Montreal Cognitive Assessment (MoCA)

Purpose

The Montreal Cognitive Assessment (MoCA) was designed as a rapid screeningTesting for disease in people without symptoms.
instrument for the detection of mild cognitive impairment. It was developed in response to the poor sensitivitySensitivity refers to the probability that a diagnostic technique will detect a particular disease or condition when it does indeed exist in a patient (National Multiple Sclerosis Society). See also “Specificity.”
of the Mini-Mental State Examination (MMSE) in distinguishing clients with mild cognitive impairment from normal elderly clients (Nasreddine et al., 2005). Thus, the MoCA is intended for clients with memory complaints who score within the normal range on the MMSE.

The MoCA assesses the following cognitive domains: attention and concentration, executive functions, memory, language, visuoconstructional skills, conceptual thinking, calculations, and orientation. The measure can be used, but is not limited to patients with strokeAlso called a “brain attack” and happens when brain cells die because of inadequate blood flow. 20% of cases are a hemorrhage in the brain caused by a rupture or leakage from a blood vessel. 80% of cases are also know as a “schemic stroke”, or the formation of a blood clot in a vessel supplying blood to the brain. More.

In-Depth Review

Purpose of the measure

The Montreal Cognitive Assessment (MoCA) was designed as a rapid screeningTesting for disease in people without symptoms.
instrument for the detection of mild cognitive impairment. It was developed in response to the poor sensitivitySensitivity refers to the probability that a diagnostic technique will detect a particular disease or condition when it does indeed exist in a patient (National Multiple Sclerosis Society). See also "Specificity."
of the Mini-Mental State Examination (MMSE) in distinguishing clients with mild cognitive impairment from normal elderly clients (Nasreddine et al., 2005). Thus, the MoCA is intended for clients with memory complaints who score within the normal range on the MMSE.

The MoCA assesses the following cognitive domains: attention and concentration, executive functions, memory, language, visuoconstructional skills, conceptual thinking, calculations, and orientation. The measure can be used, but is not limited to patients with strokeAlso called a "brain attack" and happens when brain cells die because of inadequate blood flow. 20% of cases are a hemorrhage in the brain caused by a rupture or leakage from a blood vessel. 80% of cases are also know as a "schemic stroke", or the formation of a blood clot in a vessel supplying blood to the brain. More.

Available versions

The Montreal Cognitive Assessment was developed by Dr Nasreddine in 1996, then validated with the help of Chertkow, Phillips, Whitehead, Bergman, Collin, Cummings, and Hébert in 2004-2005.

Features of the measure

Items:

The items of the MoCA examine attention and concentration, executive functions, memory, language, visuoconstructional skills, conceptual thinking, calculations, and orientation. These items are described in detail below.

Alternating Trail Making: The examiner instructs the client to “Please draw a line, going from a number to a letter in ascending order. Begin here” (points to 1) and draw a line from 1 then to A then to 2 and so on. End here (points to E).
Visuoconstructional Skills – Cube: The examiner gives the following instructions, pointing to the cube: “Copy this drawing as accurately as you can, in the space below“.
Visuoconstructional Skills – Clock: Indicate the right third of the test sheet where a space is provided for the clock drawing item, and give the following instructions: “Draw a clock. Put in all the numbers and set the time to 10 after 11“
Naming: Beginning on the left, point to each figure and say: “Tell me the name of this animal”
Memory: The examiner reads a list of 5 words at a rate of one per second, giving the following instructions: “This is a memory test. I am going to read a list of words that you will have to remember now and later on. Listen carefully. When I am through, tell me as many words as you can remember. It doesn’t matter in what order you say them“. Checkmark the space allocated for each word the client produces on the first trial on the test sheet. When the client indicates that he/she has finished (has recalled all the words), or can recall no more words, read the list a second time with the following instructions: “I am going to read the same list for a second time. Try to remember and tell me as many words as you can, including words you said the first time“. Put a checkmark in the allocated space for each word on the test sheet the client recalls after the second trial. At the end of the second trial, inform the client that she/he will be asked to recall these words again by saying, “I will ask you to recall those words again at the end of the test“
Attention:
- Forward Digit Span: Give the following instruction: “I am going to say some numbers and when I am through, repeat them to me exactly as I said them“. Read the five number sequences at a rate of one digit per second.
- Backward Digit Span: Give the following instruction: “Now I am going to say some more numbers, but when I am through you must repeat them to me in the backwards order“. Read the three number sequences at a rate of one digit per second.
- Vigilance: The examiner reads the list of letters at a rate of one per second, after giving the following instruction: “I am going to read a sequence of letters. Every time I say the letter A, tap you hand once. If I say a different letter, do not tap your hand“
- Serial 7s: The examiner gives the following instruction: “Now I will ask you to count by subtracting seven from 100, and then, keep subtracting seven from your answer until I tell you to stop“. Give this instruction twice if necessary.
Sentence Repetition: The examiner gives the following instructions: “I am going to read you a sentence. Repeat it after me, exactly as I say it [pause]. I only know that John is the one to help today.” Following the response say: “Now I am going to read you another sentence. Repeat it after me, exactly as I say it [pause]. The cat always hid under the couch when dogs were in the room“.
Verbal Fluency: The examiner gives the following instruction: “Tell me as many words as you can think of that begin with a certain letter of the alphabet that I will tell you in a moment. You can say any kind of word you want, except for proper nouns (like Bob or Boston), numbers, or words that begin with the same sound but have a different suffix, for example, love, lover, loving. I will tell you to stop after one minute. Are you ready? [pause]. Now, tell me as many words as you can beginning with the letter F” [time 60 seconds]. “Stop“
Abstraction: The examiner asks the client to explain what each pair of words has in common, starting with the example: “Tell me how an orange and a banana are alike“. If the subject answers in a concrete manner, then say only one additional time: “Tell me another way in which those items are alike“. If the client still doesn’t give the appropriate response (fruit), say “Yes, and they are also both fruit“. Do not give any additional instructions or clarification. After the practice trial say: “Now tell me how a train and a bicycle are alike“. Following the response, administer the second trial, saying: “Now, tell me how a ruler and a watch are alike“. Do not give any additional instructions or prompts
Delayed Recall:The examiner gives the following instruction: “I read some words to you earlier, which I asked you to remember. Tell me as many of those words as you can remember.” Make a checkmark on the test sheet for each of the words correctly recalled spontaneously without any cues, in the allocated space.
Optional: The client can be prompted with semantic category cues for any word that is not recalled. This is to elicit clinical information in order to provide the examiner with additional information regarding the type of memory disorder. For memory deficits due to retrieval failures, performance can be improved with a cue. For memory deficits due to encoding failures, performance does not improve with a cue. No points are awarded for words recalled from a cue.
Make a checkmark in the allocated space if they remembered the word with the help of a category cue. If not, give them a multiple choice cue.
See Also
MOCA-Peds Scoring | The American Board of Pediatrics Peds | The American Board of Pediatrics The MoCa (Montreal Cognitive Assessment) Test for Dementia Cognitive screening and assessment
Use the following category and/or multiple-choice cues for each word, when appropriate:
- FACE: category cue: part of the body multiple choice: nose, face, hand
- VELVET: category cue: type of fabric multiple choice: denim, cotton, velvet
- CHURCH: category cue: type of building multiple choice: church, school, hospital
- DAISY: category cue: type of flower multiple choice: rose, daisy, tulip
- RED: category cue: a color multiple choice: red, blue, green
Orientation: The examiner gives the following instructions: “Tell me the date today“. If the client does not give a complete answer, then prompt accordingly by saying: “Tell me the [year, month, exact date, and day of the week]“. Then say: “Now, tell me the name of this place, and which city it is in.”

Scoring:

Sum all subscores. Add one point for a client who has had 12 years or fewer of formal education, for a possible maximum of 30 points. A final total score of 26 and above is considered normal. A final total score below 26 is indicative of mild cognitive impairment.

Below is a breakdown of how each item of the MoCA is to be scored:

Item	How to score
Alternate Trail Making (1 point)	Give 1 point if the following pattern is drawn without drawing any lines that cross: 1-A-2-B-3-C-4-D-5-E. Any error that is not immediately self-corrected earns a score of 0.
Visuoconstructional skills Cube (1 point)	Give 1 point for a correctly executed drawing. Drawing must be 3D; all lines drawn; no lines added; lines are relatively parallel and lengths are similar (rectangular prisms are accepted). A point is not assigned if any of the above-criteria are not met.
Vosuoconstructional skills Clock (3 points)	Contour (1 point): The clock face must be a circle with only minor distortion acceptable (e.g. slight imperfection in closing the circle). Numbers (1 point): All clock numbers must be present with no additional numbers; numbers must be in correct order and placed in approximate quadrants on the clock face; roman numerals are accepted; numbers can be places outside the circle contour. Hands (1 point): There must be 2 hands jointly indicating the correct time; the hour hand must be clearly shorter than the minute hand; hands must be centered within the clock face with their junction close to the clock centre. A point is not assigned for a given element if any of the above-criteria are not met.
Naming (3 points)	One point each is given for the following responses: (1) camel/dromedary, (2) lion, (3) rhinoceros/rhino.
Memory (0 points)	No points are given for Trials 1 and 2.
Attention (6 points)	Digit span (2 points): Give 1 point for each sequence correctly repeated (the correct response for the backwards trial is 2-4-7). Vigilance (1 point): Give 1 point if there are 0-1 errors (an error includes a tap on a wrong letter, or a failure to tap on letter A). Serial 7s (3 points): This item is scored out of 3 points. Give 0 points for no correct subtractions; 1 point for 1 correct subtraction; 2 points for 2-3 correct subtractions; and 3 points if the client successfully makes 4-5 correct subtractions. Count each correct subtraction of 7 beginning at 100. Each subtraction is evaluated independently; that is, if the client responds with an incorrect number but continues to correctly subtract 7 from it, give a point for each correct subtraction. For example, a client may respond “92-85-78-71-64” where the “92” is incorrect, but all subsequent numbers are subtracted correctly. This is 1 error and the item would be given a score of 3.
Sentence Repetition (2 points)	Give 1 point for each sentence correctly repeated. Repetition must be exact. Be alert for errors that are omissions (e.g., omitting “only”, “always”) and substitutions/additions.
Verbal fluency (1 point)	Give 1 point if the 11 words or more are generated in 60 seconds. Record responses in the margins.
Abstraction (2 points)	Only the last 2 item pairs are scored. Give 1 point to each item pair correctly answered. The following responses are acceptable: Train-bicycle = means of transportation, means of traveling, you take trips in both Ruler-watch = measuring instruments, used to measure The following responses are not acceptable: Train-bicycle = they have wheels; Ruler-watch = they have numbers.
Delayed recall (5 points)	Give 1 point for each word recalled freely without any cues.
Orientation (6 points)	Give 1 point for each item correctly answered. The client must tell the exact date and place (name of hospital, clinic, office). No points are awarded if client makes an error of 1 day for the day and date.

Time:

The MoCA takes approximately 10-15 minutes to administer for clients with mild cognitive impairment.

Subscales:

Visuospatial/Executive; Naming; Memory; Attention; Language; Abstraction; Delayed recall; Orientation

Equipment:

Only the MoCA test sheet and a pencil are required to complete the measure.

Training:

The MoCA should be administered by a health professional. No formal training is required to administer the measure.

Alternative form of the MoCA

MoCA – version 2 & 3 (English)

Client suitability

Can be used with:

Patients with strokeAlso called a “brain attack” and happens when brain cells die because of inadequate blood flow. 20% of cases are a hemorrhage in the brain caused by a rupture or leakage from a blood vessel. 80% of cases are also know as a “schemic stroke”, or the formation of a blood clot in a vessel supplying blood to the brain. More.
The MoCA is suitable for any individual who is experiencing memory difficulties but who scores within the normal range on the Mini-Mental State Examination.

Should not be used with:

Because the MoCA is heavily language dependent, it is likely to misclassify patients with aphasiaAphasia is an acquired disorder caused by an injury to the brain and affects a person’s ability to communicate. It is most often the result of stroke or head injury.
An individual with aphasia may experience difficulty expressing themselves when speaking, difficulty understanding the speech of others, and difficulty reading and writing. Sadly, aphasia can mask a person’s intelligence and ability to communicate feelings, thoughts and emotions. (The Aphasia Institute, Canada).
The MoCA is not suitable for use with a proxy respondent as it is administered via direct observation of task completion.

In what languages is the measure available?

The MoCA has been translated into Arabic, Afrikaans, Chinese (Beijing, Cantonese, Changsha, Hong Kong, Taiwan), Czech, Croatian, Danish, Dutch, Estonian, French, Finnish, German, Greek, Hebrew, Italian, Japanese, Korean, Persian, Polish, Portuguese (Brazil), Russian, Serbian, Sinhalese, Spanish, Swedish, Thai, Turkish, Ukrainian and Vietnamese. These translations can be found at the following website: http://www.mocatest.org.

Summary

What does the tool measure?	Mild cognitive impairment
What types of clients can the tool be used for?	Can be used with but not limited to: •Patients with strokeAlso called a “brain attack” and happens when brain cells die because of inadequate blood flow. 20% of cases are a hemorrhage in the brain caused by a rupture or leakage from a blood vessel. 80% of cases are also know as a “schemic stroke”, or the formation of a blood clot in a vessel supplying blood to the brain. More •Any individual who is experiencing memory difficulties but scores within the normal range on the Mini Mental State Examination.
Is this a screeningTesting for disease in people without symptoms. or assessment tool?	ScreeningTesting for disease in people without symptoms.
Time to administer	The MoCA takes approximately 10-15 minutes to administer for clients with mild cognitive impairment.
Versions	MoCA (original); MoCA English (version 2); and MoCA English (version 3); MoCA (modified for individuals with visual impairments).
Other Languages	The MoCA has been translated into Arabic, Afrikaans, Chinese (Beijing, Cantonese, Changsha, Hong Kong, Taiwan), Czech, Croatian, Danish, Dutch, Estonian, French, Finnish, German, Greek, Hebrew, Italian, Japanese, Korean, Persian, Polish, Portuguese (Brazil), Russian, Serbian, Sinhalese, Spanish, Swedish, Thai, Turkish, Ukrainian and Vietnamese.
Measurement Properties
ReliabilityReliability can be defined in a variety of ways. It is generally understood to be the extent to which a measure is stable or consistent and produces similar results when administered repeatedly. A more technical definition of reliability is that it is the proportion of “true” variation in scores derived from a particular measure. The total variation in any given score may be thought of as consisting of true variation (the variation of interest) and error variation (which includes random error as well as systematic error). True variation is that variation which actually reflects differences in the construct under study, e.g., the actual severity of neurological impairment. Random error refers to “noise” in the scores due to chance factors, e.g., a loud noise distracts a patient thus affecting his performance, which, in turn, affects the score. Systematic error refers to bias that influences scores in a specific direction in a fairly consistent way, e.g., one neurologist in a group tends to rate all patients as being more disabled than do other neurologists in the group. There are many variations on the measurement of reliability including alternate-forms, internal consistency , inter-rater agreement , intra-rater agreement , and test-retest .	Internal consistencyA method of measuring reliability . Internal consistency reflects the extent to which items of a test measure various aspects of the same characteristic and nothing else. Internal consistency coefficients can take on values from 0 to 1. Higher values represent higher levels of internal consistency. More: Only one study has examined the internal consistencyA method of measuring reliability . Internal consistency reflects the extent to which items of a test measure various aspects of the same characteristic and nothing else. Internal consistency coefficients can take on values from 0 to 1. Higher values represent higher levels of internal consistency. More of the MoCA and reported excellent levels of internal consistencyA method of measuring reliability . Internal consistency reflects the extent to which items of a test measure various aspects of the same characteristic and nothing else. Internal consistency coefficients can take on values from 0 to 1. Higher values represent higher levels of internal consistency. More. Test-rest: Only one study has examined the test-rest reliabilityReliability can be defined in a variety of ways. It is generally understood to be the extent to which a measure is stable or consistent and produces similar results when administered repeatedly. A more technical definition of reliability is that it is the proportion of “true” variation in scores derived from a particular measure. The total variation in any given score may be thought of as consisting of true variation (the variation of interest) and error variation (which includes random error as well as systematic error). True variation is that variation which actually reflects differences in the construct under study, e.g., the actual severity of neurological impairment. Random error refers to “noise” in the scores due to chance factors, e.g., a loud noise distracts a patient thus affecting his performance, which, in turn, affects the score. Systematic error refers to bias that influences scores in a specific direction in a fairly consistent way, e.g., one neurologist in a group tends to rate all patients as being more disabled than do other neurologists in the group. There are many variations on the measurement of reliability including alternate-forms, internal consistency , inter-rater agreement , intra-rater agreement , and test-retest . of the MoCA, and reported excellent test-retest. Intra-rater: No studies have examined the intra-rater reliabilityThis is a type of reliability assessment in which the same assessment is completed by the same rater on two or more occasions. These different ratings are then compared, generally by means of correlation. Since the same individual is completing both assessments, the rater’s subsequent ratings are contaminated by knowledge of earlier ratings. of the MoCA. Inter-rater: No studies have examined the inter-rater reliabilityA method of measuring reliability . Inter-rater reliability determines the extent to which two or more raters obtain the same result when using the same instrument to measure a concept. of the MoCA.
ValidityThe degree to which an assessment measures what it is supposed to measure.	Criterion: Concurrent: Excellent correlations with the Mini Mental State Examination (MMSE) have been reported. Construct: Known groups: One study reported that the MoCA can distinguish between patients with mild cognitive impairment and healthy controls.
Floor/Ceiling Effects	No studies have examined the ceiling or floor effects of the MoCA.
Does the tool detect change in patients?	Not Applicable.
Acceptability	The MoCA is not suitable for individuals with aphasiaAphasia is an acquired disorder caused by an injury to the brain and affects a person’s ability to communicate. It is most often the result of stroke or head injury. An individual with aphasia may experience difficulty expressing themselves when speaking, difficulty understanding the speech of others, and difficulty reading and writing. Sadly, aphasia can mask a person’s intelligence and ability to communicate feelings, thoughts and emotions. (The Aphasia Institute, Canada) or for use with a proxy respondent
Feasibility	The measure is simple to score and only the MoCA test sheet and a pencil are required to complete the measure.
How to obtain the tool?	The MoCA is available at: http://www.mocatest.org.

Psychometric Properties

Overview

We conducted a literature search to identify all relevant publications on the psychometric properties of the MoCA. As the MoCA is a relatively new measure, to our knowledge, the creators have personally gathered the majority of psychometric data that are currently published on the scale.

Reliability

Internal consistencyA method of measuring reliability . Internal consistency reflects the extent to which items of a test measure various aspects of the same characteristic and nothing else. Internal consistency coefficients can take on values from 0 to 1. Higher values represent higher levels of internal consistency. More:
Nasreddine et al. (2005) examined the internal consistencyA method of measuring reliability . Internal consistency reflects the extent to which items of a test measure various aspects of the same characteristic and nothing else. Internal consistency coefficients can take on values from 0 to 1. Higher values represent higher levels of internal consistency. More of the MoCA and reported an excellent Cronbach’s alpha (alpha = 0.83) on the standardized items.

Test-retest:
Nasreddine et al. (2005) examined the test-retest reliabilityA way of estimating the reliability of a scale in which individuals are administered the same scale on two different occasions and then the two scores are assessed for consistency. This method of evaluating reliability is appropriate only if the phenomenon that the scale measures is known to be stable over the interval between assessments. If the phenomenon being measured fluctuates substantially over time, then the test-retest paradigm may significantly underestimate reliability. In using test-retest reliability, the investigator needs to take into account the possibility of practice effects, which can artificially inflate the estimate of reliability (National Multiple Sclerosis Society).
of the MoCA by administering the measure to a subsample of 26 clients (clients with mild cognitive impairment or Alzheimer’s disease, and healthy elderly controls) twice, on average 35 days apart. The correlationThe extent to which two or more variables are associated with one another. A correlation can be positive (as one variable increases, the other also increases - for example height and weight typically represent a positive correlation) or negative (as one variable increases, the other decreases - for example as the cost of gasoline goes higher, the number of miles driven decreases. There are a wide variety of methods for measuring correlation including: intraclass correlation coefficients (ICC), the Pearson product-moment correlation coefficient, and the Spearman rank-order correlation.
between the two evaluations was excellent (r = 0.92). The mean change in MoCA scores from the first to second evaluation was 0.9 points.

Validity

Criterion:

Concurrent:
Nasreddine et al. (2005) administered the MoCA and the Mini Mental State Examination to 94 patients with mild cognitive impairment, 93 patients with mild Alzheimer’s disease, and 90 healthy elderly controls. The correlationThe extent to which two or more variables are associated with one another. A correlation can be positive (as one variable increases, the other also increases - for example height and weight typically represent a positive correlation) or negative (as one variable increases, the other decreases - for example as the cost of gasoline goes higher, the number of miles driven decreases. There are a wide variety of methods for measuring correlation including: intraclass correlation coefficients (ICC), the Pearson product-moment correlation coefficient, and the Spearman rank-order correlation.
between the MoCA and the MMSE was excellent (r = 0.87).

Sensitivity and Specificity

Four studies examined whether the MoCA could detect patients known to have varying degrees of cognitive impairment and found the MoCA to be more sensitive than the Mini-Mental State Examination (MMSE) in detecting these differences.

Nasreddine et al. (2005) examined whether the MoCA could distinguish between patients with mild cognitive impairment and healthy controls. The DSM-IV and NINCDS-ADRDA criteria were used to establish diagnosis of Alzheimer’s disease and neurological assessments performed by neurologists and geriatricians were used to establish diagnosis of cognitive impairment. At a cutoff score of 26, the MoCA had a sensitivitySensitivity refers to the probability that a diagnostic technique will detect a particular disease or condition when it does indeed exist in a patient (National Multiple Sclerosis Society). See also "Specificity."
in identifying clients with mild cognitive impairment and clients with Alzheimer’s disease of 90% and 100%, respectively, and a specificitySpecificity refers to the probability that a diagnostic technique will indicate a negative test result when the condition is absent (true negative).
of 87%. The MoCA’s sensitivitySensitivity refers to the probability that a diagnostic technique will detect a particular disease or condition when it does indeed exist in a patient (National Multiple Sclerosis Society). See also "Specificity."
in detecting mild cognitive impairment was considerably more sensitive than was the Mini-Mental State Examination (MMSE) (the sensitivitySensitivity refers to the probability that a diagnostic technique will detect a particular disease or condition when it does indeed exist in a patient (National Multiple Sclerosis Society). See also "Specificity."
of the MMSE was poor: 18% for patients with mild cognitive impairment; 78% for patients with Alzheimer’s disease).

Smith, Gildeh and Holmes (2007) evaluated whether the MoCA could detect mild cognitive impairment and dementia in patients attending a memory clinic. Dementia and mild cognitive impairment were diagnosed by neuropsychological assessment involving the ICD-10 criteria and CAMCOG scores. At a cutoff score of 26, the MoCA was found to have excellent sensitivitySensitivity refers to the probability that a diagnostic technique will detect a particular disease or condition when it does indeed exist in a patient (National Multiple Sclerosis Society). See also "Specificity."
for detecting mild cognitive impairment (83%) and dementia (94%), but poor specificitySpecificity refers to the probability that a diagnostic technique will indicate a negative test result when the condition is absent (true negative).
(50% for both mild cognitive impairment and dementia). The specificitySpecificity refers to the probability that a diagnostic technique will indicate a negative test result when the condition is absent (true negative).
was lower than that identified in the earlier study by Nasreddine et al. (2005), likely due to the heterogeneous nature of the control group. The MoCA was also found to be more sensitive than the MMSE (the sensitivitySensitivity refers to the probability that a diagnostic technique will detect a particular disease or condition when it does indeed exist in a patient (National Multiple Sclerosis Society). See also "Specificity."
of the MMSE was poor: 17% for patients with mild cognitive impairment and 25% for patients with dementia).

Luis, Keegan and Mullan (2009) examined whether the MoCA could distinguish between healthy controls and patients with Alzheimer’s disease or mild cognitive impairment. A diagnosis of Alzheimer’s disease was made by neuropsychological assessment using NINCDS-ADRDA criteria and mild cognitive impairment (MCI) by Petersen’s criteria (Petersen et al., 1999 as cited in Luis, Keegan & Mullan, 2009). At a cutoff score of 26, the MoCA was found to have excellent sensitivitySensitivity refers to the probability that a diagnostic technique will detect a particular disease or condition when it does indeed exist in a patient (National Multiple Sclerosis Society). See also "Specificity."
for detecting MCI (100%) and Alzheimer’s disease and MCI combined (97%), with a poor specificitySpecificity refers to the probability that a diagnostic technique will indicate a negative test result when the condition is absent (true negative).
(35% for both groups of MCI and Alzheimer’s disease+MCI). A cutoff score of 23 was found to be optimal for identifying MCI, providing excellent sensitivitySensitivity refers to the probability that a diagnostic technique will detect a particular disease or condition when it does indeed exist in a patient (National Multiple Sclerosis Society). See also "Specificity."
and specificitySpecificity refers to the probability that a diagnostic technique will indicate a negative test result when the condition is absent (true negative).
, 96% and 95% respectively. The MoCA was found to be more sensitive than the MMSE (at a cut-off score of ≤ 24, MMSE sensitivitySensitivity refers to the probability that a diagnostic technique will detect a particular disease or condition when it does indeed exist in a patient (National Multiple Sclerosis Society). See also "Specificity."
for detecting MCI and Alzheimer’s disease+MCI was 17% and 36% respectively).

Dong et al. (2010) evaluated the sensitivitySensitivity refers to the probability that a diagnostic technique will detect a particular disease or condition when it does indeed exist in a patient (National Multiple Sclerosis Society). See also "Specificity."
and specificitySpecificity refers to the probability that a diagnostic technique will indicate a negative test result when the condition is absent (true negative).
of an alternative language version of the MoCA for detecting vascular cognitive impairment and dementia after strokeAlso called a "brain attack" and happens when brain cells die because of inadequate blood flow. 20% of cases are a hemorrhage in the brain caused by a rupture or leakage from a blood vessel. 80% of cases are also know as a "schemic stroke", or the formation of a blood clot in a vessel supplying blood to the brain. More. Patients underwent neuro-imaging and neuropsychological assessment in order to establish a diagnosis of cognitive impairment or dementia using the DSM-IV criteria. Using an optimum cutoff score of 21, the MoCA correctly identified 90% of patients with cognitive impairment (excellent sensitivitySensitivity refers to the probability that a diagnostic technique will detect a particular disease or condition when it does indeed exist in a patient (National Multiple Sclerosis Society). See also "Specificity."
) and 77% of those without cognitive impairment (adequate specificitySpecificity refers to the probability that a diagnostic technique will indicate a negative test result when the condition is absent (true negative).
). The MoCA was also found to be more sensitive than the MMSE (MMSE sensitivitySensitivity refers to the probability that a diagnostic technique will detect a particular disease or condition when it does indeed exist in a patient (National Multiple Sclerosis Society). See also "Specificity."
of 86% and specificitySpecificity refers to the probability that a diagnostic technique will indicate a negative test result when the condition is absent (true negative).
of 82% for detecting cognitive impairment).

In a population-based study of 413 patients with strokeAlso called a "brain attack" and happens when brain cells die because of inadequate blood flow. 20% of cases are a hemorrhage in the brain caused by a rupture or leakage from a blood vessel. 80% of cases are also know as a "schemic stroke", or the formation of a blood clot in a vessel supplying blood to the brain. More or TIA, the MoCA was found to detect more cognitive deficits than the MMSE. For the purposes of the study, a score of ≥ 27 on the MMSE was used to classify patients as having normal cognitive function, and < 26 on the MoCA to classify mild cognitive impairment (no formal neuropsychological testing was performed to confirm diagnosis). 58% of patients with normal MMSE scores (≥ 27) were found to have scores indicative of mild cognitive impairment when the MoCA was used for screeningTesting for disease in people without symptoms.
(<26). Several of the deficits detected by the MoCA were in domains either not assessed or detected by the MMSE, including executive function and attention (not assessed) and recall and repetition (not detected) (Pendlebury, Cuthbertson, Welch, Mehta & Rothwell, 2010). SensitivitySensitivity refers to the probability that a diagnostic technique will detect a particular disease or condition when it does indeed exist in a patient (National Multiple Sclerosis Society). See also "Specificity."
and specificitySpecificity refers to the probability that a diagnostic technique will indicate a negative test result when the condition is absent (true negative).
of the MoCA for cognitive impairment could not be established in the study because no formal neuropsychological testing was performed to confirm diagnosis.

Responsiveness

Koski, Xie and Finch (2009) evaluated the MoCA as a quantitative measure of cognitive ability and its responsivenessThe ability of an instrument to detect clinically important change over time.
. By applying Rasch analysisRasch analysis is a statistical measurement method that allowsthe measurement of an attribute – such as upper limb function – independently of particular tests or indices.Â ÂIt creates a linear representationÂusing many individual items, ranked byÂitem difficulty (e.g. picking up a very small item, versus a task requiring a very gross grasp) and person ability.ÂÂÂA well performing Rasch model will have items hierarchically placed from simple to more difficult, and individuals with high abilities should be able to perform all the items below a level of difficulty.Â The Rasch model is statistically strong because it enables ordinal measures to be converted into meaningful interval measures. It also allows information fromÂvarious tests or tools with different scoring systems to be appliedusing the Rasch model.
techniques to existing data from a geriatric outpatient clinic, the researchers found that in addition to the usefulness of the MoCA as a screeningTesting for disease in people without symptoms.
instrument, scores on the MoCA can be used to quantify the amount of cognitive ability a person has and can be used to track changes in cognitive ability over time. The significance of scores and change in scores can be interpreted based on the respondent’s baseline score, for example, a 5-point decrease from a baseline score of 25 is a more statistically significant and meaningful change than that of a 5-point decrease from a baseline score of 15 (please refer to Table 4 in Koski et al., 2009 for statistical significance of change in MoCA scores). Further research to determine the minimal clinically important difference is required.

References

Dong, Y.H., Sharma, V.K., Chan, B.P.L., Venketasubramanian, N., Teoh, H.L., Seet, R.C.S., Tanicala, S., Chan, Y.H. & Chen, C. (2010). The Montreal Cognitive Assessment (MoCA) is superior to the Mini-Mental State Examination (MMSE) for the detection of vascular cognitive impairment after acute stroke. Journal of Neurological Sciences. doi:10.1016/j.jns.2010.08.051
Koski, L., Xie, H. & Finch, L. (2009). Measuring cognition in a geriatric outpatient clinic: Rasch analysis of the Montreal Cognitive Assessment. Journal of Geriatric Psychiatry and Neurology, 22, 151-160.
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See the measure

How to obtain the MoCA?

The MoCA is available at: http://www.mocatest.org.

Montreal Cognitive Assessment (MoCA) – Strokengine (2024)