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Written Verbal Fluency Test
Written Verbal Fluency Test
Please email the authors for information about obtaining the instrument:
Core: Amyotrophic Lateral Sclerosis (ALS)
Supplemental: Huntington's Disease (HD)
Exploratory: Unruptured Cerebral Aneurysm and Subarachnoid Hemorrhage (SAH)
|Short Description of Instrument||
Summary/Overview of Instrument: The test is an adaptation of the Thurstone's Word Fluency Test (Thurstone and Thurstone, 1962) which together with other spoken word fluency tests has been shown to be sensitive to frontal lobe lesions. This test was adapted to control for motor speed for use with patients with upper limb disability with the incorporation of a copy condition. The test has been shown to be independent of physical disability.
The participant is required to verbally generate items from a given semantic category. The most frequently used category is animals; however, other categories used include: fruits and vegetables, items of clothing, things found in a supermarket.
Construct measured: Generation, executive function, semantic knowledge.
Generic vs. disease specific: Generic.
Intended use of instrument/purpose of tool (cross-sectional, longitudinal, diagnostic, etc): The category fluency task is a measure of fluency in verbal generation of semantic category members. It may be used as a longitudinal marker of disease severity in manifest/premanifest HD or as a cross-sectional measure of cognitive impairment across disease stages or between manifest/premanifest HD and healthy controls.
Means of administration (paper and pencil, computerized): Verbal (responses recorded on paper verbatim for later scoring if needed).
Location of administration (clinic, home, telephone, etc): Clinic.
Intended respondent (patient, caregiver, etc.): Patient.
# of items: N/A.
# of subscales and names of sub-scales: N/A.
The score is the total number of correct items produced in one minute. Error responses (e.g. perseverations, intrusions) are often also recorded.
Standardization of scores to a reference population (z scores, T scores, etc):
Normative data, stratified by age and education level are available for the general population (Tombaugh et al., 1999).
If scores have been standardized to a reference population, indicate frame of reference for scoring (general population, HD subjects, other disease groups, etc).
Normative data are available for the general population.
Strengths: The adaptation to control for motor speed was designed for patients with ALS. The test has also been shown to be sensitive to frontal lobe dysfunction in ALS through functional and structural MRI studies.
Weaknesses: Requires further validation of properties and production of normative data. The full test is not suitable for patients with marked writing difficulties.
Feasibility: The test requires that the patient can write. Spoken versions of this test can be employed in patients with severe upper limb dysfunction.
Reliability: Has not been assessed.
Validity: The Written Verbal Fluency Index has been shown to be sensitive to frontal lobe dysfunction in ALS in functional imaging and structural imaging (Abrahams et al. 2004, 2005a. ). The index has also be found to correlate with ocular fixation abnormalities in ALS (Donaghy et al. 2009).
Sensitivity to Change: No change was reported over a 6 month period (Abrahams et al. 2005b).
Relationships to other variables: This measure was shown not to correlate with measures of emotional lability (Palmieri et al. 2009) or measures of disease duration or disability (Abrahams et al. 2000).
Language is one of the functions most frequently affected after SAH, with a highly variable prevalence of language impairment ranging from 0 – 76% (Al-Khindi et al., 2010). Most previous studies on language function after SAH have included the verbal fluency test in the battery of tests and assessments. In longitudinal studies, a further advantage of the verbal fluency test is that it is not subject to practice effects. For these reasons, the Swiss national standard of neuropsychological assessment after SAH includes the verbal fluency test (Zweifel-Zehnder et al., 2015; Stienen et al., 2015).
Test-retest or intra-interview (within rater) reliability (as applicable):
Inter-interview (between-rater) reliability (as applicable):
Statistical methods used to assess reliability:
Validity: Category fluency scores are moderately correlated with Phonemic Fluency scores (r=.52) (Tombaugh et al., 1999), another verbal generation task.
Sensitivity to Change/Ability to Detect Change (over time or in response to an intervention):
Meta-analysis of HD observational studies published between 1993-2007 reveals longitudinal change within pre-HD and manifest HD over time.
Pre-HD cross sectional:
Effect size = -0.11 (95% CI= -0.34, 0.12) based on 9 studies including 126 participants.
Effect size = -0.40 (95% CI= -0.99, 0.19) based on 1 study including 12 participants.
Manifest HD cross sectional:
Effect size = -1.34 (95% CI= -1.90, -0.78) based on 4 studies including 40 participants.
Manifest HD longitudinal:
Effect size = -0.50 (95% CI= -1.06, 0.06) based on 3 studies including 102 participants.
Known Relationships to Other Variables (e.g. gender, education, age, etc): Performance improves with years of education and decreases with age, with education accounting for 13.6% of variance and age 23.4% (Tombaugh et al, 1999).
Diagnostic Sensitivity and Specificity, if applicable (in general population, HD population- premanifest/ manifest, other disease groups): N/A.
Mitrushina, M.M., Boone, K.B., Razani, J., & D'Elia, L.F., (2005). Handbook of normative data for neuropsychological assessment (2nd ed.). New York: Oxford University Press.
Abrahams S, Leigh PN, Harvey A, Vythelingum GN, GrisÉ D, Goldstein LH. Verbal fluency and executive dysfunction in amyotrophic lateral sclerosis (ALS). Neuropsychologia. 2000;38(6):734–747
Tombaugh TN, Kozak J, Rees L. Normative data stratified by age and education for two measures of verbal fluency: FAS and animal naming. Arch Clin Neuropsychol. 1999;14(2):167–177.
Abrahams S, Goldstein LH, Al-Chalabi A, Pickering A, Morris RG, Passingham RE, Brooks DJ, Leigh PN. Relation between cognitive dysfunction and pseudobulbar palsy in amyotrophic lateral sclerosis. J Neurol Neurosurg Psychiatry. 1997;62(5):464–472.
Abrahams S, Goldstein LH, Suckling J, Ng V, Simmons A, Chitnis X, Atkins L, Williams SC, Leigh PN. Frontotemporal white matter changes in amyotrophic lateral sclerosis. J Neurol. 2005a Mar;252(3):321–331.
Abrahams S, Leigh PN, Goldstein LH. Cognitive change in ALS: a prospective study. Neurology. 2005;64(7):1222–1226.
SAH- specific references:
Al-Khindi T, Macdonald RL, Schweizer TA. Cognitive and functional outcome after aneurysmal subarachnoid hemorrhage. Stroke. 2010;41(8):e519–e536.
Stienen MN, Zweifel-Zehnder AE, Chicherio M, Studerus-Germann A, Bl?si S, Rossi S, Gutbrod K, Schmid N, Beaud V, Mondadori C, Brugger P, Sacco L, Müri R, Hildebrandt G, Keller E, Regli L, Fandino J, Mariani L, Raabe A, Daniel RT, Reinert M, Robert R, Schatlo B, Bijlenga P, Schaller K, Monsch AU, on behalf of the Swiss SOS study group. Neuropsychological testing after aneurysmal subarachnoid hemorrhage. Swiss Medical Forum. 2015;15(48):1122–1127.
Zweifel-Zehnder AE, Stienen MN, Chicherio C, Studerus-Germann A, Bl?si S, Rossi S, Gutbrod K, Schmid N, Beaud V, Mondadori C, Brugger P, Sacco L, Müri R, Hildebrandt G, Fournier JY, Keller E, Regli L, Fandino J, Mariani L, Raabe A, Daniel RT, Reinert M, Robert T, Schatlo B, Bijlenga P, Schaller K, Monsch AU; Swiss SOS study group. Call for uniform neuropsychological assessment after aneurysmal subarachnoid hemorrhage: Swiss recommendations. Acta Neurochir (Wien). 2015;157(9):1449–1458.