The study was approved by the Ethics Committee for the Analysis of Research Projects of the HCFMUSP (approval number: 34115720.5.0000.0068).

This cohort study is in progress, and will evaluate 400 patients who were admitted to referral hospitals for SARS-CoV-2 infection. The study will conduct a 1-year follow-up among these patients at four evaluation time points: 1, 4, 6, and 12 months after hospital discharge.

Patients will be recruited and interviewed over the telephone regarding their medical records. For participation, the individual should be aged 18 years, agree to participate in this study, and sign the informed consent form. The patient must have been admitted to one of the referral hospitals that are in collaboration with this study, with a confirmed or suspected diagnosis of COVID-19, as well as normal or corrected visual and auditory acuity; the patient must be able to walk, even with the use of an auxiliary device. Those who are unavailable to attend the initial assessment within 30-45 days after hospital discharge or at the proposed collection site or those who do not complete the assessments because of refusal, complications (such as malaise or dizziness), or issues related to not understanding the tests will be excluded from this study (Figure 1).

Figure 1.

Flowchart of the participant selection process.

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The primary endpoint will be the assessment of functionality at the four evaluation points. The secondary outcomes, including those probably indirectly influencing functionality, such as fatigue, anxiety, depression, and cognitive changes, will be measured.

Figure 2 shows a flowchart of the patient selection process and chronological order of data collection.

Figure 2.

Flowchart of the data collection process.

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The assessment will begin with an interview to collect personal and sociodemographic data (name, age, date of birth, sex, race, marital status, education level, telephone, and address), prior history (Charlson Comorbidity Index and history of falls in the last year), natural history of the disease (day of symptom onset, initial symptoms, history of hospitalization, need for respiratory support and oxygen, prone position, need for emergency room visits, and readmission after hospital release), and whether any skin lesions and sensory changes developed after hospitalization.

The functional evaluation (Figure 3) was structured based on the International Functional Classification, which considers function, structure, and body activity as pillars for a complete evaluation. For the choice of questionnaires (Figure 4), we considered the practicality of the application and ease of understanding because except for the 10-point cognitive screener (10-CS), all the questionnaires will be completed through telephone interview. In addition, all questionnaires are validated in Portuguese.

Figure 3.

Flowchart of tests applied for functional assessments.

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Figure 4.

Secondary outcomes that impact functionality.

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For function and structure, we evaluated global and respiratory muscle strength and resistance. For the evaluation method, we included the Saehan digital manual dynamometer, model DHD-1 (SH1001), for the evaluation of global muscle strength. The test will be performed in both upper limbs for two attempts, and the best measurement will be considered (9,10).

We will perform the 1-min sit-to-stand test to evaluate lower limb resistance. This test counts the number of complete repetitions, that is, standing knee extension and sitting knee at 90° flexion, without using the arms for support while standing up and sitting down, at a speed that the individual feels safe and comfortable. For this test, we will measure peripheral oxygen saturation, heart rate, blood pressure, and Borg for dyspnea and fatigue in the lower limbs before and after the tests. In addition, the time taken to complete five repetitions will be measured to evaluate the muscle strength of the lower limbs (sit and stand test five times) (11,12).

Pulmonary function will be assessed using a portable digital spirometer (Microquark Cosmed, Italy) according to the recommendations of the American Thoracic Society and European Respiratory Society. The absolute and predicted values for the Brazilian population of forced vital capacity (FVC), volume expired in 1s (FEV1), FEV1/FVC ratio, and forced expiratory flow 25%-75% will be analyzed (13,14).

For body activity, we evaluated balance, mobility, and postural control. The balance will be measured in the Behavior Rating Inventory of Executive Function test, which comprises postural reaction, static and dynamic balance, flexibility, and sensory integration tests (15). Each item is scored on a four-point ordinal scale, ranging from 0 to 3 (best score). The final total score is 28 points (16).

Mobility will be evaluated using the standardized timed-up-and-go test as described by Padgett et al. (16). It measures the time taken by a patient to stand up from a chair, walk for 3 m, return, walk again to the chair, and sit down. For accurate execution and more precise data analysis, the G-walk sensor will be used, which is a digital wireless system for gait analysis. It provides data on spatiotemporal parameters (exact total test duration, functional mobility ability, fall risk, and duration of each test phase) and overall kinematics (amount of trunk flexion and extension during the test). The sensor will be placed on a belt at the height of the L5 lumbar vertebra, and through Wi-Fi, the data will be sent to the software for data analysis (17).

In addition, we will evaluate postural control using the portable Horus force platform from the manufacturer Contronic, which has high precision to determine the center of pressure. To perform the tests, the patient’s stability limits must first be evaluated. The patient will then be asked to stand for 30s under the following conditions: eyes open and closed on stable ground and eyes open and closed on unstable ground. The software program will then analyze the data of the stability limit area (SL, mm), trust ellipse area (TE, mm2), path length (PL; mm), total average PL speed (mm/s), and TE/SL ratio (%) (18).

Finally, functionality will be assessed using the Barthel Index, which evaluates an individual’s performance in activities of daily living. It is considered reliable to monitor changes in functionality patterns and to assess functional independence in daily life tasks. The sum of the points referring to the functions will classify the patients' degree of dependence (19,20).

Fatigue, sarcopenia, frailty, fear of falling, anxiety, depression, and cognition were included in the protocol to analyze all aspects that could influence functionality. For the evaluations, we will use the following questionnaires:

• a)

  Functional Assessment of Chronic Illness Therapy Fatigue Scale for fatigue: This questionnaire covers physical, functional, and emotional fatigue and social consequences of fatigue. It contains 13 items, with five responses ranging from “None” to “Very Much.” Items are scored from 0 to 4, added, multiplied by 13, and divided by the number of items effectively answered. The overall score ranges from 0 to 52, with higher scores reflecting less fatigue (21).

• b)

  SARC-F questionnaire for sarcopenia: This questionnaire comprises five objective questions on activities of daily living and history of falls in the past year. It aims to identify individuals at an increased risk of sarcopenia but not to diagnose sarcopenia (22,23).

• c)

  Clinical Frailty Score for frailty: This instrument comprises nine clinical items, in which patients can be classified as frail, pre-frail, and non-frail, according to the observation of a healthcare professional and the verification of patient information (24).

• d)

  Falls Efficacy Scale International (FES-I) for fear of falling: Adapted by the Prevention of Falls Network Europe, the FES-I contains six questions in addition to that in the original scale to assess external activities and social interaction. This questionnaire assesses 16 activities, and for each item, the patient must choose among four options. The points are added up, and the higher the score, the greater the fear of falling (25,26).

• e)

  Hospital Anxiety and Depression Scale (HADS) for anxiety and depression: This tool is used to identify cases (possible or probable) of mild anxiety and/or depression disorders in non-clinical populations. It comprises 14 items divided into two subscales: HADS-Anxiety and HADS-Depression (27,28).

• f)

  10-point cognitive screener (10-CS) for cognition: This is a brief screening instrument to detect cognitive impairments. It assesses temporal orientation, category fluency, and memory (29).

The results will be presented using descriptive statistics, such as means, standard deviations, 95% confidence intervals, and interquartile ranges. The participants will be divided into groups according to the following criteria: age group, sex, number of comorbidities, and number of medications.

The prognoses will be compared among group using repeated-measures analysis of variance and Bonferroni post-hoc test.

Multiple regression analyses will be performed to study the risk factors for falls and readmission.

All analyses will be performed using SPSS software, adopting a significance level of 5% (p<0.05).

Sample size will be calculated to better interpret the clinical significance of the results.