)
  • cognitively stimulating activities that involve language and psychomotor coordination, such as dancing, crossword puzzles, and volunteer work.
Potentially helpful tools include calendars, reminder notes, electronic cuing devices, pill boxes, and “speed-dial” telephones. Encourage patients to participate in local senior organizations and to use community resources.1

Medications—yes or no? Cholinesterase inhibitors, rofecoxib, and vitamin E have not been shown to prevent MCI from progressing to AD. Thus, insufficient evidence exists to recommend medications for patients with MCI.

Donepezil has shown possible short-term benefits, however, and patients may choose to try this medication. Some find comfort in seeking this “extra time” to make decisions about advanced directives, attend to estate and will issues, and optimize relationships while they have only mild cognitive deficits and possess decision-making capacity.

Donepezil. The Alzheimer’s Disease Cooperative Study—supported by the National Institute on Aging—was designed to determine whether daily doses of donepezil or vitamin E can delay or prevent progression of aMCI to AD.25 In the double-blind, placebo-controlled, parallel group study, 769 patients with aMCI were randomly assigned to receive donepezil, 10 mg/d; vitamin E, 1,000 IU bid; or placebo for 3 years.

Overall progression to AD was 16% per year, and the 3-year risk of progression was the same in all 3 groups. Donepezil therapy was associated with a reduced rate of progression to AD compared with placebo during the first year of treatment. Donepezil’s benefit was evident among ApoE e4 carriers at 2-year follow-up, but none of the 3 groups showed statistically significant differences after 3 years. Vitamin E showed no effect on AD progression throughout the study.

Rivastigmine. A randomized, placebo-controlled trial in which 1,018 MCI patients received rivastigmine or placebo for 4 years found no statistically significant benefit of rivastigmine on AD progression.26

Galantamine. Two international randomized, double-blind, placebo-controlled trials failed to show a statistically significant benefit of galantamine in slowing progression from aMCI to AD. MRI data from one of these studies suggested that galantamine may have reduced the rate of brain atrophy over a 2-year period.27

Rofecoxib. Epidemiologic studies indicate that anti-inflammatory drugs may reduce the risk of developing AD, but the COX-2 inhibitor rofecoxib did not delay progression to AD among aMCI patients in a large, placebo-controlled trial.28

Educate patients and family members about supportive nonpharmacologic treatments and cholinesterase inhibitors. The Alzheimer’s Association, National Institute on Aging, and local department of aging agencies offer useful resources (see Related Resources).

CASE CONTINUED: Dealing with uncertainty

Mr. R and his wife are unsettled by his MCI diagnosis. They prefer to take a “wait and watch” approach, decline initiation of a cholinesterase inhibitor, and agree to adhere to nonpharmacologic interventions you discussed. You schedule a follow-up visit in 6 months and encourage them to call you with questions.

Related resources

  • Rosenberg PB, Johnston D, Lyketsos CG. A clinical approach to mild cognitive impairment. Am J Psychiatry 2006;163: 1884-90.
  • Montreal Cognitive Assessment (MoCA). 10-minute screening test designed to help clinicians detect mild cognitive impairment. www.mocatest.org.
  • Alzheimer’s Association. www.alz.org.
  • National Institute on Aging. www.nia.nih.gov.
Drug brand name

  • Benztropine • Cogentin
  • Cyclobenzaprine • Flexeril
  • Donepezil • Aricept
  • Galantamine • Razadyne
  • Oxybutynin • Ditropan
  • Rivastigmine • Exelon
  • Rofecoxib • Vioxx
  • Sertraline • Zoloft
Disclosure

Dr. Goveas and Dr. Dixon-Holbrook report no financial relationship with any company whose products are mentioned in this article or with manufacturers of competing products.

Dr. Kerwin is a consultant to Pfizer and a speaker for Pfizer and Novartis.

Dr. Antuono receives research support from Eisai, Pfizer, and Elan and is a speaker for Pfizer and Forest Pharmaceuticals.

References

1. Gauthier S, Reisberg B, Zaudig M, et al. Mild cognitive impairment. Lancet 2006;367:1262-70.

2. Lopez OL, Jagust WJ, DeKosky ST, et al. Prevalence and classification of mild cognitive impairment in the Cardiovascular Health Study Cognition Study: part 1. Arch Neurol 2003;60:1385-9.

3. Petersen RC. Conceptual review. In: Petersen RC, ed. Mild cognitive impairment: aging to Alzheimer’s disease. New York, NY: Oxford University Press; 2003:1-14.

4. Petersen RC, Morris JC. Mild cognitive impairment as a clinical entity and treatment target. Arch Neurol 2005;62:1160-3.

5. O’Brien JT. Vascular cognitive impairment. Am J Geriatr Psychiatry 2006;14:724-33.

6. Janvin CC, Larsen JP, Aarsland D, et al. Subtypes of mild cognitive impairment in Parkinson’s disease: progression to dementia. Mov Disord 2006;21:1343-9.

7. Farlow MR, He Y, Tekin S, et al. Impact of APOE in mild cognitive impairment. Neurology 2004;63:1898-1901.

8. Winblad B, Palmer K, Kivipelto M, et al. Mild cognitive impairment—beyond controversies, towards a consensus: report of the International Working Group on Mild Cognitive Impairment. J Intern Med 2004;256:240-6.

9. Petersen RC. Mild cognitive impairment as a diagnostic entity. J Intern Med 2004;256:183-94.

10. Geda YE, Smith GE, Knopman DS, et al. De novo genesis of neuropsychiatric symptoms in mild cognitive impairment (MCI). Int Psychogeriatr 2004;16:51-60.

11. Robert PH, Berr C, Volteau M, et al. Apathy in patients with mild cognitive impairment and the risk of developing dementia of Alzheimer’s disease: a one-year follow-up study. Clin Neurol Neurosurg 2006;108:733-6.

12. Modrego PJ, Ferrandez J. Depression in patients with mild cognitive impairment increases the risk of developing dementia of Alzheimer type. Arch Neurol 2004;61:1290-3.

13. Jack CR, Petersen RC, Xu YC, et al. Prediction of AD with MRI-based hippocampal volume in mild cognitive impairment. Neurology 1999;52:1397-1403.

14. Nestor PJ, Fryer TD, Smielewski P, et al. Limbic hypometabolism in Alzheimer’s disease and mild cognitive impairment. Ann Neurol 2003;54:343-51.

15. Sunderland T, Hampel H, Takeda M, et al. Biomarkers in the diagnosis of Alzheimer’s disease: are we ready? J Geriatr Psychiatry Neurol 2006;19:172-9.

16. Lyketsos CG, Lopez O, Jones B, et al. Prevalence of neuropsychiatric symptoms in dementia and mild cognitive impairment: results from the Cardiovascular Health Study. JAMA 2002;288:1475-83.

17. Steffens DC, Otey E, Alexoupolos GS, et al. Perspectives on depression, mild cognitive impairment, and cognitive decline. Arch Gen Psychiatry 2006;63:130-8.

18. Gabryelewicz T, Styczynska M, Pfeffer A, et al. Prevalence of major and minor depression in elderly persons with mild cognitive impairment: MADRS factor analysis. Int J Geriatr Psychiatry 2004;19:1168-72.

19. Geda YE, Knopman DS, Mrazek DA, et al. Depression, apolipoprotein E genotype, and the incidence of mild cognitive impairment: a prospective cohort study. Arch Neurol 2006;63:435-40.

20. Devanand DP, Pelton GH, Marston K, et al. Sertraline treatment of elderly patients with depression and cognitive impairment. Int J Geriatr Psychiatry 2003;18:123-30.

21. Mohs RC, Doody RS, Morris JC, et al. A 1-year, placebo-controlled preservation of function survival study of donepezil in AD patients. Neurology 2001;57:481-8.

22. Teng EL, Chui HC. The Modified Mini-Mental State (3MS) examination. J Clin Psychiatry 1987;48:314-8.

23. Nasreddine ZS, Phillips NA, Bédirian V, et al. The Montreal Cognitive Assessment (MoCA): a brief screening tool for mild cognitive impairment. J Am Geriatr Soc 2005;53:695-9.

24. Fleisher AS, Sowell BB, Taylor C, et al. Clinical predictors of progression to Alzheimer disease in amnestic mild cognitive impairment. Neurology 2007;68:1588-95.

25. Petersen RC, Thomas RG, Grundman M, et al. for the Alzheimer’s Disease Cooperative Study Group. Vitamin E and donepezil for the treatment of mild cognitive impairment. N Engl J Med 2005;352:2379-88.

26. Feldman HH, Ferris S, Winblad B, et al. Effect of rivastigmine on delay to diagnosis of Alzheimer’s disease from mild cognitive impairment: the InDDEx study. Lancet Neurol 2007;6:501-12.

27. Petersen RC. Mild cognitive impairment: current research and clinical implications. Semin Neurol 2007;27:22-31.

28. Thal LJ, Ferris SH, Kirby L, et al. A randomized, double-blind study of rofecoxib in patients with mild cognitive impairment. Neuropsychopharmacology 2005;30(6):1204-15.

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Meredith Dixon-Holbrook, MD
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Diana Kerwin, MD
Assistant professor, Department of internal medicine, Division of geriatrics/gerontology, Medical College of Wisconsin, Milwaukee
Piero Antuono, MD
Professor of neurology, Medical College of Wisconsin, Milwaukee

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Piero Antuono, MD
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Assistant professor, Department of psychiatry and behavioral medicine, Medical College of Wisconsin, Milwaukee
Meredith Dixon-Holbrook, MD
First-year resident in psychiatry, Medical College of Wisconsin, Milwaukee
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Assistant professor, Department of internal medicine, Division of geriatrics/gerontology, Medical College of Wisconsin, Milwaukee
Piero Antuono, MD
Professor of neurology, Medical College of Wisconsin, Milwaukee

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Mr. R, age 67, presents with what he describes as uncharacteristic “memory loss” that is affecting his ability to run his accounting business. He and his wife relate that he was doing well until approximately 9 months ago, when he started showing difficulties remembering clients’ names and addresses.

His wife became extremely concerned when he made serious accounting errors in a 1-month period that resulted in the loss of a longtime customer. Mr. R has become easily distracted and absentminded as well, and his wife reports he is misplacing things around the house.

Screening for mild cognitive impairment (MCI) is not recommended for asymptomatic, cognitively healthy older persons, but memory complaints in individuals age >50—especially when corroborated by a reliable informant—warrant further assessment. Your challenge is to determine whether subtle cognitive changes in patients such as Mr. R are part of normal aging, caused by medical or mental illnesses, or a harbinger of Alzheimer’s disease (AD) or another dementia.

Although no treatments can yet prevent dementia, substantial new research is defining the MCI diagnosis for clinicians. This article describes:

  • the evolving understanding of MCI and its subtypes
  • risk factors for converting from MCI to AD
  • an evidence-based work-up (including functional, cognitive, and neuropsychological testing)
  • neuroprotective strategies for patients with an MCI diagnosis, including evidence on cholinesterase inhibitors, vitamin E, and anti-inflammatory agents.

MCI’s evolving definition

MCI is characterized by subjective and objective cognitive decline greater than expected for an individual’s age and education but less than the functional deficit required for a dementia diagnosis. MCI is proposed to identify persons with early but pathologic cognitive impairment that has a high risk to progress to AD and possibly other dementias.

MCI is thought to be a transitional state between normal aging and dementia.1 Its estimated prevalence in the general population is 19% among individuals age 85.2

MCI subtypes. Some experts view MCI as a single entity, whereas others suggest amnestic (aMCI) and nonamnestic (nMCI) subtypes.1,3 Each subtype is further divided into single and multiple cognitive domains. So, for example, the diagnosis would be:

  • aMCI-single cognitive domain for memory impairment only
  • aMCI-multiple cognitive domains for memory impairment plus nonmemory deficits, such as in language, executive function, or visuospatial function
  • nMCI-single or multiple cognitive domains for nonmemory deficits without memory impairment.
MCI subtypes may have different outcomes for progression to dementia, and all progressive dementias may have their own predementia states.4 Vascular MCI, for instance, is thought to result from cerebrovascular disease and is proposed to describe a prodrome of vascular dementia.5

Determining a patient’s MCI subtype is still a research activity and calls for comprehensive neuropsychological testing. MCI patients perform at least 1.5 standard deviations below the average for age- and education-matched healthy individuals on objective measures of memory.1

Conversion to dementia

In longitudinal population studies patients with MCI have shown an 11% to 33% risk of developing dementia within 2 years, whereas 44% reverted to normal 1 year later. Reasons for reversibility may include variable definitions of MCI among the longitudinal studies and the possibility that patients who recovered or improved may have had reversible causes of dementia.1

When patients with MCI are followed over time, they progress not only to AD but also to non-AD dementias. For example, patients with Parkinson’s disease (PD) and MCI may be at higher risk of progressing to dementia than cognitively intact PD patients.6 MCI patients with the e4 allele of the apolipoprotein E gene (ApoE e4) are at increased risk to convert from MCI to AD.7

Individuals with aMCI (Table 1)8 progress to AD at a rate of 10% to 15% per year, compared with 1% to 2% per year in normal elderly persons. The Mayo AD research center studies reported a conversion rate of up to 80% from aMCI to AD within 6 years.9

Research focuses on identifying preclinical AD states and potential targets for intervention using disease-modifying therapies. Some experts consider MCI to be the earliest clinical manifestation of AD, at least in a subgroup of patients.

Identifying markers to predict which patients are likely to convert from MCI to dementia also is a major research objective. In addition to ApoE status (Table 2),7,9-15 predictors of conversion may include:

 

 

  • hippocampal atrophy13
  • reduced metabolism in the temporoparietal cortex and posterior cingulum14
  • elevated CSF tau and the 42 amino acid form of ß-amyloid (Aß 42).15
Research techniques such as structural neuroimaging, positron-emission tomography, functional magnetic resonance imaging (fMRI), and cerebrospinal fluid biomarkers have not been defined for clinical use, however.

Neuropsychiatric symptoms. Individuals with MCI and neuropsychiatric symptoms may be at particular risk for progressing to dementia. Agitation or depression are more prevalent in persons with MCI than in normal elderly but less prevalent than in those with dementia (Table 3).10,16

The cross-sectional, community-based Cardiovascular Health Study showed one or more neuropsychiatric symptom in:

  • 16% of normal healthy elderly
  • 43% of MCI patients
  • 75% of dementia patients.16
Depression (20%), apathy (15%), and irritability (15%) were the neuropsychiatric symptoms reported most frequently in MCI patients, compared with apathy (36%), depression (32%), and agitation/aggression (30%) in dementia patients.

Sleep disturbances and anxiety in persons with MCI may predict progression to AD.10 A baseline high frequency of apathy in aMCI patients has been associated with progression to AD within 1 year.11

Table 1

Amnestic MCI: Proposed diagnostic criteria

Subjective memory impairment, preferably corroborated by a reliable informant
Reduced performance on objective memory tests, compared with persons of similar age and educational background
Typical general cognitive function
Intact basic activities of daily living and intact or minimally impaired instrumental activities of daily living
Absence of dementia
MCI: mild cognitive impairment
Source: Reference 8
Table 2

Factors shown to predict conversion from MCI to dementia

CategoryPredictors of conversion
ClinicalCognitive: Amnestic MCI
Neuropsychiatric: Depression, apathy, and possibly nighttime behaviors and anxiety
Neuropsychological testsClock-drawing test, Trail-Making Test B, Symbol Digit Modalities Test, Delayed 10-Word List Recall, New York University Paragraph Recall Test (Delayed), ADAS-Cog total score
NeuroimagingMRI: Entorhinal cortex and hippocampal atrophy
PET: Medial temporal region, parietotemporal association cortex, and posterior cingulate hypometabolism
fMRI: Abnormal hippocampal, posterior cingulate, and medial temporal region activation on memory tasks
CSF markersIncrease: t-tau, p-tau
Decrease: Aß 42
Genetic markersApoE e4 carriers
ADAS-Cog: Alzheimer’s Disease Assessment Scale-Cognitive subscale; ApoE e4: apolipoprotein E gene, e4 allele; CSF: cerebrospinal fluid; MCI: mild cognitive impairment; MRI: magnetic resonance imaging; fMRI: functional MRI; PET: positron-emission tomography
Source: References 7,9-15
Table 3

Neuropsychiatric symptoms: Rising prevalence mirrors cognitive deterioration in elderly patients*

Neuropsychiatric symptomsNormal elderlyMCIMild AD
Depressed mood/dysphoria++++++
Nighttime behaviors/sleep++++++
Irritability++++++
Anxiety+/-+++++
Apathy/indifference+/-+++++
Agitation/aggression+/-+/+++++
Eating/appetite disturbance+/-+++
Disinhibition+/-+/-++
Aberrant motor behavior0+++
Delusions0+/-++
Euphoria0+/-+/-
Hallucinations00+
* 0 = 0%; +/- = 1% to 5%; + = 6% to 10%; ++ = 11% to 20%; +++ = 21% to 40%
MCI: mild cognitive impairment; AD: Alzheimer’s disease
Source: References 10,16

Depression and MCI

Depression and cognitive complaints overlap considerably in older adults. Depressed patients without dementia show persistent cognitive deficits even after depression remits. In some patients, new-onset geriatric depression is considered a prodrome of MCI and AD. Given that AD neuropathologic changes precede clinical symptoms by many years, depression and AD have been proposed as different clinical manifestations of AD pathology.17

Among patients with MCI, 20% meet criteria for major depression and 26% for minor depression. Symptoms often include sadness, poor concentration, inner tension, pessimistic thoughts, lassitude, and insomnia.18

Depressed MCI patients are at higher risk of developing dementia than those without depression, especially if cognitive measures do not improve after depression is treated.12 Similarly, cognitively intact older persons who develop depression are at increased risk for MCI, particularly if they carry the ApoE e4 genotype.19

In the only study in which MCI patients’ neuropsychiatric symptoms have been treated, 39 elderly patients with depression and MCI received open-label sertraline, ≤200 mg/d, for 12 weeks. Among the 26 patients who completed the trial, 17 showed moderate improvement in depressive symptoms, attention, and executive function, and 9 showed no response.20

Recommendation. In clinical practice, antidepressant treatment—usually a selective serotonin reuptake inhibitor (SSRI), with or without psychotherapy—is recommended for the MCI patient with comorbid major depression.

CASE CONTINUED: No signs of depression

Mr. R’s medical, neurologic, and substance use history is unremarkable. Family history includes AD in a paternal aunt diagnosed at age 82. Mr. R reports no history of mood, sleep, or appetite changes and no psychotic symptoms. He shows no deficits in activities of daily living (ADL), although his wife recently took over paying household bills after he forgot to make a payment.

Evidence-based workup

Functional assessment. In the differential diagnosis of MCI, give special attention to functional impairment, which points toward dementia. ADL generally are preserved in MCI, and minimal deterioration is seen in instrumental activities of daily living (IADL). A relatively easy way to assess function is to use the Alzheimer’s Disease Functional Assessment and Change Scale (ADFACS), which is based on 16 ADL and IADL items (Table 4).21

 

 

A substantial functional decline precludes an MCI diagnosis, although the degree of functional decline can be difficult to assess in older adults with physical limitations caused by medical comorbidities.

Cognitive assessment. Because most individuals with MCI score in the normal range on the Folstein Mini-Mental State Examination (MMSE), the modified MMSE (3MS)22 may be more sensitive for detecting MCI. The 3MS retains the MMSE’s brevity (≤10 minutes to administer) but incorporates 4 additional items, has more graded scoring responses, and broadens the score range to 0 to 100. The clock-drawing test also is sensitive for MCI, especially in detecting early visuoconstructional dysfunction.

The Montreal Cognitive Assessment (MoCA) is a 10-minute, 30-point scale designed to help clinicians detect MCI (see Related Resources). The MoCA usually is given with the modified MMSE for a comprehensive cognitive assessment.

Nasreddine et al23 administered the MoCA and MMSE to 94 patients who met clinical criteria for MCI, 93 patients with mild AD, and 90 healthy cognitively normal elderly persons, using a cutoff score of 26. MoCA showed:

  • 90% sensitivity for detecting MCI (compared with 18% for the MMSE)
  • 87% specificity to exclude normal elderly persons.
The average MoCA score in patients with AD was much lower than in individuals with MCI, but score ranges of these 2 groups overlapped. Therefore, a score

Neuropsychological testing can be more sensitive than office-based screening tools in defining MCI subtypes. In the Alzheimer’s Disease Cooperative Study (ADCS), the neuropsychological measures that most accurately predicted progression of patients with aMCI to AD within 36 months were the:

  • Symbol Digit Modalities Test
  • New York University Paragraph Recall Test (Delayed)
  • Delayed 10-Word List Recall
  • Alzheimer’s Disease Assessment Scale-cognitive subscale (ADAS-Cog) total score.24
Laboratory tests, imaging. Use laboratory studies (Table 5) to rule out reversible causes of MCI symptoms.8 Reserve CSF studies for suspected CNS infection (such as meningitis, human immunodeficiency virus, or neurosyphilis) and brain imaging for suspected cerebral pathology (such as infarct, subdural hematoma, normal pressure hydrocephalus, or tumor).

Table 4

Alzheimer’s Disease Functional Assessment and Change Scale (ADFACS)

Basic ADLInstrumental ADL (IADL)
ToiletingUse of telephone
FeedingHousehold tasks
DressingUsing household appliances
Personal hygiene and groomingManaging money
 Shopping
BathingFood preparation
WalkingAbility to get around inside and outside home
 Hobbies and leisure activities
 Handling personal mail
 Grasp of situations and explanations
The 16-item ADFACS total score ranges from 0 to 54 (best to worst):
  • Rate basic ADLs from 0 (no impairment) to 4 (very severe impairment), for a total score range of 0 to 24.
  • Rate IADLs from 0 (no impairment) to 3 (severe impairment), for a total score range of 0 to 30.
Use total scores to assess for functional decline from baseline. A decline from 0 to 1 on individual ADL and IADL items is not considered clinically significant.
ADL: activities of daily living
Source: Reprinted with permission from reference 21
Table 5

Lab studies to rule out reversible causes of MCI

Complete blood count with differential
Basic metabolic panel
Liver function tests
Serum calcium
Serum vitamin B12 and folate
Thyroid function tests
Rapid plasma reagin
HIV in high-risk individuals
CSF studies if CNS infection is suspected
CSF: cerebrospinal fluid; HIV: human immunodeficiency virus; MCI: mild cognitive impairment
Source: Reference 8

CASE CONTINUED: Subtle cognitive deficits

Mr. R scores 27/30 on the MMSE (losing 3 points on recall) and 25/30 on the MoCA (losing points on visuospatial/executive function, fluency, and delayed recall). Thyroid stimulating hormone, vitamin B12, folate, and rapid plasma reagin tests are unremarkable; brain MRI shows no significant abnormalities.

You refer Mr. R for neuropsychological testing, and most cognitive domains are normal. Exceptions include moderate impairment in immediate and delayed verbal and visual memory and mild executive dysfunction.

Based on your clinical evaluation and neuropsychological testing, you diagnose amnestic MCI. Mr. R shows abnormalities in memory and executive functioning without significant decline in basic and instrumental ADLs, is not taking medications, and has no other medical or psychiatric condition that could explain his cognitive deficits.

You discuss the diagnosis with him and his wife, including evidence on his risk for progression to dementia, neuroprotective strategies, and medications.

After an MCI diagnosis

Neuroprotection. Eliminate medications with anticholinergic effects, including:

  • tricyclic antidepressants
  • conventional antipsychotics
  • antihistamines
  • drugs used to treat urinary incontinence, such as oxybutynin
  • muscle relaxants, such as cyclobenzaprine
  • certain antiparkinsonian drugs, such as benztropine.
Encourage patients to avoid alcohol and sedatives. Collaborate with primary care providers to control cerebrovascular risk factors such as hyperlipidemia, diabetes mellitus, hypertension, and obesity. Treat depression, which may be a risk factor for developing dementia.
 

 


Monitoring. The American Academy of Neurology recommends monitoring patients diagnosed with MCI every 6 to 12 months for cognitive and functional decline.

In these visits, include:

  • repeat office-based cognitive assessment, especially the modified MMSE, clock-drawing test, and MoCA
  • careful history-taking from the patient and reliable informant
  • repeat neuropsychological testing annually or when dementia is suspected
  • assessment of the caregiver for distress.
Compensating for memory loss. Many individuals with MCI have insight into their cognitive deficits and are interested in making lifestyle changes. Experts recommend:

  • moderate exercise (at least 30 minutes per session, 3 times a week)
  • cognitively stimulating activities that involve language and psychomotor coordination, such as dancing, crossword puzzles, and volunteer work.
Potentially helpful tools include calendars, reminder notes, electronic cuing devices, pill boxes, and “speed-dial” telephones. Encourage patients to participate in local senior organizations and to use community resources.1

Medications—yes or no? Cholinesterase inhibitors, rofecoxib, and vitamin E have not been shown to prevent MCI from progressing to AD. Thus, insufficient evidence exists to recommend medications for patients with MCI.

Donepezil has shown possible short-term benefits, however, and patients may choose to try this medication. Some find comfort in seeking this “extra time” to make decisions about advanced directives, attend to estate and will issues, and optimize relationships while they have only mild cognitive deficits and possess decision-making capacity.

Donepezil. The Alzheimer’s Disease Cooperative Study—supported by the National Institute on Aging—was designed to determine whether daily doses of donepezil or vitamin E can delay or prevent progression of aMCI to AD.25 In the double-blind, placebo-controlled, parallel group study, 769 patients with aMCI were randomly assigned to receive donepezil, 10 mg/d; vitamin E, 1,000 IU bid; or placebo for 3 years.

Overall progression to AD was 16% per year, and the 3-year risk of progression was the same in all 3 groups. Donepezil therapy was associated with a reduced rate of progression to AD compared with placebo during the first year of treatment. Donepezil’s benefit was evident among ApoE e4 carriers at 2-year follow-up, but none of the 3 groups showed statistically significant differences after 3 years. Vitamin E showed no effect on AD progression throughout the study.

Rivastigmine. A randomized, placebo-controlled trial in which 1,018 MCI patients received rivastigmine or placebo for 4 years found no statistically significant benefit of rivastigmine on AD progression.26

Galantamine. Two international randomized, double-blind, placebo-controlled trials failed to show a statistically significant benefit of galantamine in slowing progression from aMCI to AD. MRI data from one of these studies suggested that galantamine may have reduced the rate of brain atrophy over a 2-year period.27

Rofecoxib. Epidemiologic studies indicate that anti-inflammatory drugs may reduce the risk of developing AD, but the COX-2 inhibitor rofecoxib did not delay progression to AD among aMCI patients in a large, placebo-controlled trial.28

Educate patients and family members about supportive nonpharmacologic treatments and cholinesterase inhibitors. The Alzheimer’s Association, National Institute on Aging, and local department of aging agencies offer useful resources (see Related Resources).

CASE CONTINUED: Dealing with uncertainty

Mr. R and his wife are unsettled by his MCI diagnosis. They prefer to take a “wait and watch” approach, decline initiation of a cholinesterase inhibitor, and agree to adhere to nonpharmacologic interventions you discussed. You schedule a follow-up visit in 6 months and encourage them to call you with questions.

Related resources

  • Rosenberg PB, Johnston D, Lyketsos CG. A clinical approach to mild cognitive impairment. Am J Psychiatry 2006;163: 1884-90.
  • Montreal Cognitive Assessment (MoCA). 10-minute screening test designed to help clinicians detect mild cognitive impairment. www.mocatest.org.
  • Alzheimer’s Association. www.alz.org.
  • National Institute on Aging. www.nia.nih.gov.
Drug brand name

  • Benztropine • Cogentin
  • Cyclobenzaprine • Flexeril
  • Donepezil • Aricept
  • Galantamine • Razadyne
  • Oxybutynin • Ditropan
  • Rivastigmine • Exelon
  • Rofecoxib • Vioxx
  • Sertraline • Zoloft
Disclosure

Dr. Goveas and Dr. Dixon-Holbrook report no financial relationship with any company whose products are mentioned in this article or with manufacturers of competing products.

Dr. Kerwin is a consultant to Pfizer and a speaker for Pfizer and Novartis.

Dr. Antuono receives research support from Eisai, Pfizer, and Elan and is a speaker for Pfizer and Forest Pharmaceuticals.

Mr. R, age 67, presents with what he describes as uncharacteristic “memory loss” that is affecting his ability to run his accounting business. He and his wife relate that he was doing well until approximately 9 months ago, when he started showing difficulties remembering clients’ names and addresses.

His wife became extremely concerned when he made serious accounting errors in a 1-month period that resulted in the loss of a longtime customer. Mr. R has become easily distracted and absentminded as well, and his wife reports he is misplacing things around the house.

Screening for mild cognitive impairment (MCI) is not recommended for asymptomatic, cognitively healthy older persons, but memory complaints in individuals age >50—especially when corroborated by a reliable informant—warrant further assessment. Your challenge is to determine whether subtle cognitive changes in patients such as Mr. R are part of normal aging, caused by medical or mental illnesses, or a harbinger of Alzheimer’s disease (AD) or another dementia.

Although no treatments can yet prevent dementia, substantial new research is defining the MCI diagnosis for clinicians. This article describes:

  • the evolving understanding of MCI and its subtypes
  • risk factors for converting from MCI to AD
  • an evidence-based work-up (including functional, cognitive, and neuropsychological testing)
  • neuroprotective strategies for patients with an MCI diagnosis, including evidence on cholinesterase inhibitors, vitamin E, and anti-inflammatory agents.

MCI’s evolving definition

MCI is characterized by subjective and objective cognitive decline greater than expected for an individual’s age and education but less than the functional deficit required for a dementia diagnosis. MCI is proposed to identify persons with early but pathologic cognitive impairment that has a high risk to progress to AD and possibly other dementias.

MCI is thought to be a transitional state between normal aging and dementia.1 Its estimated prevalence in the general population is 19% among individuals age 85.2

MCI subtypes. Some experts view MCI as a single entity, whereas others suggest amnestic (aMCI) and nonamnestic (nMCI) subtypes.1,3 Each subtype is further divided into single and multiple cognitive domains. So, for example, the diagnosis would be:

  • aMCI-single cognitive domain for memory impairment only
  • aMCI-multiple cognitive domains for memory impairment plus nonmemory deficits, such as in language, executive function, or visuospatial function
  • nMCI-single or multiple cognitive domains for nonmemory deficits without memory impairment.
MCI subtypes may have different outcomes for progression to dementia, and all progressive dementias may have their own predementia states.4 Vascular MCI, for instance, is thought to result from cerebrovascular disease and is proposed to describe a prodrome of vascular dementia.5

Determining a patient’s MCI subtype is still a research activity and calls for comprehensive neuropsychological testing. MCI patients perform at least 1.5 standard deviations below the average for age- and education-matched healthy individuals on objective measures of memory.1

Conversion to dementia

In longitudinal population studies patients with MCI have shown an 11% to 33% risk of developing dementia within 2 years, whereas 44% reverted to normal 1 year later. Reasons for reversibility may include variable definitions of MCI among the longitudinal studies and the possibility that patients who recovered or improved may have had reversible causes of dementia.1

When patients with MCI are followed over time, they progress not only to AD but also to non-AD dementias. For example, patients with Parkinson’s disease (PD) and MCI may be at higher risk of progressing to dementia than cognitively intact PD patients.6 MCI patients with the e4 allele of the apolipoprotein E gene (ApoE e4) are at increased risk to convert from MCI to AD.7

Individuals with aMCI (Table 1)8 progress to AD at a rate of 10% to 15% per year, compared with 1% to 2% per year in normal elderly persons. The Mayo AD research center studies reported a conversion rate of up to 80% from aMCI to AD within 6 years.9

Research focuses on identifying preclinical AD states and potential targets for intervention using disease-modifying therapies. Some experts consider MCI to be the earliest clinical manifestation of AD, at least in a subgroup of patients.

Identifying markers to predict which patients are likely to convert from MCI to dementia also is a major research objective. In addition to ApoE status (Table 2),7,9-15 predictors of conversion may include:

 

 

  • hippocampal atrophy13
  • reduced metabolism in the temporoparietal cortex and posterior cingulum14
  • elevated CSF tau and the 42 amino acid form of ß-amyloid (Aß 42).15
Research techniques such as structural neuroimaging, positron-emission tomography, functional magnetic resonance imaging (fMRI), and cerebrospinal fluid biomarkers have not been defined for clinical use, however.

Neuropsychiatric symptoms. Individuals with MCI and neuropsychiatric symptoms may be at particular risk for progressing to dementia. Agitation or depression are more prevalent in persons with MCI than in normal elderly but less prevalent than in those with dementia (Table 3).10,16

The cross-sectional, community-based Cardiovascular Health Study showed one or more neuropsychiatric symptom in:

  • 16% of normal healthy elderly
  • 43% of MCI patients
  • 75% of dementia patients.16
Depression (20%), apathy (15%), and irritability (15%) were the neuropsychiatric symptoms reported most frequently in MCI patients, compared with apathy (36%), depression (32%), and agitation/aggression (30%) in dementia patients.

Sleep disturbances and anxiety in persons with MCI may predict progression to AD.10 A baseline high frequency of apathy in aMCI patients has been associated with progression to AD within 1 year.11

Table 1

Amnestic MCI: Proposed diagnostic criteria

Subjective memory impairment, preferably corroborated by a reliable informant
Reduced performance on objective memory tests, compared with persons of similar age and educational background
Typical general cognitive function
Intact basic activities of daily living and intact or minimally impaired instrumental activities of daily living
Absence of dementia
MCI: mild cognitive impairment
Source: Reference 8
Table 2

Factors shown to predict conversion from MCI to dementia

CategoryPredictors of conversion
ClinicalCognitive: Amnestic MCI
Neuropsychiatric: Depression, apathy, and possibly nighttime behaviors and anxiety
Neuropsychological testsClock-drawing test, Trail-Making Test B, Symbol Digit Modalities Test, Delayed 10-Word List Recall, New York University Paragraph Recall Test (Delayed), ADAS-Cog total score
NeuroimagingMRI: Entorhinal cortex and hippocampal atrophy
PET: Medial temporal region, parietotemporal association cortex, and posterior cingulate hypometabolism
fMRI: Abnormal hippocampal, posterior cingulate, and medial temporal region activation on memory tasks
CSF markersIncrease: t-tau, p-tau
Decrease: Aß 42
Genetic markersApoE e4 carriers
ADAS-Cog: Alzheimer’s Disease Assessment Scale-Cognitive subscale; ApoE e4: apolipoprotein E gene, e4 allele; CSF: cerebrospinal fluid; MCI: mild cognitive impairment; MRI: magnetic resonance imaging; fMRI: functional MRI; PET: positron-emission tomography
Source: References 7,9-15
Table 3

Neuropsychiatric symptoms: Rising prevalence mirrors cognitive deterioration in elderly patients*

Neuropsychiatric symptomsNormal elderlyMCIMild AD
Depressed mood/dysphoria++++++
Nighttime behaviors/sleep++++++
Irritability++++++
Anxiety+/-+++++
Apathy/indifference+/-+++++
Agitation/aggression+/-+/+++++
Eating/appetite disturbance+/-+++
Disinhibition+/-+/-++
Aberrant motor behavior0+++
Delusions0+/-++
Euphoria0+/-+/-
Hallucinations00+
* 0 = 0%; +/- = 1% to 5%; + = 6% to 10%; ++ = 11% to 20%; +++ = 21% to 40%
MCI: mild cognitive impairment; AD: Alzheimer’s disease
Source: References 10,16

Depression and MCI

Depression and cognitive complaints overlap considerably in older adults. Depressed patients without dementia show persistent cognitive deficits even after depression remits. In some patients, new-onset geriatric depression is considered a prodrome of MCI and AD. Given that AD neuropathologic changes precede clinical symptoms by many years, depression and AD have been proposed as different clinical manifestations of AD pathology.17

Among patients with MCI, 20% meet criteria for major depression and 26% for minor depression. Symptoms often include sadness, poor concentration, inner tension, pessimistic thoughts, lassitude, and insomnia.18

Depressed MCI patients are at higher risk of developing dementia than those without depression, especially if cognitive measures do not improve after depression is treated.12 Similarly, cognitively intact older persons who develop depression are at increased risk for MCI, particularly if they carry the ApoE e4 genotype.19

In the only study in which MCI patients’ neuropsychiatric symptoms have been treated, 39 elderly patients with depression and MCI received open-label sertraline, ≤200 mg/d, for 12 weeks. Among the 26 patients who completed the trial, 17 showed moderate improvement in depressive symptoms, attention, and executive function, and 9 showed no response.20

Recommendation. In clinical practice, antidepressant treatment—usually a selective serotonin reuptake inhibitor (SSRI), with or without psychotherapy—is recommended for the MCI patient with comorbid major depression.

CASE CONTINUED: No signs of depression

Mr. R’s medical, neurologic, and substance use history is unremarkable. Family history includes AD in a paternal aunt diagnosed at age 82. Mr. R reports no history of mood, sleep, or appetite changes and no psychotic symptoms. He shows no deficits in activities of daily living (ADL), although his wife recently took over paying household bills after he forgot to make a payment.

Evidence-based workup

Functional assessment. In the differential diagnosis of MCI, give special attention to functional impairment, which points toward dementia. ADL generally are preserved in MCI, and minimal deterioration is seen in instrumental activities of daily living (IADL). A relatively easy way to assess function is to use the Alzheimer’s Disease Functional Assessment and Change Scale (ADFACS), which is based on 16 ADL and IADL items (Table 4).21

 

 

A substantial functional decline precludes an MCI diagnosis, although the degree of functional decline can be difficult to assess in older adults with physical limitations caused by medical comorbidities.

Cognitive assessment. Because most individuals with MCI score in the normal range on the Folstein Mini-Mental State Examination (MMSE), the modified MMSE (3MS)22 may be more sensitive for detecting MCI. The 3MS retains the MMSE’s brevity (≤10 minutes to administer) but incorporates 4 additional items, has more graded scoring responses, and broadens the score range to 0 to 100. The clock-drawing test also is sensitive for MCI, especially in detecting early visuoconstructional dysfunction.

The Montreal Cognitive Assessment (MoCA) is a 10-minute, 30-point scale designed to help clinicians detect MCI (see Related Resources). The MoCA usually is given with the modified MMSE for a comprehensive cognitive assessment.

Nasreddine et al23 administered the MoCA and MMSE to 94 patients who met clinical criteria for MCI, 93 patients with mild AD, and 90 healthy cognitively normal elderly persons, using a cutoff score of 26. MoCA showed:

  • 90% sensitivity for detecting MCI (compared with 18% for the MMSE)
  • 87% specificity to exclude normal elderly persons.
The average MoCA score in patients with AD was much lower than in individuals with MCI, but score ranges of these 2 groups overlapped. Therefore, a score

Neuropsychological testing can be more sensitive than office-based screening tools in defining MCI subtypes. In the Alzheimer’s Disease Cooperative Study (ADCS), the neuropsychological measures that most accurately predicted progression of patients with aMCI to AD within 36 months were the:

  • Symbol Digit Modalities Test
  • New York University Paragraph Recall Test (Delayed)
  • Delayed 10-Word List Recall
  • Alzheimer’s Disease Assessment Scale-cognitive subscale (ADAS-Cog) total score.24
Laboratory tests, imaging. Use laboratory studies (Table 5) to rule out reversible causes of MCI symptoms.8 Reserve CSF studies for suspected CNS infection (such as meningitis, human immunodeficiency virus, or neurosyphilis) and brain imaging for suspected cerebral pathology (such as infarct, subdural hematoma, normal pressure hydrocephalus, or tumor).

Table 4

Alzheimer’s Disease Functional Assessment and Change Scale (ADFACS)

Basic ADLInstrumental ADL (IADL)
ToiletingUse of telephone
FeedingHousehold tasks
DressingUsing household appliances
Personal hygiene and groomingManaging money
 Shopping
BathingFood preparation
WalkingAbility to get around inside and outside home
 Hobbies and leisure activities
 Handling personal mail
 Grasp of situations and explanations
The 16-item ADFACS total score ranges from 0 to 54 (best to worst):
  • Rate basic ADLs from 0 (no impairment) to 4 (very severe impairment), for a total score range of 0 to 24.
  • Rate IADLs from 0 (no impairment) to 3 (severe impairment), for a total score range of 0 to 30.
Use total scores to assess for functional decline from baseline. A decline from 0 to 1 on individual ADL and IADL items is not considered clinically significant.
ADL: activities of daily living
Source: Reprinted with permission from reference 21
Table 5

Lab studies to rule out reversible causes of MCI

Complete blood count with differential
Basic metabolic panel
Liver function tests
Serum calcium
Serum vitamin B12 and folate
Thyroid function tests
Rapid plasma reagin
HIV in high-risk individuals
CSF studies if CNS infection is suspected
CSF: cerebrospinal fluid; HIV: human immunodeficiency virus; MCI: mild cognitive impairment
Source: Reference 8

CASE CONTINUED: Subtle cognitive deficits

Mr. R scores 27/30 on the MMSE (losing 3 points on recall) and 25/30 on the MoCA (losing points on visuospatial/executive function, fluency, and delayed recall). Thyroid stimulating hormone, vitamin B12, folate, and rapid plasma reagin tests are unremarkable; brain MRI shows no significant abnormalities.

You refer Mr. R for neuropsychological testing, and most cognitive domains are normal. Exceptions include moderate impairment in immediate and delayed verbal and visual memory and mild executive dysfunction.

Based on your clinical evaluation and neuropsychological testing, you diagnose amnestic MCI. Mr. R shows abnormalities in memory and executive functioning without significant decline in basic and instrumental ADLs, is not taking medications, and has no other medical or psychiatric condition that could explain his cognitive deficits.

You discuss the diagnosis with him and his wife, including evidence on his risk for progression to dementia, neuroprotective strategies, and medications.

After an MCI diagnosis

Neuroprotection. Eliminate medications with anticholinergic effects, including:

  • tricyclic antidepressants
  • conventional antipsychotics
  • antihistamines
  • drugs used to treat urinary incontinence, such as oxybutynin
  • muscle relaxants, such as cyclobenzaprine
  • certain antiparkinsonian drugs, such as benztropine.
Encourage patients to avoid alcohol and sedatives. Collaborate with primary care providers to control cerebrovascular risk factors such as hyperlipidemia, diabetes mellitus, hypertension, and obesity. Treat depression, which may be a risk factor for developing dementia.
 

 


Monitoring. The American Academy of Neurology recommends monitoring patients diagnosed with MCI every 6 to 12 months for cognitive and functional decline.

In these visits, include:

  • repeat office-based cognitive assessment, especially the modified MMSE, clock-drawing test, and MoCA
  • careful history-taking from the patient and reliable informant
  • repeat neuropsychological testing annually or when dementia is suspected
  • assessment of the caregiver for distress.
Compensating for memory loss. Many individuals with MCI have insight into their cognitive deficits and are interested in making lifestyle changes. Experts recommend:

  • moderate exercise (at least 30 minutes per session, 3 times a week)
  • cognitively stimulating activities that involve language and psychomotor coordination, such as dancing, crossword puzzles, and volunteer work.
Potentially helpful tools include calendars, reminder notes, electronic cuing devices, pill boxes, and “speed-dial” telephones. Encourage patients to participate in local senior organizations and to use community resources.1

Medications—yes or no? Cholinesterase inhibitors, rofecoxib, and vitamin E have not been shown to prevent MCI from progressing to AD. Thus, insufficient evidence exists to recommend medications for patients with MCI.

Donepezil has shown possible short-term benefits, however, and patients may choose to try this medication. Some find comfort in seeking this “extra time” to make decisions about advanced directives, attend to estate and will issues, and optimize relationships while they have only mild cognitive deficits and possess decision-making capacity.

Donepezil. The Alzheimer’s Disease Cooperative Study—supported by the National Institute on Aging—was designed to determine whether daily doses of donepezil or vitamin E can delay or prevent progression of aMCI to AD.25 In the double-blind, placebo-controlled, parallel group study, 769 patients with aMCI were randomly assigned to receive donepezil, 10 mg/d; vitamin E, 1,000 IU bid; or placebo for 3 years.

Overall progression to AD was 16% per year, and the 3-year risk of progression was the same in all 3 groups. Donepezil therapy was associated with a reduced rate of progression to AD compared with placebo during the first year of treatment. Donepezil’s benefit was evident among ApoE e4 carriers at 2-year follow-up, but none of the 3 groups showed statistically significant differences after 3 years. Vitamin E showed no effect on AD progression throughout the study.

Rivastigmine. A randomized, placebo-controlled trial in which 1,018 MCI patients received rivastigmine or placebo for 4 years found no statistically significant benefit of rivastigmine on AD progression.26

Galantamine. Two international randomized, double-blind, placebo-controlled trials failed to show a statistically significant benefit of galantamine in slowing progression from aMCI to AD. MRI data from one of these studies suggested that galantamine may have reduced the rate of brain atrophy over a 2-year period.27

Rofecoxib. Epidemiologic studies indicate that anti-inflammatory drugs may reduce the risk of developing AD, but the COX-2 inhibitor rofecoxib did not delay progression to AD among aMCI patients in a large, placebo-controlled trial.28

Educate patients and family members about supportive nonpharmacologic treatments and cholinesterase inhibitors. The Alzheimer’s Association, National Institute on Aging, and local department of aging agencies offer useful resources (see Related Resources).

CASE CONTINUED: Dealing with uncertainty

Mr. R and his wife are unsettled by his MCI diagnosis. They prefer to take a “wait and watch” approach, decline initiation of a cholinesterase inhibitor, and agree to adhere to nonpharmacologic interventions you discussed. You schedule a follow-up visit in 6 months and encourage them to call you with questions.

Related resources

  • Rosenberg PB, Johnston D, Lyketsos CG. A clinical approach to mild cognitive impairment. Am J Psychiatry 2006;163: 1884-90.
  • Montreal Cognitive Assessment (MoCA). 10-minute screening test designed to help clinicians detect mild cognitive impairment. www.mocatest.org.
  • Alzheimer’s Association. www.alz.org.
  • National Institute on Aging. www.nia.nih.gov.
Drug brand name

  • Benztropine • Cogentin
  • Cyclobenzaprine • Flexeril
  • Donepezil • Aricept
  • Galantamine • Razadyne
  • Oxybutynin • Ditropan
  • Rivastigmine • Exelon
  • Rofecoxib • Vioxx
  • Sertraline • Zoloft
Disclosure

Dr. Goveas and Dr. Dixon-Holbrook report no financial relationship with any company whose products are mentioned in this article or with manufacturers of competing products.

Dr. Kerwin is a consultant to Pfizer and a speaker for Pfizer and Novartis.

Dr. Antuono receives research support from Eisai, Pfizer, and Elan and is a speaker for Pfizer and Forest Pharmaceuticals.

References

1. Gauthier S, Reisberg B, Zaudig M, et al. Mild cognitive impairment. Lancet 2006;367:1262-70.

2. Lopez OL, Jagust WJ, DeKosky ST, et al. Prevalence and classification of mild cognitive impairment in the Cardiovascular Health Study Cognition Study: part 1. Arch Neurol 2003;60:1385-9.

3. Petersen RC. Conceptual review. In: Petersen RC, ed. Mild cognitive impairment: aging to Alzheimer’s disease. New York, NY: Oxford University Press; 2003:1-14.

4. Petersen RC, Morris JC. Mild cognitive impairment as a clinical entity and treatment target. Arch Neurol 2005;62:1160-3.

5. O’Brien JT. Vascular cognitive impairment. Am J Geriatr Psychiatry 2006;14:724-33.

6. Janvin CC, Larsen JP, Aarsland D, et al. Subtypes of mild cognitive impairment in Parkinson’s disease: progression to dementia. Mov Disord 2006;21:1343-9.

7. Farlow MR, He Y, Tekin S, et al. Impact of APOE in mild cognitive impairment. Neurology 2004;63:1898-1901.

8. Winblad B, Palmer K, Kivipelto M, et al. Mild cognitive impairment—beyond controversies, towards a consensus: report of the International Working Group on Mild Cognitive Impairment. J Intern Med 2004;256:240-6.

9. Petersen RC. Mild cognitive impairment as a diagnostic entity. J Intern Med 2004;256:183-94.

10. Geda YE, Smith GE, Knopman DS, et al. De novo genesis of neuropsychiatric symptoms in mild cognitive impairment (MCI). Int Psychogeriatr 2004;16:51-60.

11. Robert PH, Berr C, Volteau M, et al. Apathy in patients with mild cognitive impairment and the risk of developing dementia of Alzheimer’s disease: a one-year follow-up study. Clin Neurol Neurosurg 2006;108:733-6.

12. Modrego PJ, Ferrandez J. Depression in patients with mild cognitive impairment increases the risk of developing dementia of Alzheimer type. Arch Neurol 2004;61:1290-3.

13. Jack CR, Petersen RC, Xu YC, et al. Prediction of AD with MRI-based hippocampal volume in mild cognitive impairment. Neurology 1999;52:1397-1403.

14. Nestor PJ, Fryer TD, Smielewski P, et al. Limbic hypometabolism in Alzheimer’s disease and mild cognitive impairment. Ann Neurol 2003;54:343-51.

15. Sunderland T, Hampel H, Takeda M, et al. Biomarkers in the diagnosis of Alzheimer’s disease: are we ready? J Geriatr Psychiatry Neurol 2006;19:172-9.

16. Lyketsos CG, Lopez O, Jones B, et al. Prevalence of neuropsychiatric symptoms in dementia and mild cognitive impairment: results from the Cardiovascular Health Study. JAMA 2002;288:1475-83.

17. Steffens DC, Otey E, Alexoupolos GS, et al. Perspectives on depression, mild cognitive impairment, and cognitive decline. Arch Gen Psychiatry 2006;63:130-8.

18. Gabryelewicz T, Styczynska M, Pfeffer A, et al. Prevalence of major and minor depression in elderly persons with mild cognitive impairment: MADRS factor analysis. Int J Geriatr Psychiatry 2004;19:1168-72.

19. Geda YE, Knopman DS, Mrazek DA, et al. Depression, apolipoprotein E genotype, and the incidence of mild cognitive impairment: a prospective cohort study. Arch Neurol 2006;63:435-40.

20. Devanand DP, Pelton GH, Marston K, et al. Sertraline treatment of elderly patients with depression and cognitive impairment. Int J Geriatr Psychiatry 2003;18:123-30.

21. Mohs RC, Doody RS, Morris JC, et al. A 1-year, placebo-controlled preservation of function survival study of donepezil in AD patients. Neurology 2001;57:481-8.

22. Teng EL, Chui HC. The Modified Mini-Mental State (3MS) examination. J Clin Psychiatry 1987;48:314-8.

23. Nasreddine ZS, Phillips NA, Bédirian V, et al. The Montreal Cognitive Assessment (MoCA): a brief screening tool for mild cognitive impairment. J Am Geriatr Soc 2005;53:695-9.

24. Fleisher AS, Sowell BB, Taylor C, et al. Clinical predictors of progression to Alzheimer disease in amnestic mild cognitive impairment. Neurology 2007;68:1588-95.

25. Petersen RC, Thomas RG, Grundman M, et al. for the Alzheimer’s Disease Cooperative Study Group. Vitamin E and donepezil for the treatment of mild cognitive impairment. N Engl J Med 2005;352:2379-88.

26. Feldman HH, Ferris S, Winblad B, et al. Effect of rivastigmine on delay to diagnosis of Alzheimer’s disease from mild cognitive impairment: the InDDEx study. Lancet Neurol 2007;6:501-12.

27. Petersen RC. Mild cognitive impairment: current research and clinical implications. Semin Neurol 2007;27:22-31.

28. Thal LJ, Ferris SH, Kirby L, et al. A randomized, double-blind study of rofecoxib in patients with mild cognitive impairment. Neuropsychopharmacology 2005;30(6):1204-15.

References

1. Gauthier S, Reisberg B, Zaudig M, et al. Mild cognitive impairment. Lancet 2006;367:1262-70.

2. Lopez OL, Jagust WJ, DeKosky ST, et al. Prevalence and classification of mild cognitive impairment in the Cardiovascular Health Study Cognition Study: part 1. Arch Neurol 2003;60:1385-9.

3. Petersen RC. Conceptual review. In: Petersen RC, ed. Mild cognitive impairment: aging to Alzheimer’s disease. New York, NY: Oxford University Press; 2003:1-14.

4. Petersen RC, Morris JC. Mild cognitive impairment as a clinical entity and treatment target. Arch Neurol 2005;62:1160-3.

5. O’Brien JT. Vascular cognitive impairment. Am J Geriatr Psychiatry 2006;14:724-33.

6. Janvin CC, Larsen JP, Aarsland D, et al. Subtypes of mild cognitive impairment in Parkinson’s disease: progression to dementia. Mov Disord 2006;21:1343-9.

7. Farlow MR, He Y, Tekin S, et al. Impact of APOE in mild cognitive impairment. Neurology 2004;63:1898-1901.

8. Winblad B, Palmer K, Kivipelto M, et al. Mild cognitive impairment—beyond controversies, towards a consensus: report of the International Working Group on Mild Cognitive Impairment. J Intern Med 2004;256:240-6.

9. Petersen RC. Mild cognitive impairment as a diagnostic entity. J Intern Med 2004;256:183-94.

10. Geda YE, Smith GE, Knopman DS, et al. De novo genesis of neuropsychiatric symptoms in mild cognitive impairment (MCI). Int Psychogeriatr 2004;16:51-60.

11. Robert PH, Berr C, Volteau M, et al. Apathy in patients with mild cognitive impairment and the risk of developing dementia of Alzheimer’s disease: a one-year follow-up study. Clin Neurol Neurosurg 2006;108:733-6.

12. Modrego PJ, Ferrandez J. Depression in patients with mild cognitive impairment increases the risk of developing dementia of Alzheimer type. Arch Neurol 2004;61:1290-3.

13. Jack CR, Petersen RC, Xu YC, et al. Prediction of AD with MRI-based hippocampal volume in mild cognitive impairment. Neurology 1999;52:1397-1403.

14. Nestor PJ, Fryer TD, Smielewski P, et al. Limbic hypometabolism in Alzheimer’s disease and mild cognitive impairment. Ann Neurol 2003;54:343-51.

15. Sunderland T, Hampel H, Takeda M, et al. Biomarkers in the diagnosis of Alzheimer’s disease: are we ready? J Geriatr Psychiatry Neurol 2006;19:172-9.

16. Lyketsos CG, Lopez O, Jones B, et al. Prevalence of neuropsychiatric symptoms in dementia and mild cognitive impairment: results from the Cardiovascular Health Study. JAMA 2002;288:1475-83.

17. Steffens DC, Otey E, Alexoupolos GS, et al. Perspectives on depression, mild cognitive impairment, and cognitive decline. Arch Gen Psychiatry 2006;63:130-8.

18. Gabryelewicz T, Styczynska M, Pfeffer A, et al. Prevalence of major and minor depression in elderly persons with mild cognitive impairment: MADRS factor analysis. Int J Geriatr Psychiatry 2004;19:1168-72.

19. Geda YE, Knopman DS, Mrazek DA, et al. Depression, apolipoprotein E genotype, and the incidence of mild cognitive impairment: a prospective cohort study. Arch Neurol 2006;63:435-40.

20. Devanand DP, Pelton GH, Marston K, et al. Sertraline treatment of elderly patients with depression and cognitive impairment. Int J Geriatr Psychiatry 2003;18:123-30.

21. Mohs RC, Doody RS, Morris JC, et al. A 1-year, placebo-controlled preservation of function survival study of donepezil in AD patients. Neurology 2001;57:481-8.

22. Teng EL, Chui HC. The Modified Mini-Mental State (3MS) examination. J Clin Psychiatry 1987;48:314-8.

23. Nasreddine ZS, Phillips NA, Bédirian V, et al. The Montreal Cognitive Assessment (MoCA): a brief screening tool for mild cognitive impairment. J Am Geriatr Soc 2005;53:695-9.

24. Fleisher AS, Sowell BB, Taylor C, et al. Clinical predictors of progression to Alzheimer disease in amnestic mild cognitive impairment. Neurology 2007;68:1588-95.

25. Petersen RC, Thomas RG, Grundman M, et al. for the Alzheimer’s Disease Cooperative Study Group. Vitamin E and donepezil for the treatment of mild cognitive impairment. N Engl J Med 2005;352:2379-88.

26. Feldman HH, Ferris S, Winblad B, et al. Effect of rivastigmine on delay to diagnosis of Alzheimer’s disease from mild cognitive impairment: the InDDEx study. Lancet Neurol 2007;6:501-12.

27. Petersen RC. Mild cognitive impairment: current research and clinical implications. Semin Neurol 2007;27:22-31.

28. Thal LJ, Ferris SH, Kirby L, et al. A randomized, double-blind study of rofecoxib in patients with mild cognitive impairment. Neuropsychopharmacology 2005;30(6):1204-15.

Issue
Current Psychiatry - 07(04)
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Current Psychiatry - 07(04)
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37-49
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37-49
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Mild cognitive impairment: How can you be sure?
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Mild cognitive impairment: How can you be sure?
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mild cognitive impairment; dementia; cognitive changes; Alzheimer’s disease; Parkinson’s disease; depression and cognitive complaints; Joseph S. Goveas MD; Meredith Dixon-Holbrook MD; Diana Kerwin MD; Piero Antuono MD;
Legacy Keywords
mild cognitive impairment; dementia; cognitive changes; Alzheimer’s disease; Parkinson’s disease; depression and cognitive complaints; Joseph S. Goveas MD; Meredith Dixon-Holbrook MD; Diana Kerwin MD; Piero Antuono MD;
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