To analyze the relationship between gait speed and physical function in a cross-sectional study, we recruited patients with PAD and symptoms of intermittent claudication. The sample size to achieve significance in correlations ≥0.25, considering an alpha error of 0.05 and a power of 80%, was estimated to be 123 patients. The patients were submitted to an assessment of their gait speed through the 4-meter walk test, which was performed in two conditions: usual pace and fast pace. To assess physical function, a 6MWT, handgrip strength test, static balance test and sit-to-stand test were performed. Patients also answered two specific questionnaires (Walking impairment questionnaire - WIQ and Walking Estimated-Limitation Calculated by History - WELCH) to assess their self-reported physical function. Associations between gait speed (usual and fast pace) with objective and subjective measures of physical function were assessed through multiple linear regression analysis.

Symptomatic PAD patients were recruited at hospitals in São Paulo, Brazil, between September 2015 and March 2018. The inclusion criteria were as follows: a) aged 50 years or older with presence of intermittent claudication symptoms (Rutherford stages II and III in one or two legs; b) ankle brachial index (ABI) <0.90; c) absence of critical limb ischemia, rest pain, noncompressible vessels, amputated limbs and/or ulcers, and d) absence of pulmonary diseases.

The study was approved by the Institutional Review Board, performed in accordance with the International Ethics Standards, conformed to the Helsinki Declaration, and approved by the Institutional Ethics Committee.

Prior to data collection and participation, patients were informed about the procedures for participation in the study, as well as the risks and benefits, and signed a written informed consent form.

Sociodemographic, comorbidities, and medication information were obtained through a face-to-face interview. Sociodemographic variables included age, sex (male or female), and educational status (incomplete high school, high school or more). History of smoking habits (ex-, current, or never-smoker), obesity (body mass index (BMI) ≥30 kg/m2), diabetes (doctor-diagnosed or use of glucose-lowering drugs), hypertension (systolic/diastolic blood pressure ≥140/90 mmHg or use of antihypertensive drugs), dyslipidemia (doctor-diagnosed or use of lipid-lowering drugs), coronary heart disease, heart failure, and cerebrovascular disease (medical history) were obtained. Body weight was measured via a calibrated scale to the nearest 0.1 kilogram, while height was measured with a stadiometer to the nearest 0.01 m. BMI was calculated as body weight divided by height squared in meters.

PAD severity was identified by a single evaluator using the ABI in accordance with guidelines (15). Briefly, ABI was measured as the highest systolic blood pressure in the posterior tibial or dorsalis pedis artery divided by the highest systolic blood pressure in the brachial artery. Blood pressure measurements were recorded in both limbs using a Doppler vascular monitor (Medmega DV160, Brazil) and a mercury sphygmomanometer.

To analyze gait speed, we assessed patients on a 4-meter test. Patients performed this test twice (usual and fast gait) over four meters, and the time was recorded using a stopwatch (within 0.1 seconds). To assess the usual gait speed, patients were instructed to “walk to the other end of the course at your usual speed, just as if you were walking down the street to go to the store.” To assess the fast gait speed, patients were instructed to walk as fast as they could until the end of the course. Patients were allowed to use assistive devices if needed, and each participant was timed for two attempts at usual and fast gait speeds. The fastest walk of each pair of attempts (usual and fast) was used for analyses. To describe the gait speed, a ratio between distance (4-meter) and the time that the patient took to complete the course was calculated.

Handgrip strength was obtained using a dynamometer with digital display (CAMRY, USA) that was adjustable and calibrated with a scale from 0 to 100 kgf. Patients remained seated with a slight adduction of the shoulder, the elbow flexed at 90°, and the forearm and wrist in a neutral position. The test was performed in three attempts for both arms. In each attempt, patients performed a maximal voluntary contraction for five seconds, with a 1-minute interval between each attempt.

The standing balance test required patients to maintain for 10 seconds each stance, with their feet placed side by side, semitandem, and in tandem. For each stance, the interviewer first demonstrated the task, then supported patients to maintain their balance while they positioned their feet, asked if they were ready, released the support and began timing. The timing was stopped when participants moved their feet or grasped the interviewer for support or when 10 seconds had elapsed. Scores ranged from 0 to 4 (maximum performance).

The sit-to-stand test required patients to stand from a chair with their arms across their chest, five times, as quickly as possible, the task was timed from the initial sitting position to the final standing position at the end of the fifth stand. The time measured in seconds was the outcome.

Patients also performed an over-ground 6MWT along a 30-m-long corridor as previously described (16). Briefly, patients were encouraged to “walk at their usual pace for six minutes and cover as much ground as possible” and rest if necessary. At the end of each minute, patients received feedback on the elapsed time, and standardized encouragement in the form of statements such as “you're doing well, keep it up” and “do your best“ were utilized. The total walked distance was defined as the maximum distance completed by the patient at the end of six minutes.

Subjective physical function was measured by validated versions of the WIQ (17) and WELCH questionnaire (18). The WIQ assesses self-reported ambulatory ability in 3 domains: walking distance, walking speed, and stair climbing, with each domain scored on a 0 to 100 scale, where 0 represents extreme limitation and 100 represents no difficulties walking long distances, walking rapidly, or climbing 3 stair flights, respectively. The WELCH questionnaire (18) is a four-question questionnaire related to the speed at which the patient walks normally. The WELCH score ranges from 0 to 100, with zero indicating a patient who can only walk for 30 seconds when walking slowly and who usually walks much slower than relatives, friends or people of the same age without PAD. A score of 100 refers to a patient who can walk 3 hours or more, even when walking fast, and who usually walks faster than relatives, friends or people of the same age without PAD.

The Gaussian distribution and the homogeneity of variance of the data were analyzed by Shapiro-Wilk and Levene tests. Associations between gait speed (usual and fast pace) with physical function (balance, sit-to-stand test, handgrip strength and 6MWT) and subjective physical function (WIQ and WELCH) were assessed through multiple linear regression analysis. Within these models, variables with known associations to either dependent or independent variables were chosen a priori and included as covariates to the regression model. Covariates included age, ABI, BMI, and gender. A residual analysis was performed with homoscedasticity examined using graphical analysis (scatter plot) and the Cook-Weisberg test. Multicollinearity was assessed assuming a variance inflation factor below 5.0. The unstandardized coefficients (standard error), coefficient values, and significance were determined in the regression models. All analyses were performed using IBM SPSS Statistics, version 20.0, and the level of significance was set at p<0.05 (2-tailed).