More Than 50 Long-Term Effects of COVID-19: A Systematic Review and Meta-Analysis

DOI: https://doi.org/10.21203/rs.3.rs-266574/v1

Abstract

Background. COVID-19, caused by SARS-CoV-2, can involve sequelae and other medical complications that last weeks to months after initial recovery, which has come to be called Long-COVID or COVID long-haulers. This systematic review and meta-analysis aims to identify studies assessing long-term effects of COVID-19 and estimates the prevalence of each symptom, sign, or laboratory parameter of patients at a post-COVID-19 stage.

Methods. LitCOVID (PubMed and Medline) and Embase were searched by two independent researchers. All articles with original data for detecting long-term COVID-19 published before 1st of January 2021 and with a minimum of 100 patients were included. For effects reported in two or more studies, meta-analyses using a random-effects model were performed using the MetaXL software to estimate the pooled prevalence with 95% CI. Heterogeneity was assessed using I2 statistics. This systematic review followed Preferred Reporting Items for Systematic Reviewers and Meta-analysis (PRISMA) guidelines, although the study protocol was not registered.

Results. A total of 18,251 publications were identified, of which 15 met the inclusion criteria. The prevalence of 55 long-term effects was estimated, 21 meta-analyses were performed, and 47,910 patients were included. The follow-up time ranged from 14 to 110 days post-viral infection. The age of the study participants ranged between 17 and 87 years. It was estimated that 80% (95% CI 65-92) of the patients that were infected with SARS-CoV-2 developed one or more long-term symptoms. The five most common symptoms were fatigue (58%), headache (44%), attention disorder (27%), hair loss (25%), and dyspnea (24%). All meta-analyses showed medium (n=2) to high heterogeneity (n=13).

Conclusions. In order to have a better understanding, future studies need to stratify by sex, age, previous comorbidities, the severity of COVID-19 (ranging from asymptomatic to severe), and duration of each symptom. From the clinical perspective, multi-disciplinary teams are crucial to developing preventive measures, rehabilitation techniques, and clinical management strategies with whole-patient perspectives designed to address long COVID-19 care.

Background

The severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) was detected in China in December 2019. Since then, more than 90 million people worldwide have been infected after a year, and over 2 million people have died from the coronavirus disease 2019 (COVID-19)(1). Although unprecedented efforts from the scientific and medical community have been directed to sequence, diagnose, treat, and prevent COVID-19, individuals' lasting effects after the acute phase of the disease are yet to be revealed.

To date, there is no established term to coin the slow and persistent condition in individuals with lasting sequelae of COVID-19. Different authors have used the terms “Long-COVID-19”, “Long Haulers”, “Post-acute COVID-19”, “Persistent COVID-19 Symptoms”, “Post COVID-19 manifestations”, “Long-term COVID-19 effects”, “Post COVID-19 syndrome", among others. In the absence of an agreed definition, we convened for this review to refer to "Long-term effects of COVID-19”.

Symptoms, signs, or abnormal clinical parameters persisting two or more weeks after COVID-19 onset that do not return to a healthy baseline can potentially be considered long-term effects of the disease(2). Although such alteration is mostly reported in severe and critical disease survivors, the lasting effects also occur in individuals with a mild infection who did not require hospitalization(3). It has not yet been established if sex, gender, age, ethnicity, underlying health conditions, viral dose, or progression of COVID-19 significantly affect the risk of developing long-term effects of COVID-19(4).

Since first reported, there has been a vast amount of social media patient groups, polls, comments, and scientific articles aiming to describe the chronicity of COVID-19. In parallel, hundreds of scientific publications, including cohorts studying specific effects of the disease and lists of case reports, have been described (5). However, a broad overview of all the possible longstanding effects of COVID-19 is still needed.

The aim of our study was to perform a systematic review and meta-analysis of peer-reviewed studies to estimate the incidence of all the symptoms, signs, or abnormal laboratory parameters extending beyond the acute phase of COVID-19 reported to date.

Methods

Search strategy and selection criteria

The search's objective was to identify peer-reviewed human studies in English that reported symptoms, signs, or laboratory parameters of patients at a post-COVID-19 stage (assessed two weeks or more after initial symptoms) in cohorts of COVID-19 patients. Only studies with a minimum of 100 patients were included.

The databases used to identify the studies were LitCOVID (6) (PubMed and Medline) and Embase. Studies were included if they were published before January 1st 2021. The search terms used for both searches were: COVID long* OR haulers OR post OR chronic OR term OR complications OR recurrent OR lingering OR convalescent OR convalescence. Given that LitCOVID includes all articles from MedLine, in the search in Embase we excluded the articles from MedLine and those not related to COVID-19. All types of studies, including randomized controlled trials, cohorts, and cross-sectional studies, were analyzed only when the cases (numerator) were part of a COVID-19 cohort (denominator). Titles, abstracts, and full texts of articles were independently screened by two authors (SLL and TWO). The complete article was reviewed in case of difference of opinion on the inclusion based on title or abstract. Disagreement on the inclusion of a full-text article was discussed with all the authors. The exclusion criteria were: (1) not written in English; (2) have less than 100 patients included in the study. The systematic review followed the Preferred reporting Items for Systematic Reviewers and Meta-analysis (PRISMA) guidelines (7, 8).

Data extraction

Data were extracted by 4 authors (AC, PR, RS, SV) and QCed by two authors (TWO, CP). The descriptive variables extracted were country, setting, follow-up time, the severity of COVID-19, sample size, mean age and percentage of gender, outcomes, and names used to describe the Long-term effects of COVID-19.

Outcomes

All the diseases, disorders, symptoms, signs, and laboratory parameters reported total numbers or percentages were included. When two-time points were reported in the study, the outcomes assessed after the most extended follow-up were used.

Data-analysis

For effects reported only in a single study, the prevalence was estimated by dividing the number of patients with each symptom by the total number of COVID-19 patients in the sample multiplied by 100 to estimate the percentage. For effects reported in two or more studies, meta-analyses using a random-effects model were performed using the MetaXL software to estimate the pooled prevalence, which uses a double arcsine transformation(9). Prevalence with 95% Confidence Intervals (CI) was presented.

Given the heterogeneity expected, a random-effects model was used. Heterogeneity was assessed using the I2 statistics. Values of 25%, 50%, and 75% for I2 represented low, medium, and high heterogeneity. Sensitivity analyses were performed to assess the contribution of each study.

Each study's quality was assessed and described using the MetaXL Guidelines, which is specific to evaluate the quality of studies assessing incidence and prevalence.
A description of what was considered is found in supplement Table 1.

Table 1

General Characteristics of Studies.

Authorref.

Country

Setting

Follow-up timepoint mean

Population

Sample Size

(n)

Age Mean (SD)/

range

Sex % Male

Outcomes

Term used to refer to Long-term effects

Andrews (40)

UK, Italy

Multicenter

52 days

Mild to moderate Health Care Workers

114

Median 38

24.6

Hyposmia, anosmia, hypogeusia, ageusia, dysgeusia.

NR

Carfì (12)

Italy

Single Center

60 days

Hospitalized

143

56.5

(19–84)

63

Fatigue, dyspnea, joint pain, chest pain, cough, anosmia, Sicca syndrome, Rhinitis, red eyes, dysgeusia, headache, sputum, lack of appetite, sore throat, vertigo, myalgia, diarrhea.

Persistent symptoms

Post-acute COVID-19

Carvalho-Schneider (41)

France

University Hospital

60 days

Mild, moderate, and severe

150

49

(44–64)

44

Weight loss > 5%, severe dyspnea or asthenia, asthenia, chest pain, palpitations, anosmia/ageusia, headache, cutaneous signs, arthralgia, myalgia, digestive disorders, fever, sick leave.

Symptom persistence

Chopra (42)

US

Multicenter

60 days

Hospitalized, and ICU

488

62

51.8

Persistent symptoms and New symptoms: Anosmia, dysgeusia, cough, shortness of breath/chest tightness/wheezing, chest problems, breathlessness, oxygen use, new use of CPAP or another breathing machine when asleep emotional impact (50%) and (financial impact).

Long term sequelae

Galvan-Tejada (43)

Mexico

Questionnaire in 3 cities

31 days

NA

141

39

49

Chills, dyspnea, anosmia, dysgeusia, nausea or vomiting, cough, red eyes.

Persistent symptoms

Garrigues (44)

France

Single Center

110 days

Hospitalized and ICU

120

63.2

62.5

Cough, chest pain, fatigue, dyspnea, ageusia, anosmia, hair loss, attention disorder, memory loss, sleep disorder.

Post-discharge symptoms

Horvath (45)

Australia

Health Database

83 days

Mild, moderate

102

45

(17–87)

40

Anosmia, ageusia, hyposmia, hypogeusia.

Post-recovery

Kamal (46)

Egypt

General population

NR

80% Mild

15% Moderate

5% Severe ICU

287

32.3

(20–60)

35.9

Fatigue, anxiety, joints pain, continuous headache, chest pain, dementia, depression. Dyspnea, blurred vision, tinnitus, intermittent fever, obsessive-compulsive disorder, pulmonary fibrosis, diabetes mellitus, migraine, stroke, renal failure, myocarditis, arrhythmia.

Post COVID-19 manifestations

Mandal (47)

UK

3 Hospitals

median 54 days

59% Oxygen 14.5% ICU 7.1%Intubation

26%Mild

41% Moderate

30% Severe

384

59.9

(± 16.1)

62

Breathlessness, cough, fatigue, depression, elevated d-dimer, elevated C reactive protein, abnormal chest radiograph, poor sleep quality.

Long-COVID

Munro (48)

UK

University Hospitals

8 weeks

Hospitalized

121

64

(44–82)

87.5

Changes in hearing, tinnitus.

Persistent

Sonnweber (49)

Austria

Multicenter

100 days

75%Hospitalized

50% oxygen 25% outpatient

Mild (N = 36), Moderate (N = 37), Severe (N = 40), Critical (N = 32)

145 and 135

57

(50–70)

55

Dyspnea, cough, fever, diarrhea, vomiting, pain, night sweat, sleep disorder, hyposmia/anosmia, reduced lung diffusing capacity, CT lung abnormalities, CRP, IL-6, PCT, d-dimer, nt-PRObnp, serum ferritin.

Persistent symptoms

Long-term sequelae

Taquet (50)

USA

Electronic Health Records

Range 14–90 days

No previous history of psychiatric disorders

44,779

49.3 (19.2)

45.1

New: Psychiatric illness disorders psychotic, insomnia, mood disorders (depressive episodes), anxiety disorders (PTSD, panic disorder, adjustment disorder, and generalized anxiety disorder).

COVID-19 sequela

Tenforde (2)

US

CDC multistate telephone interview nationwide

Range 14–21 days

Symptomatic Outpatient

270

18–50

48

Vomiting, confusion, abdominal pain, chest pain, sore throat, nausea, dyspnea, congestion, diarrhea, loss of smell, loss of taste, chills, fever, body aches, headache, cough, fatigue.

Prolonged symptoms

Prolonged illness

Townsend (14)

Ireland

Outpatient Clinic

Range 56 days to 12 weeks

Mild, moderate symptomatic, outpatient, and 55.5% Hospital

128

49.5

46.1

Fatigue (only symptoms studied).

Persistent fatigue

Xiong (10)

China

Single Center

97) days

Hospitalized

538

52

(41–62)

45.5

General symptoms, physical decline/fatigue, post-activity polypnoea, respiratory, cardiovascular, psychosocial, alopecia.

Clinical sequelae

NR = Not Reported

Results

The title and abstract of 18,251 publications were screened. Of these, 82 full publications were reviewed. Nineteen studies were excluded because they involved less than 100 persons. A total of 15 studies were selected to be analyzed (Table 1, Fig. 1). Most of the studies assessed specific symptoms included in a previously applied questionnaire. The process of study selection is presented in Fig. 1. There were 9 studies from UK/ Europe, 3 from the US, 1 each from Australia, China, Egypt, and Mexico. The patient follow-up time ranged from 14 days to 110 days. Six out of the 11 studies included only patients hospitalized for COVID-19. The rest of the studies mixed mild, moderate, and severe COVID-19 patients.

The number of patient cohorts that were followed up in the studies ranged from 102 to 44,799.
Adults ranging from 17–87 years of age were included. There were no studies with overlapping samples. A couple of studies reported that fatigue was more common in female, and one study reported that post activity polypnea and alopecia were more common in female (3, 10). The rest of the studies did not stratify their results by age or sex.

Regarding the quality of the studies, all had a score of 8 or more. The general characteristics of the studies are shown in Table 1. Different authors have used the terms “Post-acute COVID-19”, “Long COVID-19”, “Persistent COVID-19 Symptoms”, “Chronic COVID-19”, “Post COVID-19 manifestations”, “Long-term COVID-19 effects”, “Post COVID-19 syndrome”, “Ongoing COVID-19,” “long term sequelae”, or “Long-haulers” as synonyms (Table 2).

Table 2

Long term effects in patients recovering from COVID-19.

 

Studies

Cases

Sample Size

Prevalence % (95%CI)

CLINICAL MANIFESTATIONS

1 or > Symptoms

7

1403

1915

80 (65–92)

Fatigue

7

1042

1892

58 (42–73)

Headache

2

261

579

44 (13–78)

Attention Disorder

1

32

120

27 (19–36)

Hair Loss

2

178

658

25 (17–34)

Dyspnea

9

584

2130

24 (14–36)

Ageusia

4

108

466

23 (14–33)

Anosmia

6

210

1110

21 (12–32)

Post-activity polypnea

1

115

538

21 (18–25)

Joint Pain

4

191

1098

19 (7–34)

Cough

7

465

2108

19 (7–34)

Sweat

2

144

638

17 (6–30)

Nausea or Vomit

1

22

141

16 (10–23)

Chest Pain/Discomfort

6

264

1706

16 (10–22)

Memory Loss

3

320

45186

16 (0–55)

Hearing loss or tinnitus

2

64

425

15 (10–20)

Anxiety

4

2288

45896

13 (3–26)

Depression

4

182

1501

12 (3–23)

Digestive disorders

1

15

130

12 (7–18)

Weight loss

1

15

130

12 (7–18)

Cutaneous signs

1

15

130

12 (7–18)

Resting heart rate increase

1

60

538

11 (9–14)

Palpitations

1

14

130

11 (6–17)

General Pain

1

17

145

11 (7–18)

Intermittent Fever

1

32

287

11 (8–15)

Sleep Disorder

5

1036

46070

11 (3–24)

Reduced pulmonary diffusing capacity

1

14

145

10 (6–16)

Sleep Apnea

1

34

404

8 (6–12)

Chills

2

44

679

7 (1–18)

Health Care related Mental Health

1

28

404

7 (5–10)

Psychiatric illness

1

2597

44779

6 (6–6)

Red Eyes

1

8

141

6 (3–11)

Pulmonary Fibrosis

1

14

287

5 (3–8)

Discontinuous flushing

1

26

538

5 (3–7)

Diabetes Mellitus

1

12

287

4 (2–7)

Sputum

1

16

538

3 (2–5)

Limb edema

1

14

538

3 (1–4)

Dizziness

1

14

538

3 (1–4)

Stroke

1

8

287

3 (1–5)

Throat Pain

1

17

538

3 (2–5)

Mood Disorders

1

896

44779

2 (2–2)

Dysphoria

1

9

538

2 (1–3)

Obsessive Compulsive Disorder (OCD)

2

15

579

2 (0–8)

New Hypertension

1

7

538

1 (1–3)

Myocarditis

1

4

287

1 (0–4)

Renal Failure

1

4

287

1 (0–4)

Post-Traumatic Stress Disorder

(PTSD)

1

2

292

1 (0–2)

Arrythmia

1

1

287

0.4 (0–2)

Paranoia

1

1

292

0.3 (0–2)

LAB TESTS AND OTHER EXAMINATIONS

Abnormal Chest XRay/CT

2

188

529

34 (27–42)

Elevated D-dimer

2

134

529

20 (6–39)

Elevated NT-proBNP

1

16

145

11 (6–17)

Elevated C-reactive protein

2

44

529

8 (5–12)

Elevated Serum Ferritin

1

12

145

8 (4–14)

Elevated Procalcitonin

1

6

145

4 (2–9)

Elevated IL-6

1

4

145

3 (1–7)

*Random effects weighted by quality effects model MetaXL for 2 or more studies
C-reactive protein (CRP), Interleukin-6 (IL-6), D-dimer, NT-proBNP, serum ferritin, N-terminal (NT)-pro hormone BNP (NT-proBNP),

We identified a total of 55 long-term effects associated with COVID-19 in the literature reviewed (Table 3). Most of the effects correspond to clinical symptoms such as fatigue, headache, joint pain, anosmia, ageusia, etc. Diseases such as stroke and diabetes mellitus were also present. Measurable parameters included 6 elevated laboratory parameters, i.e., interleukin-6 (IL-6), procalcitonin, serum ferritin, C-reactive protein (CRP), N-terminal (NT)-pro hormone BNP (NT-proBNP), and D-dimer. Abnormal chest XRay/computed tomography (CT) was also identified (Fig. 2).

Table 2 presents the prevalence of all the effects that were reported. It was possible to perform 21 meta-analyses, for the rest the prevalence was estimated using 1 cohort. The meta-analysis of the studies (n = 7) that included an estimate for one symptom or more reported that 80% (95% CI 65–92) of the patients with COVID-19 have long-term symptoms.

The 5 most common manifestations were fatigue (58%, 95% CI 42–73), headache (44%, 95% CI 13–78), attention disorder (27% 95% CI 19–36), hair loss (25%, 95% CI 17–34), dyspnea (24%, 95% CI 14–36) (Table 2, Fig. 2). An abnormal chest XRay/CT was observed in 34% (95% CI 27–42) of the patients. Markers reported to be elevated were D-dimer (20%, 95% CI 6–39), NT-proBNP (11%, 95% CI 6–17) C-reactive protein (8%, 95% CI 5–12), serum ferritin (8% 95% CI 4–14), procalcitonin (4% 95% CI 2–9) and IL-6 (3% 95% CI% 1–7) (Table 2, Fig. 2).

Other symptoms were related to lung disease (cough, chest discomfort, reduced pulmonary diffusing capacity, sleep apnea, and pulmonary fibrosis), cardiovascular (arrhythmias, myocarditis), neurological (dementia, depression, anxiety, attention disorder, obsessive-compulsive disorders), and others were unspecific such as hair loss, tinnitus, and night sweat (Table 2, Fig. 2). Two meta-analyses showed low heterogeneity (I2 < 25%), two medium heterogeneity, and the high rest heterogeneity (I2 > 75%).

One study was excluded because it did not provide a denominator, and therefore it was not possible to estimate the prevalence(11). In such a study, the authors performed a survey in a Facebook group of patients who previously had COVID-19 and compared the symptoms of those hospitalized with mild to moderate symptoms. They concluded that both groups had symptoms after three months of having COVID-19. Symptoms that were not mentioned in any of the articles we studied include sudden loss of body weight, ear pain, eye problems, sneezing, cold nose, burning feeling in the trachea, dizziness, heart palpitations, pain/ burning feeling in the lungs, pain between the shoulder blades, Sicca syndrome, vertigo, body aches, and confusion(2, 12).

Discussion

The recovery from COVID-19 should be more developed than checking for hospital discharge or testing negative for SARS-CoV-2 or positive for antibodies (13). This systematic review and meta-analysis shows that 80% (95% CI 65–92) of individuals with a confirmed COVID-19 diagnosis continue to have at least one overall effect beyond two weeks following acute infection. In total, 55 effects, including symptoms, signs, and laboratory parameters, were identified, with fatigue, anosmia, lung dysfunction, abnormal chest XRay/CT, and neurological disorders being the most common (Table 1, Fig. 2). Most of the symptoms were similar to the symptomatology developed during the acute phase of COVID-19. However, there is a possibility that there are other effects that have not yet been identified. In the following paragraphs, we will discuss the most common symptoms to illustrate how complex each one can be. However, further studies are needed to understand each symptom separately and in conjunction with the other symptoms. The five most common effects were fatigue (58%), headache (44%), attention disorder (27%), hair loss (25%), and dyspnea (24%).

Fatigue (58%) is the most common symptom of long and acute COVID-19(14). It is present even after 100 days of the first symptom of acute COVID-19(3, 14). There are syndromes such as acute respiratory distress syndrome (ARDS), in which it has been observed that after a year, more than two-thirds of patients reported clinically significant fatigue symptoms(15). The symptoms observed in post-COVID-19 patients, resemble in part the chronic fatigue syndrome (CFS), which includes the presence of severe incapacitating fatigue, pain, neurocognitive disability, compromised sleep, symptoms suggestive of autonomic dysfunction, and worsening of global symptoms following minor increases in physical and/or cognitive activity(1620). Currently, myalgic encephalomyelitis (ME) or CFS is a complex and controversial clinical condition without established causative factors, and 90% of ME/CFS has not been diagnosed(21). Possible causes of CFS include viruses, immune dysfunction, endocrine-metabolic dysfunction, and neuropsychiatric factors. The infectious agents related to CFS have been Epstein-Barr virus, cytomegalovirus, enterovirus and herpesvirus (22). It is tempting to speculate that SARS-CoV-2 can be added to the viral agents' list causing ME/CFS.

Several neuropsychiatric symptoms have been reported, headache (44%), attention disorder (27%), and anosmia (21%). There are other symptoms reported, which were not included in the publications, including brain fog and neuropathy (23, 24). The etiology of neuropsychiatric symptoms in COVID-19 patients is complex and multifactorial. They could be related to the direct effect of the infection, cerebrovascular disease (including hypercoagulation)(25), physiological compromise (hypoxia), side effects of medications, and social aspects of having a potentially fatal illness(26). Adults have a double risk of being newly diagnosed with a psychiatric disorder after the COVID-19 diagnosis (26), and the most common psychiatric conditions presented were anxiety disorders, insomnia, and dementia. Sleep disturbances might contribute to the presentation of psychiatric disorders(27). Prompt diagnosis and intervention of any neuropsychiatric care is recommended for all patients recovering from COVID-19. An increase in mental health attention models in hospitals and communities is needed during and after the COVID-19 pandemic. Hair loss after COVID-19 could be considered as telogen effluvium, defined by diffuse hair loss after an important systemic stressor or infection, and it is caused because of premature follicular transitions from active growth phase (anagen) to resting phase (telogen). It is a self-limiting condition that lasts approximately 3 months, but it could cause emotional distress(28).

Dyspnea and cough were found in 24% and 19% of patients, respectively (Table 2, Fig. 2). In addition, abnormalities in CT lung scans persisted in 35% of patients even after 60–100 days from the initial presentation. In a follow-up study conducted in China among non-critical cases of hospitalized patients with COVID-19, radiographic changes persisted in nearly two-thirds of patients 90 days after discharge(29). Although most of the available studies do not include baseline pulmonary dysfunction or radiographic abnormalities, findings indicate improvement or resolution of abnormal CT findings. Previous data from recovered patients with other viral pneumonia(30, 31), also found residual radiographic changes. Abnormalities in pulmonary function, such as decreased diffusion capacity for carbon monoxide, were present among 10% of patients in this meta-analysis. Although these findings are not as high as compared to other available studies of survivors with COVID-19 or SARS, where the estimate of lung dysfunction is 53% and 28% respectively(32, 33), the reasons behind these differences could be distinct follow-up periods, definitions of pulmonary dysfunction, or characteristics of the patient population. Nevertheless, residual radiographic findings or lung function abnormalities require additional investigation on their clinical relevance and long-term consequences.

The immune-mediated tissue damage in COVID-19 involves cellular and humoral responses, but the immunity to SARS-CoV-2 and the protection to reinfection or a final viral (29, 34) clearance is unknown. Also, the reason why some patients experience long-term symptoms after COVID-19 is uncertain. This could be partially explained by host-controlled factors that influence the outcome of the viral infection, including genetic susceptibility, age of the host when infected, dose and route of infection, induction of anti-inflammatory cells and proteins, presence of concurrent infections, past exposure to cross-reactive agents, etc. Whether SARS-CoV-2 can cause substantial tissue damage leading to a chronic form of the disease such as the chronic lesions in convalescence observed in other viruses such as human immunodeficiency virus (HIV), hepatitis C virus (HCV), hepatitis B virus (HBV), and some herpesviruses is still unknown.

The results assessed in the present study are in line with the current scientific knowledge on other coronaviruses, such as those producing SARS and MERS, both sharing clinical characteristics with COVID-19, including post symptoms. Studies on SARS survivors have shown lung abnormalities months after infection. After a one-year follow-up, a study showed that 28% of the survivors presented decreased lung function and pulmonary fibrosis signs (33, 35, 36). In addition, MERS survivors showed pulmonary fibrosis (33%) (37). Regarding psychiatric symptoms, a study reported high levels of depression, anxiety, and post-traumatic stress disorder (PTSD) (26) in the long term in patients previously infected with other coronaviruses.

To assure that future healthcare providers, researchers, and educators recognize the effects of long-term COVID19 that are sex- and age-specific related, it is of high importance to classify the groups according to such variables to make better decisions about prevention, diagnosis and disease management.

Limitations of this systematic review and meta-analyses include the small sample size for some outcomes, which makes it difficult to generalize these results to the general population. The variation in the definition of some outcomes and markers and the possibility of bias. For example, several studies that used a self-reported questionnaire could result in reporting bias. In addition, the studies were very heterogeneous, mainly due to the follow-up time references and the mixture of patients who had moderate and severe COVID-19. All of the studies assessed had performed their internal pre-definition of symptoms, and therefore there is the possibility that important outcomes were not reported. Another limitation is that, given that COVID-19 is a new disease, it is not possible to determine how long these effects will last. In order to decrease heterogeneity and have a better understanding of the long-term effects of COVID-19, there is a need for studies to stratify by age, previous comorbidities, the severity of COVID-19 (including asymptomatic), as well as the duration of each symptom. To determine whether these long-term effects either complicate previous diseases or are a continuation of COVID-19, there is a need for prospective cohort studies. The baseline characteristics should be well established.

There is a need to standardize biological measures such as peripheral blood markers of genetic, inflammatory, immune, and metabolic function to compare studies. Besides studying pre-defined symptoms and markers, an open question should be included. Proper documentation in medical charts by health care providers and the flexibility and collaboration from the patients to report their symptoms are of equal importance.

Conclusions

More evidence and research from multi-disciplinary teams are crucial to understanding the causes, mechanisms, and risks to develop preventive measures, rehabilitation techniques, and clinical management strategies with whole-patient perspectives designed to address the after-COVID-19 care. From the clinical point of view, physicians should be aware of the symptoms, signs, and biomarkers present in patients previously affected by COVID-19 to promptly assess, identify and halt long COVID-19 progression, minimize the risk of chronic effects and help reestablish pre-COVID-19 health. Management of all these effects requires further understanding to design individualized, dynamic cross-sectoral interventions in Post-COVID clinics with multiple specialties, including graded exercise, physical therapy, continuous checkups, and cognitive behavioral therapy when required(38, 39).

Abbreviations

Acute respiratory distress syndrome (ARDS); Credible interval (CI); Coronavirus disease 2019 (COVID-19); chronic fatigue syndrome (CFS); C-reactive protein (CRP); computed tomography (CT); human immunodeficiency virus (HIV), hepatitis C virus (HCV), hepatitis B virus (HBV); Interleukin-6 (IL-6); N-terminal (NT)-pro hormone BNP (NT-proBNP); myalgic encephalomyelitis (ME); Middle East respiratory syndrome (MERS); Obsessive Compulsive Disorder (OCD); Post-traumatic stress disorder (PTSD); SARS-CoV-2: Severe acute respiratory syndrome coronavirus 2; Severe acute respiratory syndrome (SARS); post-traumatic stress disorder (PTSD).

Declarations

Ethical Approval and Consent to participate.

“Not applicable”

Consent for publication.

“Not applicable”.

Availability of supporting data.

All data relevant to the study are included in the article or uploaded as supplementary information.
Competing interests.
The authors are solely responsible for all content, and funders played no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. The authors declare that they have no competing interests. SLL is an employee of Novartis Pharmaceutical Company; the statements presented in the paper do not necessarily represent the position of the company. The remaining authors have no competing interests to declare.

Funding. This work was supported by grant R21NS106640 from National Institute for Neurological Disorders and Stroke (NINDS), and funds from Houston Methodist Research Institute, Houston, TX.

Authors' contributions. TWO and CP performed the statistical analysis. SLL, TWO, CP, RS, PR, and SV did the literature search, collected the data, wrote the manuscript and make edits. SLL and SV were mainly responsible for interpretation of the data and preparing the final version. SV did figures. All authors provided critical feedback and contributed to the final manuscript.
Acknowledgements.

“Not applicable”.

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