Association between functional performance and executive cognitive functions in an elderly population including patients with low ankle-brachial index.

INTRODUCTION: Peripheral arterial disease, as measured by the ankle-brachial index (ABI), is prevalent among the elderly, and is associated with functional performance, assessed by the 6-minute walk test (6MWT). Executive cognitive function (ECF) impairments are also prevalent in this population, but no existing study has investigated the association between ECF and functional performance in an elderly population including individuals with low ABI. AIM: To investigate the association between functional performance, as measured by the 6MWT, and loss in ECF, in an elderly sample including individuals with low ABI.
METHOD: The ABI group was formed by 26 elderly individuals with low ABI (mean ABI: 0.63±0.19), and the control group was formed by 40 elderly individuals with normal ABI (mean ABI: 1.08±0.07). We analyzed functional performance using the 6MWT, global cognition using the Mini-Mental State Examination (MMSE), and ECF using the Digit Span for assessing attention span and working memory, the Stroop Color Word Test (SCWT) for assessing information processing speed and inhibitory control/impulsivity, and the Controlled Oral Word Association Test (COWAT) for assessing semantic verbal fluency and phonemic verbal fluency. We also used a factor analysis on all of the ECF tests (global ECF).
RESULTS: Before adjustment, the ABI group performed worse on global cognition, attention span, working memory, inhibitory control/impulsivity, semantic verbal fluency, and phonemic verbal fluency. After adjustment, the ABI group performance remained worse for working memory and semantic verbal fluency. In a simple correlation analysis including all of the subjects, the 6MWT was associated with global cognition, attention span, working memory, information processing speed, inhibitory control/impulsivity, semantic verbal fluency, and global ECF. After adjustment, all the associations remained statistically significant.
CONCLUSION: This study found an independent association between functional performance and ECF in an elderly population including low ABI individuals, showing that, in elderly populations with functional impairment, ECF may also be impaired.

Introduction

Lower extremity peripheral arterial disease (PAD), a cardiovascular disease (CVD) resulting from atherosclerotic processes affecting the lower limbs,1 is prevalent among the elderly.2 Low ankle–brachial index (ABI), the most utilized criterion for detecting PAD,3 may lead to pain on exertion, skeletal muscle atrophy and weakness,4 resulting in loss of functional performance.5 Studies have shown that a low ABI is related to decreased walking speed6 even among asymptomatic subjects.7 However, physical dysfunction seems to increase with the severity of symptoms resulting from a low ABI.8

The 6-minute walk test (6MWT) has been utilized in several studies of low ABI populations, in order to investigate different outcomes of PAD.9–12 In many of these studies, symptoms resulting from low ABI and its severity were shown to be associated with and completely or partially explain shorter distances on the 6MWT,9–11 pointing to an important relationship with functional loss.

Cognitive impairment is also prevalent among the elderly.13 Executive cognitive functions (ECF), which encompass the cognitive abilities of making decisions, judging, and suiting behaviors in order to solve problems,14 like any other cognitive function, may be impaired in the elderly.13 This impairment can lead to poor treatment adherence15 and loss of independence13 and ultimately increase the risk of developing dementia itself.16 The different manifestations of CVD, as well as the risk factors that lead to its development, have been shown to associate with cognitive losses – especially the ones related to executive functioning17 – that may increase with the severity18 and with the number of CVD manifestations.19

Thus, early detection of executive dysfunction and functional impairments in patients with low ABI may be useful to prevent future problems and cognitive decline that affect quality of life. To our knowledge, no existing study has investigated the specific relationship between ECF and functional performance in an elderly sample including individuals with low ABI. Given the associations mentioned earlier, we hypothesized that, in such individuals, functional performance, as measured by the 6MWT, will be associated with loss in ECF.

Method

Population

The low ABI group (ABI group) for the study was recruited consecutively from the Vascular Clinic at Hospital das Clínicas, in São Paulo, Brazil, from April 2011 to August 2013. The normal ABI group (control group) was recruited from elderly communities near the Hospital and was similar to the ABI group in terms of age and sex. The inclusion criterion for the ABI group was an ABI value <1.00, thus including borderline and PAD subjects in the ABI group, while the inclusion criterion for control group was an ABI value ≥1.00.20

The exclusion criteria for both groups were history of stroke, epilepsy, psychotic disorder, traumatic brain injury and developmental delay, all assessed in self-reports. The study project was evaluated and approved by the Ethical Committee of the Hospital das Clínicas. All subjects were fully informed about the purpose and procedures of the study, and gave written informed consent.

Sociodemographic investigation

All individuals were contacted by phone and invited to attend a scheduled appointment at the hospital. We performed an interview collecting sociodemographic information such as age, sex, education level, social level, and family income.

Clinical and functional assessment

The weight and height of each participant were measured using a regular scale, and the body mass index (BMI) was calculated as the ratio between weight and squared height. Systolic blood pressure, diastolic blood pressure and heart rate were measured in the supine position, after 5 minutes of rest, and repeated after 1 minute. The second measurement was considered in the analysis. With the subject still in the supine position, the ABI was measured using a calf, a sphygmomanometer, and a portable vascular Doppler (DV 610, Medmega, SP, Brazil); systolic pressures were measured in the following order: left brachial artery, left dorsalis pedis artery, left posterior tibial artery, right dorsalis pedis artery, right posterior tibial artery, and right brachial artery. The ABI value for each leg was calculated as the ratio between the highest pressure in the arms and the highest pressure in each leg. The lowest value between the two legs was considered in the analysis.21 The 6MWT was performed in a 20 m hall, and the subject was instructed to walk for 6 minutes, according to his or her tolerance, and to slow down or stop if necessary. The time was registered by the researcher, and every minute, words of encouragement were spoken. The test was interrupted every time the individual cited leg pain that did not allow him or her to continue the activity, but the timer continued to run during this period, and the participant resumed activity as soon as the pain attenuated. The total distance walked by the subject was considered in the analysis.22

Executive cognitive functions assessment

The cognitive assessment consisted of three steps. In the first step we assessed the intelligence quotient (IQ) and psychiatric symptoms, for use in the correction of the analysis, given their association with cognitive performance. The Block Design and the Vocabulary subtests of the Wechsler Adult Intelligence Scale – third edition (WAIS-III) were utilized as a short form of IQ assessment. On the Block Design subtest, the subject is presented with geometric figures in two colors, increasing in complexity, and is asked to reproduce them with blocks in the same colors, in a certain amount of time. Each completed figure was scored, and the total score was computed. On the Vocabulary subtest, the subject is presented with spoken words, increasing in difficulty, and is asked to tell their meanings or their synonyms. Every correct word was scored, and the total score was computed. Scores for both subtests were added and weighted to be transformed into the IQ value by age groups.23 The Beck Depression Inventory is a self-administered test assessing depressive symptoms. It is composed of 21 questions, which go from 0 to 3, assessing psychological and physical symptoms. The total score was computed and was used in the analysis. The Beck Anxiety Inventory is also a self-administered test assessing anxiety symptoms. It is also composed of 21 questions, which go from 0 to 3, assessing psychological and physical symptoms. The total score was computed and used in the analysis.24

In the second step, we assessed global cognition. The Mini-Mental State Examination (MMSE) is the most utilized screening of global cognition. It is composed of 19 questions or commands, divided into 6 cognitive domains: orientation, immediate recall, attention and calculation, delayed recall, language, and construction. We used the total score in the analysis (up to 30 points).25

In the third step, we assessed ECF. The Digit Span test assesses verbal attention and is composed of two tasks: Digit Forward, assessing attention span, and Digit Backward, assessing working memory. In the first task, sequences of numbers with an increasing degree of difficulty are presented to the subject, and he or she is asked to reproduce them in the same order. In the second task, different sequences of numbers with an increasing degree of difficulty are presented to the subject, and he or she is asked to reproduce them in reverse order. The score on each task goes up to 14. We used separate scores for each task in the analysis.23

The Controlled Oral Word Association Test (COWAT) assesses verbal fluency, and it is a test in which the subject is asked to name specific kinds of words within 1 minute. The “Animals” category was used to assess semantic verbal fluency, and the “Letters” category, using the letters “F,” “A”, and “S” (FAS), was used to assess phonemic verbal fluency. We used the total score for the “Animals” category and the sum of the scores on the letters F, A and S for the “Letters” category.26

The Stroop Color Word Test (SCWT) is a test in which the subject is asked to inhibit the reading of the written word and indicate the color in which the word is written. The test is composed of three different parts, with colored figures/words, which increase in difficulty, and the time the subject takes to complete each part is registered. The first one assesses information processing speed and the second and third ones assess inhibitory control/impulsivity. We utilized separate times for each part.26

Executive functions, cognitive aspects that involve multiple domains, are all related to the functioning of the prefrontal cortex, and belong to the same cognitive construct.14 Thus, in addition to the separate scores for each test, we also analyzed a unit of every ECF category verified in the third step of the cognitive assessment.

Education level: This variable was used as a covariate because it is closely related to cognition and cognitive loss,27 in either young and elderly populations,28,29 and could bias the performance of the groups. Number of years of formal education was used to represent the education level.

Social level (socioeconomic level): Social level has also been associated with cognitive performance, and was measured in this study to be used as another covariate.30 The level was defined by an instrument based on the number of material goods the person possesses at home.31

Family income: Low income has been associated with poor performance on cognitive tests. Therefore, we used this variable as a covariate, since it could influence the analysis.32 Family income was based on total monthly household income.

Intelligence quotient: Intellectual performance is also related to either poor or favorable results in cognitive assessment.33 That is why IQ was measured in this study, and used as another covariate in the analysis. The description of the assessment can be found in the study method.

Depressive symptoms: There is evidence to indicate that depressive symptoms can also impair cognition, especially in the elderly.34 Thus, we utilized these symptoms as another covariate in the analysis. The description of this assessment also can be found in the study method.

Anxiety symptoms: Elderly complaints about cognitive difficulties can also be associated to anxiety symptoms.35 Therefore, we utilized this variable as a covariate to avoid its bias in the analysis. The description of the assessment can be found in the study method.

Statistical analysis

Comparative analyses on the groups’ performance were done using the Chi-square test for the categorical variables and the Student’s t-test and the Mann–Whitney test for the continuous parametric and nonparametric variables, respectively.

Pearson correlation analyses of the total study sample were used to investigate the associations between functional performance and global cognition/ECF. Partial correlation analyses were performed to investigate the associations between functional performance and global cognition/ECF, adjusted for the confounding variables described in the previous section.

Principal component analysis was used for two purposes: first, to generate a global factor for socioeconomic characteristics, uniting the information on education level, social level, family income, and IQ, because they were highly correlated (minimum correlation between them was R=0.482, P<0.001), in order to generate a new factor that could unite their characteristics. The new variable was saved, named “sociodemographic factor”, and utilized in the adjustment analysis, instead of the separate variables, along with depressive symptoms and anxiety symptoms. A similar process was used as a second purpose, which was to generate a global factor for ECF, identifying the common variance in the Digit Forward, Digit Backward, SCWT I, SCWT II, SCWT III, COWAT – FAS, and COWAT – Animals tests, due to their mentioned similarity in terms of cognitive constructs. The resulting factor values are decreasing and negatively related to our variables of interest. The new variable was saved, named “ECF factor”, and utilized in the analysis, along with the independent scores for each ECF measurement.

Results

During the research period, 32 individuals with low ABI were contacted, 27 agreed to participate in the study, and 26 actually came to the examination and were included in the study sample. For the control group, 41 individuals (with similar ages and sex to the ABI group) were contacted, of whom 40 agreed to participate, and all of them came to the examination and were included in the study sample.

Sociodemographic, clinical, and functional characteristics are described in Table 1. The mean age for the control (67.17±8.24) and ABI (68.57±8.34) groups was similar (P=0.504), and so were male (control =65.4%, n=17 vs ABI=62.5%, n=25; P=0.812) and female (control =34.6%, n=9 vs ABI=37.5%, n=15; P=0.812) sex frequencies. On the other hand, the ABI group had a lower education level (control =12.85±5.16 vs ABI=8.30±4.76; P=0.001), lower distribution of social level (P=0.029), lower family income (control =2,491.29±1601.77 vs ABI=1,227.35±755.62, P=0.002), lower IQ levels (control =111.94±8.96 vs ABI=98.47±25.06, P=0.007), a higher prevalence of depressive symptoms (control =6.79±5.23 vs ABI=12.56±9.30, P=0.008), and a higher prevalence of anxiety symptoms (control =5.47±4.59 vs ABI=11.48±7.23, P=0.001).

Table 1

Sociodemographic, clinical and functional characterization

Variable	Control (n=40)	ABI (n=26)	P-value
Age
Mean (years)	67.17 (±8.24)	68.57 (±8.34)	0.504a
Range	54–88	53–87
Sex			0.812b
Male	65.4% (n=17)	62.5% (n=25)
Female	34.6% (n=9)	37.5% (n=15)
Education level (years)	12.85 (±5.16)	8.30 (±4.76)	0.001a
Social level			0.029b
A	5% (n=2)	0% (n=0)
B	62.5% (n=25)	30.8% (n=8)
C	17.5% (n=7)	38.5% (n=10)
D	0% (n=0)	7.7% (n=2)
E	0% (n=0)	0% (n=0)
Family income ($ per month)	2491.29 (±1601.77)	1227.35 (±755.62)	0.002a
IQ	111.94 (±8.96)	98.47 (±25.06)	0.007a
BDI	6.79 (±5.23)	12.56 (±9.30)	0.008a
BAI	5.47 (±4.59)	11.48 (±7.23)	0.001a
BMI (kg/m2)	25.49 (±3.84)	25.81 (±4.65)	0.773a
SBP (mmHg)	134.68 (±20.04)	147.05 (±22.93)	0.099a
DBP (mmHg)	80.50 (±10.85)	80.20 (±12.68)	0.941a
HR (bpm)	66.31 (±13.34)	63.78 (±10.36)	0.533a
ABI	1.08 (±0.07)	0.63 (±0.19)	0.001a
6MWT (m)	394.74 (±88.28)	294.20 (±76.05)	0.001a

Notes:

General Linear Model;

chi-squared test. Significant P-values are highlighted in bold.

Abbreviations: IQ, intelligence quotient; BDI, Beck Depression Inventory; BAI, Beck Anxiety Inventory; BMI, body mass index; SBP, systolic blood pressure; DBP, diastolic blood pressure; HR, heart rate; ABI, ankle-brachial index; 6MWT, 6-minute walk test.

The groups were similar in some of the clinical characteristics, such as BMI (control =25.49±3.84 kg/m2 vs ABI=25.81±4.65 kg/m2; P=0.773), systolic blood pressure (control =134.68±20.04 mmHg vs ABI=147.05±22.93 mmHg; P=0.099), diastolic blood pressure (control =80.50±10.85 mmHg vs ABI=80.20±12.68 mmHg; P=0.941), and heart rate (control =66.31±13.34 bpm vs ABI=63.78±10.36 bpm; P=0.533). However, the ABI group had lower values of ABI (control =1.08±0.07 vs ABI=0.63±0.19; P=0.001), as expected, and walked shorter distances in the 6MWT (control =394.74±88.28 m vs ABI=294.20±76.05 m; P=0.001).

In the comparative analysis of ECF between groups (shown in Table 2), in the unadjusted model, the ABI group performed worse on global cognition (control =28.55±1.46 vs ABI=27.44±1.73; P=0.007). It also performed worse on several ECF subdomains, such as attention span (control =5.94±1.98 vs ABI=4.80±1.19; P=0.023), working memory (control =5.11±1.72 vs ABI=3.90±1.20; P=0.008), inhibitory control (control =22.89±8.91 vs ABI=30.14±14.29, P=0.015), semantic verbal fluency (control =18.92±7.49 vs ABI=15.53±3.55; P=0.036), and phonemic verbal fluency (control =35.27±15.04 vs ABI=26.92±10.12; P=0.016). After adjustment, working memory performance (P=0.013) and phonemic verbal fluency (P=0.005) remained worse for ABI patients.

Table 2

Comparison of ECF performance between groups

Variable	Control (n=40)	ABI (n=26)	Unadjusted	Adjusteda
MMSE	28.55 (±1.46)	27.44 (±1.73)	0.007	0.270
Digit Span
Digit Forward	5.94 (±1.98)	4.80 (±1.19)	0.023	0.062
Digit Backward	5.11 (±1.72)	3.90 (±1.20)	0.008	0.013
SCWT
I	16.11 (±6.35)	18.81 (±6.98)	0.116	0.165
II	22.89 (±8.91)	30.14 (±14.29)	0.015	0.084
III	40.70 (±19.21)	43.00 (±18.18)	0.635	0.949
COWAT
Letters FAS	18.92 (±7.49)	15.53 (±3.55)	0.036	0.005
Animals	35.27 (±15.04)	26.92 (±10.12)	0.016	0.228
ECF factor	−0.08 (±1.07)	0.37 (±0.82)	0.172	0.056

Notes:

Adjusted for sociodemographic factor, depressive symptoms, and anxiety symptoms. Significant P-values were highlighted in bold.

Abbreviations: MMSE, Mini-Mental State Examination; SCWT, Stroop Color Word Test; COWAT, Controlled Oral Word Association Test; ECF, executive cognitive functions; ABI, ankle-brachial index.

Association between functional performance and executive cognitive functions

In the analysis of the association between functional performance and ECF (Figure 1), the unadjusted model showed that the 6MWT was associated with global cognition (ρ=0.412; P=0.001), attention span (ρ=0.427; P=0.001), working memory (ρ=0.360; P=0.008), information processing speed (ρ=−0.306; P=0.016), inhibitory control/impulsivity (ρ=−0.366; P=0.003), phonemic verbal fluency (ρ=0.365; P=0.003), and global ECF (ρ=−0.332; P=0.018). After adjustment (Table 3), the 6MWT remained associated with global cognition (r=0.375, P=0.015), attention span (r=0.371, P=0.016), working memory (r=0.373, P=0.015), information processing speed (r =−0.332, P=0.032), inhibitory control/impulsivity (r=−0.352, P=0.022), phonemic verbal fluency (r=0.412, P=0.007), and global ECF (r=−0.444, P=0.003).

Figure 1

Associations between functional performance and ECF.

Notes: (A) 6MWT vs MMSE; (B) 6MWT vs Digit Forward; (C) 6MWT vs Digit Backward; (D) 6MWT vs SCWT I; (E) 6MWT vs SCWT II; (F) 6MWT vs SCWT III; (G) 6MWT vs COWAT – letters FAS; (H) 6MWT vs COWAT – Animals; (I) 6MWT vs ECF factor.

Abbreviations: 6MWT, 6-minute walk test; MMSE, Mini-Mental State Examination; SCWT, Stroop Color Word Test; COWAT, Controlled Oral Word Association Test; ECF, executive cognitive functions.

Table 3

Adjusted associations between functional performance and ECF

Variable	6MWTa	P-value
MMSE	0.375	0.015
Digit Span
Digit Forward	0.371	0.016
Digit Backward	0.373	0.015
SCWT
I	−0.332	0.032
II	−0.302	0.052
III	−0.352	0.022
COWAT
Letters FAS	0.412	0.007
Animals	0.207	0.189
ECF factor	−0.444	0.003

Notes:

Adjusted for sociodemographic factor, depressive symptoms, and anxiety symptoms. Significant P-values were highlighted in bold.

Abbreviations: MMSE, Mini-Mental State Examination; SCWT, Stroop Color Word Test; COWAT, Controlled Oral Word Association Test; ECF, executive cognitive functions; 6MWT, 6-minute walk test.

Discussion

This study found an independent association between functional performance and ECF in an elderly population including low ABI individuals. The performance in the 6MWT was independently associated with global cognition, attention span, working memory, information processing speed, inhibitory control/impulsivity, phonemic verbal fluency, and global ECF.

Our findings contribute to a growing body of evidence which shows that in elderly populations, impairment in functional performance might be associated with ECF impairment. In a prospective study of 2,776 elderly subjects, gait speed was associated with decline in attention and psychomotor speed after 5 years of follow-up.36 This association occurs in the opposite way as well. In a cross-sectional analysis of a normal ABI population of 3,075 subjects, the Digit Symbol Substitution Test was associated with performance on gait speed, chair stands, and standing balance tests.37 On the other hand, low ABI has formerly been associated with ECF impairment even in its asymptomatic form.38 When it comes to cognition, ECF have also been associated with different manifestations of functional loss, such as decreases in mobility,39 gait speed,40 and route learning,41 as well as an increased risk of falls.42

To our knowledge, this is the first study to find an association between functional performance, as measured by the 6MWT, and ECF in an elderly population including low ABI patients. One previous study, analyzing the relationship between functional performance and cognitive function in a low ABI population, utilized only the Clock Drawing Test, which does not assess ECF specifically.43 Some other studies have investigated the ECF of low ABI subjects, along with other cognitive functions, but have not assessed the functional performance of their populations.44–46

We also included a novel variable in the adjustment analysis. To our knowledge, the IQ has never been used as a covariate in any study assessing the association between functional performance and cognition in populations including individuals with low ABI. As mentioned, this variable is an important predictor of cognitive performance,33 and thus, should be considered carefully in this type of study.

The physiology of this specific association between functional performance and ECF might be explained, at least in part, by the pathophysiological mechanisms underlying atherosclerotic vascular disease, a process that might lead to hemorrhagic and ischemic major and minor tissue losses.47,48 As a systemic process, it might be related to peripheral and central impairments concomitantly, as was observed in this study. These findings highlight a dangerous association, especially in the elderly, and should be carefully considered, since any functional or cognitive impairment in the elderly may lead to loss of independence and quality of life.

The sample analyzed in our study showed that the group with lower ABI also had lower educational, social, and economic statuses. One possible reason for this difference might be related to the establishment of vascular impairment. People with lower educational levels and lower economic status might be less exposed to information on diseases, risk factors for their development and health care, which would lead to increased incidence of diseases, including vascular impairment.