From H1N1 to COVID-19: What we have seen in children with hemoglobinopathies

Oliveira, Claudia de Melo; Soares, Victor Jablonski; Rechenmacher, Ciliana; Daudt, Liane Esteves; Michalowski, Mariana Bohns

doi:10.1016/j.clinsp.2021.100004

Abstract

This work aimed to better understand the impact of pandemics of respiratory viruses on children with hemoglobinopathies through a comprehensive review of the literature. MEDLINE, SCIELO, LILACS, and PUBMED were used as data sources to find articles without time period restrictions. Previous observations suggest that patients with hemoglobinopathies are a group especially susceptible to the complications of viral respiratory infections, with greater morbidity and mortality related to them. Within this context, this review found that, during the 2009 H1N1 pandemic, the risk of hospitalization in children and adults increased, especially in patients with a history of complications such as acute chest syndrome. In addition, the Coronavirus Disease 2019 (COVID-19) pandemic appears to have less repercussion among children with hemoglobinopathies compared to adults, similar to what is seen in the general population. In the H1N1 pandemic, patients with hemoglobinopathies behaved as a group more susceptible to complications, with increased morbidity and mortality. However, for COVID-19, the existing data to date on these patients do not show the same clinical impact. Thus, although these children deserve attention in case of infection due to their potential risks, they seem to have a favorable evolution.

Highlights

Children with hemoglobinopathies have less severe conditions with Coronavirus 2019 Disease (COVID-19) compared to adults, which is similar to that observed in the general population
In the H1N1 pandemic, patients with hemoglobinopathies behaved as the group most susceptible to complications, with increased morbidity and mortality

Introduction

In December 2019, a new coronavirus was identified by Chinese scientists in the city of Wuhan in Hubei, China, after studying patients with pneumonia of unknown origin.¹1 Huang C, Wang Y, Li X, Ren L, Zhao J, Hu Y, et al. Clinical features of patients infected with 2019 novel coronavirus in Wuhan. China. Lancet. 2020;395(10223):497-506. The virus called Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) spread quickly to other countries, challenging the economic, medical, and public health infrastructures.²2 Khan M, Adil SF, Alkhathlan HZ, Tahir MN, Saif S, Khan M, et al. COVID-19: a global challenge with old history, epidemiology and progress so far. Molecules 2020;26 (1):39. Existing studies have already shown that all age groups are susceptible to SARS-CoV-2 and that transmission occurs through oral fluid droplets. The spectrum of the disease varies from asymptomatic patients to cases in which the infection, named Coronavirus Disease 2019 (COVID-19), causes symptoms such as fever, cough, sore throat, fatigue, headache, and in more severe cases, acute respiratory syndrome, and multiple organ dysfunction.³3 Singhal T. A review of coronavirus disease-2019 (COVID-19). Indian J Pediatr 2020;87(4):281-6.

Hemoglobinopathies are a group of high prevalence diseases. With approximately 7% of the worldwide population being carriers, hemoglobinopathies are the most common monogenic diseases and one of the world's major health problems.⁴4 Weatherall DJ. Hemoglobinopathies worldwide: present and future. Curr Mol Med 2008;8(7):592-9. In this context, these patients have been impacted not only by COVID-19 but also by other pandemics of respiratory viruses that have affected the human population in recent decades, such as Influenza A (H1N1), in 2009. Considering that comorbid chronic diseases are strongly correlated with disease severity among COVID-19 patients,⁵5 Liu H, Chen S, Liu M, Nie H, Lu H. Comorbid chronic diseases are strongly correlated with disease severity among COVID-19 patients: a systematic review and meta-analysis. Aging Dis 2020;11(3):668-78. those with hemoglobinopathies could be at higher risk of worse prognosis, especially in the pediatric population. In this review, the authors describe the characteristics that make children with hemoglobinopathies a group that requires special attention and the already known impact of respiratory viruses on this population. The following electronic databases were used: MEDLINE, SCIELO, LILACS, and PUBMED.

Overview of hemoglobinopathies

Hemoglobinopathies are genetic disorders that affect hemoglobin molecules, a protein present in red blood cells. Most of the hemoglobinopathies result from mutations that alter the amino acid sequence of a globin chain, thus, changing the physiologic properties of the variant hemoglobin and producing the characteristic clinical abnormalities. Thalassemia syndromes, on the other hand, arise from mutations that impair the production or translation of globin mRNA, leading to deficient globin chain biosynthesis.⁶6 Dan Longo. Harrison’s Hematology and Oncology. 3rd ed. New York: McGraw-Hill Education; 2016. p. 84.

In relation to hereditary hemoglobinopathies, the most common are hemoglobin S, hemoglobin C, beta-thalassemia, hemoglobin E, and alpha thalassemia.⁴4 Weatherall DJ. Hemoglobinopathies worldwide: present and future. Curr Mol Med 2008;8(7):592-9. Sickle cell disease (SCD) is characterized by alteration of the two beta-globin genes, where at least one is an S gene. These sickle cells are more rigid and, therefore, can lead to pain, organ damage, and acute chest syndrome (ACS). These are the main known reasons for increased general morbidity and mortality in this patient population.

A hemoglobin disorders epidemiology study of 2008 estimates that 1.1% of couples in the world are at risk of having children with hemoglobinopathies, and 2.7 of every 1000 pregnancies are affected, with birthplace having a big impact on prognosis. If affected, children who are born in high-income countries have long-term survival with a chronic disorder, while the majority of those born in poor countries die before the age of five. Hemoglobinopathies are responsible for 3.4% of mortality in children younger than five years old around the world and for 6.4% in Africa.⁷7 Modell B, Darlison M. Global epidemiology of haemoglobin disorders and derived service indicators. Bull World Health Organ 2008;86(6):480-7. Approximately 1000 children with SCD are born in Brazil annually.⁸8 Ministério da Saúde. Relatório anual de dados do PNTN, 2014 a 2018. Brasília: Ministério da Saúde; c2020. Available from: https://www.camara.leg.br/proposicoesWeb/prop_mostrarintegra;jsessionid=node0g4c6wg3jnc2dhb7c3xzqfzvo5759849.node0?codteor=1918714&filename=Tramitacao-RIC+782/2020 [Cited October 6th, 2021].
https://www.camara.leg.br/proposicoesWeb...

Two retrospective studies described data and characteristics of SCD in Brazil and its mortality. Fernandes et al.⁹9 Fernandes AP, Januário JN, Cangussu CB, Macedo DL de, Viana MB. Mortality of children with sickle cell disease: a population study. J Pediatr (Rio J) 2010;86 (4):279-84. studied 1,396 children that had a hemoglobin profile compatible with SCD, collected in the Neonatal Screening Program in Minas Gerais. Among these cases, 78 patients died between 1998 and 2005; most of them (71.8%) were children younger than two years old. The main causes of death were infections (38.5%) and Acute Splenic Sequestration (16.6%). In another study, in-hospital mortality rates were described, and differences were observed between the states of the country: 2.0% in Bahia, 2.1% in Rio de Janeiro, and 1.0% in São Paulo. Moreover, mortality was approximately five times higher in adults than in children and adolescents. Variations in lethality probably reflect social differences between Brazil and other countries, as well as the regions in the country.¹⁰10 Loureiro MM, Rozenfeld S. Epidemiologia de internações por doença falciforme no Brasil. Rev Saude Publica 2005;39(6):943-9. Another retrospective study analyzed the mortality rate in 1,676 patients who had SCD and bthalassemia from 1998 to 2012 at HEMORIO where 281 patients died with a mortality rate of 10.8% for children (< 18 years old) and 18.87% for adults. The life expectancy was 21.3 years inferior to the general Brazilian population.¹¹11 Lobo CLC, Nascimento EMD, Jesus LJC, Freitas TG, Lugon JR, Ballas SK. Mortality in children, adolescents, and adults with sickle cell anemia in Rio de Janeiro, Brazil. Rev Bras Hematol Hemoter. 2018;40(1):37-42. Knowledge of these baseline data is important because it allows for the assessment of the impact of recent respiratory virus pandemics, such as H1N1 and COVID-19, on the survival of these patients.

H1N1 pandemic: what we learned

The first reported cases of H1N1 appeared in Mexico in February 2009. In April of the same year, the WHO declared H1N1 a public health emergency of global importance, and in June, when there had been reported more than 26,000 cases in 73 countries, the infection was considered a pandemic.¹²12 Fineberg HV. Pandemic preparedness and response - lessons from the H1N1 influenza of 2009. N Engl J Med 2014;370(14):1335-42. In a year and a half, the total number of deaths worldwide was approximately 20,000, and more than 214 countries were affected.¹³13 World Health Organization. Pandemic (H1N1) 2009 - update 112. Genebra: World Health Organization; c2010. Available from: https://www.who.int/csr/don/2010_08_06/en/ [cited May 8th, 2021].
https://www.who.int/csr/don/2010_08_06/e... This pandemic also had a significant impact on Brazil. The cumulative incidence in the country in 2009 was 28/100,000 inhabitants, with 52,827 confirmed cases. The case fatality rate reported by Rosseto and Luna was 3.9% (2,056/52,827) in 2009 and 12.4% (120/970) in 2010. Nevertheless, the authors called attention to the fact that the case-fatality rate was calculated using different populations, times, and places, creating biases in possible comparisons between the two periods. Moreover, they described limitations due to the quality of data collection, in addition to underreporting and lack of a prioritized record-keeping system for serious cases or those from risk groups.¹⁴14 Rossetto EV, Luna EJ. A descriptive study of pandemic Influenza A (H1N1) PDM09 In Brazil, 2009 - 2010. Rev Inst Med Trop Sao Paulo 2016;58:78.

SCD was one of the comorbidities reported among patients hospitalized during the H1N1 pandemic as they have a higher predisposition to organ complications and hypoxia.¹⁵15 Miller AC, Subramanian RA, Safi F, Sinert R, Zehtabchi S, Elamin EM. Influenza A 2009 (H1N1) virus in admitted and critically ill patients. J Intensive Care Med 2012;27(1):25-31. 2,200 children with SCD were evaluated in London from April to August 2009. According to this survey, approximately 40 children with SCD were diagnosed with H1N1, 50% of them were admitted to the hospital, and 25% developed acute chest syndrome. The hospitalization rate was considered higher compared to the general population, which was 7%.¹⁶16 Inusa B, Zuckerman M, Gadong N, Afif M, Arnott S, Heath P, et al. Pandemic influenza A (H1N1) virus infections in children with sickle cell disease. Blood 2010;115 (11):2329-30. Another study showed that patients with hemoglobinopathies, in general, had approximately three times more chances of being hospitalized.¹⁷17 Lenzi L, Mello ÂM de, Silva LR, Grochocki MH, Pontarolo R. Pandemic influenza A (H1N1) 2009: risk factors for hospitalization. J Bras Pneumol 2012;38(1):57-65. A retrospective cohort conducted by Johns Hopkins Hospital analyzed cases of influenza A, B, and H1N1 in children and young adults with SCD. It was found that those with H1N1 tended to be older, have asthma, develop ACS more frequently, and present more severe pain.¹⁸18 Strouse JJ, Reller ME, Bundy DG, Amoako M, Cancio M, Han RN, et al. Severe pandemic H1N1 and seasonal influenza in children and young adults with sickle cell disease. Blood 2010;116(18):3431-4. In addition, these patients needed intensive care more often, receiving more blood transfusions and antiviral treatments.

In another retrospective study, 48 patients with SCD diagnosed with H1N1 at the Cincinnati Children's Hospital Medical Center were evaluated.¹⁹19 George A, Benton J, Pratt J, Kim MO, Kalinyak KA, Kalfa TA, et al. The impact of the 2009 H1N1 influenza pandemic on pediatric patients with sickle cell disease. Pediatr Blood Cancer 2011;57(4):648-53. Among these, 23 (48%) patients had to be hospitalized, 10 of which were due to ACS. No patient needed mechanical ventilation or died. History of ACS and asthma were associated with higher rates of hospitalization and the likelihood of developing a new ACS. Furthermore, Colombatti et al.²⁰20 Colombatti R, Perrotta S, Masera N, Palazzi G, Notarangelo LD, Pusiol A, et al. Lessons learned from the H1N1 pandemic: the need to improve systematic vaccination in sickle cell disease children. A multi center survey in Italy. Vaccine 2011;29(6): 1126-8. conducted a retrospective study with 11 Italian Pediatric Hematology-Oncology Units, including data from 17 patients that were admitted for laboratory-confirmed H1N1 infection among 322 patients with SCD. Half of them had ACS and flu-like syndrome with vaso-occlusive crises. Also, 41% of the patients received a simple transfusion due to a fall in hemoglobin, while 29% underwent erythrocytapheresis.

Thus, the H1N1 pandemic showed that patients with SCD are especially susceptible to the complications of viral respiratory infections and have increased morbidity. Within this group, patients with a previous history of ACS and bronchial hyperreactivity were especially likely to need hospitalization and develop ACS.¹⁹19 George A, Benton J, Pratt J, Kim MO, Kalinyak KA, Kalfa TA, et al. The impact of the 2009 H1N1 influenza pandemic on pediatric patients with sickle cell disease. Pediatr Blood Cancer 2011;57(4):648-53. Even though these studies did not address any deaths by H1N1 in patients with SCD, critical illness was especially common in older patients compared to the children population.¹⁸18 Strouse JJ, Reller ME, Bundy DG, Amoako M, Cancio M, Han RN, et al. Severe pandemic H1N1 and seasonal influenza in children and young adults with sickle cell disease. Blood 2010;116(18):3431-4. The main studies on H1N1 and hemoglobinopathies and their results are described in Table 1.

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Table 1
Data from articles reporting H1N1 infection in patients with hemoglobinopathies.

SARS-CoV-2 pandemic: what we know so far

According to the WHO's international registry, on May 5^th, 2021, countries on all six continents had reported more than 150 million cases of COVID-19 and over 3.2 million deaths.²¹21 WHO Coronavirus. (COVID-19) Dashboard. Genebra: World Health Organization; c2020. Available from: https://covid19.who.int/ [cited May 8th, 2021].
https://covid19.who.int/... The Center for Disease Control COVID-19 Response Team has reported that, as of April 2^nd, 2020, only 1.7% of the COVID-19 cases reported occurred in pediatric patients, despite 22% of the US population being younger than 18 years old. It also estimated that 20% of these pediatric patients were hospitalized, compared to 33% adults aged 18-64 years.²²22 Patel NA. Pediatric COVID-19: Systematic review of the literature. Am J Otolaryngol 2020;41(5):102573. Considering the previous experience of vulnerability of children with hemoglobinopathies during the H1N1 pandemic, a significant increase in the morbidity and mortality of these patients during SARS-CoV-2 infection was also expected.²³23 Taher AT, Bou-Fakhredin R, Kreidieh F, Motta I, De Franceschi L, Cappellini MD. Care of patients with hemoglobin disorders during the COVID-19 pandemic: An overview of recommendations. Am J Hematol 2020;95(8):E208-10. The main studies on SARS-CoV-2 and children and their findings are summarized in Table 2.

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Table 2
Data from reported cases of SARS-CoV-2 infection in patients with hemoglobinopathies.

The Medical College of Wisconsin established the SECURE-SCD Registry to collect data on COVID-19 cases occurring globally in patients with SCD.²⁴24 Panepinto JA, Brandow AM, Singh A. Surveillance Epidemiology of Coronavirus (COVID-19) Under Research Exclusion. Wauwatosa: Medical College of Wisconsin; c2020. Available from: https://covidsicklecell.org/updates/2021-04-30/ [updated April 30th, 2021; cited May 8th, 2021].
https://covidsicklecell.org/updates/2021... Professionals were asked to report only COVID-19 confirmed cases and to do it only after resolution of acute illness or death. Until April 30^th, there were 784 registered cases. The mean age was 22.44 years old, with almost half of the patients being younger than 19 (48.1%). Of the total, 137 were asymptomatic, 431 had mild symptoms, 105 had moderate clinical severity, while 89 and 19 patients had severe and critical forms of the disease, respectively. Even though no statistical analysis of this data has been provided by the SECURE-SCD Registry hitherto, from a total of 19 deaths, only one was recorded on the < 19 years old group. Also, it is noteworthy that previous hospitalization for pain (equal to 3 or more in the last three years) was a common characteristic both in the total group (40.1%) and in those who died (68.4%).

Similar results were found in a real-time national survey on COVID-19 in hemoglobinopathy and rare inherited anemia patients.²⁵25 Telfer P, De la Fuente J, Sohal M, Brown R, Eleftheriou P, Roy N, et al. Real-time national survey of COVID-19 in hemoglobinopathy and rare inherited anemia patients. Haematologica 2020;105(11):2651-4. Sickle cell disease accounted for 166 of the 195 cases reported. There were 149 adults and 17 children (defined as ≤ 18 years). One hundred and twenty-eight (77.1%) SCD patients were admitted to the hospital, of whom 15 (11.7%), all adults, required non-invasive and/or mechanical ventilation. The outcomes of 142 patients with SCD with a completed course of infection were analyzed. A total of 131 (92.2%) recovered, while 11 (8.4%) died. The median age of patients who died was higher (51 years, ranging from 19 to 68 years) than those who recovered (31 years, ranging from 6 weeks to 72 years, p = 0.0042). No deaths occurred in children. The association of patient variables with survival was analyzed in SCD patients (n = 77) who were admitted to the hospital with a laboratory-confirmed COVID-19 diagnosis. The overall mortality in the group was 10.4%.

In contrast to the association of older age and male sex with the risk of COVID-19 related death in other populations, no significant correlation was found with age, sex, or SCD genotype. Mortality was higher in females and mild genotypes, although the differences were not significant. Patients with thalassemia accounted for 26 of the cohort. Two deaths were reported in transfusion-dependent patients 92y = HbH (cancer and splenectomy) and 53y = TDT (iron overload and diabetes); both had concurrent morbidities. Only three patients with rare inherited anemia (unstable hemoglobin Hb Köln: 2; hereditary elliptocytosis: 1) were reported. All received transfusion for acute hemolysis during the COVID-19 episode and subsequently recovered. Considering the presumed higher risk of infection for the patients with hemoglobinopathies, data on the hospitalization rate of these patients is also an important parameter. A retrospective cohort conducted by Singh et al.²⁶26 Singh A, Brandow AM, Panepinto JA. COVID-19 in individuals with sickle cell disease/trait compared with other Black individuals. Blood Adv 2021;5(7):1915-21. collected data to compare COVID-19 outcomes between individuals with SCD and sickle cell trait (SCT) and those without these diseases. The authors found that patients with COVID-19 and SCD remained at a higher risk of hospitalization (Relative Risk [RR=2.0]; 95% CI, 1.5-2.7) and development of pneumonia (RR=2.4; 95% CI, 1.6-3.4) and pain (RR=3.4; 95% CI, 2.5-4.8) compared with the group who do not have SCD or trait. On the other hand, the case fatality rates were not significantly different. There were also no significant differences in COVID-19 outcomes between individuals with SCT and control. This suggests that heterozygous patients have a different risk when affected by COVID-19 when compared to homozygous SCD. Although the age of patients was disregarded in this study, a different investigation found that young adults with SCD had a lower risk of intensive care unit admission when compared to older inpatients,²⁷27 Arlet JB, de Luna G, Khimoud D, Odièvre MH, de Montalembert M, Joseph L, et al. Prognosis of patients with sickle cell disease and COVID-19: a French experience. Lancet Haematol 2020;7(9):e632-4. but it lacks statistical power.

In another cohort, Minniti et al.²⁸28 Minniti CP, Zaidi AU, Nouraie M, Manwani D, Crouch GD, Crouch AS, et al. Clinical predictors of poor outcomes in patients with sickle cell disease and COVID-19 infection. Blood Adv 2021;5(1):207-15. analyzed 66 patients with SCD and COVID-19, of which nine were children, from five academic centers in the United States. In their study, it was possible to differentiate the characteristics of patients who were hospitalized from those who were not. There was no difference in SCD genotype or age among those who needed admission. However, the presence of chronic kidney disease and higher leukocyte count were associated with the need for hospitalization, while the use of SCD-modifying therapy was more common in outpatients. Among the seven deaths recorded in this study, none occurred in the pediatric age group. Overall, these studies suggest that patients with SCD are at higher risk of hospitalization due to COVID-19, especially those with previous comorbidities such as chronic kidney disease and of developing complications during the hospital stay in comparison with those without hemoglobinopathies.

Regarding thalassemia, most of the literature so far does not deal so much with prognosis and clinical impact but with infection rates. Nevertheless, with the course of the SARS-CoV-2 pandemic and epidemiological observations, the issue of a possible protective mechanism for patients with hemoglobinopathies arose. Lansiaux et al.²⁹29 Lansiaux E, Pébaÿ PP, Picard JL, Son-Forget J. COVID-19: beta-thalassemia subjects immunised? Med Hypotheses 2020;142:109-827. used multiple linear regression to observe the population of three Italian regions with a higher prevalence of heterozygosity for thalassemia and lower infection rates to formulate the hypothesis of immunity. However, the very limitations inherent in this study make the causal relationship questionable.

Furthermore, in a multicenter, retrospective, and cross-sectional study, Karimi et al.³⁰30 Karimi M, Haghpanah S, Azarkeivan A, Zahedi Z, Zarei T, Akhavan Tavakoli M, et al. Prevalence and mortality in β-thalassaemias due to outbreak of novel coronavirus disease (COVID-19): the nationwide Iranian experience. Br J Haematol 2020;190(3): e137-40. estimated the prevalence of COVID-19 in the general Iranian population. In April 2020, it was 11.01/10,000 inhabitants, while for the population with thalassemia, it was 8.17/10,000 (p = 0.24). Mortality was significantly higher in the latter group (26.6%) compared to the former (6.34%) (p = 0.001). In another study,³¹31 Littera R, Campagna M, Deidda S, Angioni G, Cipri S, Melis M, et al. Human leukocyte antigen complex and other immunogenetic and clinical factors influence susceptibility or protection to SARS-CoV-2 infection and severity of the disease course. The Sardinian experience. Front Immunol 2020;11:605688. a cohort of 182 patients with SARS-CoV-2 infection was analyzed. Nineteen had the genetic trait for beta-thalassemia, and none were in the group of severely ill patients. However, the molecular mechanism that supports that hypothesis of a possible protective mechanism, based on the SARS-CoV-2 attack on the 1-beta chain of hemoglobin, was rejected.³²32 DeMartino AW, Rose JJ, Amdahl MB, Dent MR, Shah FA, Bain W, et al. No evidence of hemoglobin damage by SARS-CoV-2 infection. Haematologica 2020;105(12): 2769-73. Other studies also do not correlate the increased severity of SARS-CoV-2 infection in patients with thalassemia syndromes.³³33 Motta I, Migone De Amicis M, Pinto VM, Balocco M, Longo F, Bonetti F, et al. SARS- CoV-2 infection in beta thalassemia: preliminary data from the Italian experience. Am J Hematol 2020;95(8):E198-9. Given the weak evidence, further research is needed to estimate a possible correlation between thalassemia and the COVID-19 infection rate.

Conclusion

The H1N1 and SARS-CoV-2 pandemics are recent in our history and have severely affected humankind, causing numerous deaths. Despite the effort of the scientific community, these viruses’ complete molecular mechanisms of action, as well as how they affect different populations, are still unclear. Thus, these understandings may help to minimize the impact and the number of deaths. Therefore, this literature review aimed to contribute to the care of children with hemoglobinopathies in the context of COVID-19.

Although there was great concern with patients with hemoglobinopathies in the COVID-19 pandemic due to the complications observed during the H1N1 pandemic, this population was not so severely affected. Moreover, the gathered data indicates that children with hemoglobin disorders have fewer symptoms and better outcomes when compared to adults. This finding is similar to that found by other reviews³⁴34 Vilela TS, Braga JAP, Loggetto SR. Hemoglobinopathy and pediatrics in the time of COVID-19. Hematol Transfus Cell Ther 2021;43(1):87-100. and could be related to the same protective mechanisms hypothesized for the general pediatric population.³⁵35 Zimmermann P, Curtis N. Why is COVID-19 less severe in children? A review of the proposed mechanisms underlying the age-related difference in severity of SARS-CoV- 2 infections. Arch Dis Child 2020. archdischild-2020-320-338. Nonetheless, some studies indicate that, as in the first pandemic, both adults and children with hemoglobinopathies may be at higher risk of hospitalization and intrahospital complications. Those with comorbidities, like chronic kidney disease, could be at an even higher risk. These data, however, should be looked at carefully since this is a heterogeneous group of diseases with different pathophysiologies in which the interaction with SARS-CoV-2 could result in different outcomes.

Acknowledgments

This research was supported by the Research and Event Incentive Fund (FIPE) of the Porto Alegre Clínicas Hospital (HCPA), 2020-0328.

References

¹
Huang C, Wang Y, Li X, Ren L, Zhao J, Hu Y, et al. Clinical features of patients infected with 2019 novel coronavirus in Wuhan. China. Lancet. 2020;395(10223):497-506.
²
Khan M, Adil SF, Alkhathlan HZ, Tahir MN, Saif S, Khan M, et al. COVID-19: a global challenge with old history, epidemiology and progress so far. Molecules 2020;26 (1):39.
³
Singhal T. A review of coronavirus disease-2019 (COVID-19). Indian J Pediatr 2020;87(4):281-6.
⁴
Weatherall DJ. Hemoglobinopathies worldwide: present and future. Curr Mol Med 2008;8(7):592-9.
⁵
Liu H, Chen S, Liu M, Nie H, Lu H. Comorbid chronic diseases are strongly correlated with disease severity among COVID-19 patients: a systematic review and meta-analysis. Aging Dis 2020;11(3):668-78.
⁶
Dan Longo. Harrison’s Hematology and Oncology. 3rd ed. New York: McGraw-Hill Education; 2016. p. 84.
⁷
Modell B, Darlison M. Global epidemiology of haemoglobin disorders and derived service indicators. Bull World Health Organ 2008;86(6):480-7.
⁸
Ministério da Saúde. Relatório anual de dados do PNTN, 2014 a 2018. Brasília: Ministério da Saúde; c2020. Available from: https://www.camara.leg.br/proposicoesWeb/prop_mostrarintegra;jsessionid=node0g4c6wg3jnc2dhb7c3xzqfzvo5759849.node0?codteor=1918714&filename=Tramitacao-RIC+782/2020 [Cited October 6th, 2021].
» https://www.camara.leg.br/proposicoesWeb/prop_mostrarintegra;jsessionid=node0g4c6wg3jnc2dhb7c3xzqfzvo5759849.node0?codteor=1918714&filename=Tramitacao-RIC+782/2020
⁹
Fernandes AP, Januário JN, Cangussu CB, Macedo DL de, Viana MB. Mortality of children with sickle cell disease: a population study. J Pediatr (Rio J) 2010;86 (4):279-84.
¹⁰
Loureiro MM, Rozenfeld S. Epidemiologia de internações por doença falciforme no Brasil. Rev Saude Publica 2005;39(6):943-9.
¹¹
Lobo CLC, Nascimento EMD, Jesus LJC, Freitas TG, Lugon JR, Ballas SK. Mortality in children, adolescents, and adults with sickle cell anemia in Rio de Janeiro, Brazil. Rev Bras Hematol Hemoter. 2018;40(1):37-42.
¹²
Fineberg HV. Pandemic preparedness and response - lessons from the H1N1 influenza of 2009. N Engl J Med 2014;370(14):1335-42.
¹³
World Health Organization. Pandemic (H1N1) 2009 - update 112. Genebra: World Health Organization; c2010. Available from: https://www.who.int/csr/don/2010_08_06/en/ [cited May 8th, 2021].
» https://www.who.int/csr/don/2010_08_06/en/
¹⁴
Rossetto EV, Luna EJ. A descriptive study of pandemic Influenza A (H1N1) PDM09 In Brazil, 2009 - 2010. Rev Inst Med Trop Sao Paulo 2016;58:78.
¹⁵
Miller AC, Subramanian RA, Safi F, Sinert R, Zehtabchi S, Elamin EM. Influenza A 2009 (H1N1) virus in admitted and critically ill patients. J Intensive Care Med 2012;27(1):25-31.
¹⁶
Inusa B, Zuckerman M, Gadong N, Afif M, Arnott S, Heath P, et al. Pandemic influenza A (H1N1) virus infections in children with sickle cell disease. Blood 2010;115 (11):2329-30.
¹⁷
Lenzi L, Mello ÂM de, Silva LR, Grochocki MH, Pontarolo R. Pandemic influenza A (H1N1) 2009: risk factors for hospitalization. J Bras Pneumol 2012;38(1):57-65.
¹⁸
Strouse JJ, Reller ME, Bundy DG, Amoako M, Cancio M, Han RN, et al. Severe pandemic H1N1 and seasonal influenza in children and young adults with sickle cell disease. Blood 2010;116(18):3431-4.
¹⁹
George A, Benton J, Pratt J, Kim MO, Kalinyak KA, Kalfa TA, et al. The impact of the 2009 H1N1 influenza pandemic on pediatric patients with sickle cell disease. Pediatr Blood Cancer 2011;57(4):648-53.
²⁰
Colombatti R, Perrotta S, Masera N, Palazzi G, Notarangelo LD, Pusiol A, et al. Lessons learned from the H1N1 pandemic: the need to improve systematic vaccination in sickle cell disease children. A multi center survey in Italy. Vaccine 2011;29(6): 1126-8.
²¹
WHO Coronavirus. (COVID-19) Dashboard. Genebra: World Health Organization; c2020. Available from: https://covid19.who.int/ [cited May 8th, 2021].
» https://covid19.who.int/
²²
Patel NA. Pediatric COVID-19: Systematic review of the literature. Am J Otolaryngol 2020;41(5):102573.
²³
Taher AT, Bou-Fakhredin R, Kreidieh F, Motta I, De Franceschi L, Cappellini MD. Care of patients with hemoglobin disorders during the COVID-19 pandemic: An overview of recommendations. Am J Hematol 2020;95(8):E208-10.
²⁴
Panepinto JA, Brandow AM, Singh A. Surveillance Epidemiology of Coronavirus (COVID-19) Under Research Exclusion. Wauwatosa: Medical College of Wisconsin; c2020. Available from: https://covidsicklecell.org/updates/2021-04-30/ [updated April 30th, 2021; cited May 8th, 2021].
» https://covidsicklecell.org/updates/2021-04-30/
²⁵
Telfer P, De la Fuente J, Sohal M, Brown R, Eleftheriou P, Roy N, et al. Real-time national survey of COVID-19 in hemoglobinopathy and rare inherited anemia patients. Haematologica 2020;105(11):2651-4.
²⁶
Singh A, Brandow AM, Panepinto JA. COVID-19 in individuals with sickle cell disease/trait compared with other Black individuals. Blood Adv 2021;5(7):1915-21.
²⁷
Arlet JB, de Luna G, Khimoud D, Odièvre MH, de Montalembert M, Joseph L, et al. Prognosis of patients with sickle cell disease and COVID-19: a French experience. Lancet Haematol 2020;7(9):e632-4.
²⁸
Minniti CP, Zaidi AU, Nouraie M, Manwani D, Crouch GD, Crouch AS, et al. Clinical predictors of poor outcomes in patients with sickle cell disease and COVID-19 infection. Blood Adv 2021;5(1):207-15.
²⁹
Lansiaux E, Pébaÿ PP, Picard JL, Son-Forget J. COVID-19: beta-thalassemia subjects immunised? Med Hypotheses 2020;142:109-827.
³⁰
Karimi M, Haghpanah S, Azarkeivan A, Zahedi Z, Zarei T, Akhavan Tavakoli M, et al. Prevalence and mortality in β-thalassaemias due to outbreak of novel coronavirus disease (COVID-19): the nationwide Iranian experience. Br J Haematol 2020;190(3): e137-40.
³¹
Littera R, Campagna M, Deidda S, Angioni G, Cipri S, Melis M, et al. Human leukocyte antigen complex and other immunogenetic and clinical factors influence susceptibility or protection to SARS-CoV-2 infection and severity of the disease course. The Sardinian experience. Front Immunol 2020;11:605688.
³²
DeMartino AW, Rose JJ, Amdahl MB, Dent MR, Shah FA, Bain W, et al. No evidence of hemoglobin damage by SARS-CoV-2 infection. Haematologica 2020;105(12): 2769-73.
³³
Motta I, Migone De Amicis M, Pinto VM, Balocco M, Longo F, Bonetti F, et al. SARS- CoV-2 infection in beta thalassemia: preliminary data from the Italian experience. Am J Hematol 2020;95(8):E198-9.
³⁴
Vilela TS, Braga JAP, Loggetto SR. Hemoglobinopathy and pediatrics in the time of COVID-19. Hematol Transfus Cell Ther 2021;43(1):87-100.
³⁵
Zimmermann P, Curtis N. Why is COVID-19 less severe in children? A review of the proposed mechanisms underlying the age-related difference in severity of SARS-CoV- 2 infections. Arch Dis Child 2020. archdischild-2020-320-338.

Publication Dates

Publication in this collection
16 Mar 2022
Date of issue
2022

History

Received
10 Aug 2021
Accepted
01 Nov 2021

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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[27] ²⁷
Arlet JB, de Luna G, Khimoud D, Odièvre MH, de Montalembert M, Joseph L, et al. Prognosis of patients with sickle cell disease and COVID-19: a French experience. Lancet Haematol 2020;7(9):e632-4.

[28] ²⁸
Minniti CP, Zaidi AU, Nouraie M, Manwani D, Crouch GD, Crouch AS, et al. Clinical predictors of poor outcomes in patients with sickle cell disease and COVID-19 infection. Blood Adv 2021;5(1):207-15.

[29] ²⁹
Lansiaux E, Pébaÿ PP, Picard JL, Son-Forget J. COVID-19: beta-thalassemia subjects immunised? Med Hypotheses 2020;142:109-827.

[30] ³⁰
Karimi M, Haghpanah S, Azarkeivan A, Zahedi Z, Zarei T, Akhavan Tavakoli M, et al. Prevalence and mortality in β-thalassaemias due to outbreak of novel coronavirus disease (COVID-19): the nationwide Iranian experience. Br J Haematol 2020;190(3): e137-40.

[31] ³¹
Littera R, Campagna M, Deidda S, Angioni G, Cipri S, Melis M, et al. Human leukocyte antigen complex and other immunogenetic and clinical factors influence susceptibility or protection to SARS-CoV-2 infection and severity of the disease course. The Sardinian experience. Front Immunol 2020;11:605688.

[32] ³²
DeMartino AW, Rose JJ, Amdahl MB, Dent MR, Shah FA, Bain W, et al. No evidence of hemoglobin damage by SARS-CoV-2 infection. Haematologica 2020;105(12): 2769-73.

[33] ³³
Motta I, Migone De Amicis M, Pinto VM, Balocco M, Longo F, Bonetti F, et al. SARS- CoV-2 infection in beta thalassemia: preliminary data from the Italian experience. Am J Hematol 2020;95(8):E198-9.

[34] ³⁴
Vilela TS, Braga JAP, Loggetto SR. Hemoglobinopathy and pediatrics in the time of COVID-19. Hematol Transfus Cell Ther 2021;43(1):87-100.

[35] ³⁵
Zimmermann P, Curtis N. Why is COVID-19 less severe in children? A review of the proposed mechanisms underlying the age-related difference in severity of SARS-CoV- 2 infections. Arch Dis Child 2020. archdischild-2020-320-338.

Author, year	Design	Study population	Main findings
Strouse et al.,¹⁸18 Strouse JJ, Reller ME, Bundy DG, Amoako M, Cancio M, Han RN, et al. Severe pandemic H1N1 and seasonal influenza in children and young adults with sickle cell disease. Blood 2010;116(18):3431-4. 2010	Retrospective cohort	123 SCD patients < 22 yo with diagnoses of influenza A (66); B (28); and H1N1 (29)	Patients with seasonal influenza were younger and less likely to have asthma. Patients with H1N1 more often developed ACS, severe pain, and illness requiring intensive care. The most frequent treatments used with these patients were antiviral agents, red blood cell transfusions, and exchange transfusions (10% for those with H1N1 vs. 3% for seasonal influenza, p=0.045). No patient died.
George et al.,¹⁹19 George A, Benton J, Pratt J, Kim MO, Kalinyak KA, Kalfa TA, et al. The impact of the 2009 H1N1 influenza pandemic on pediatric patients with sickle cell disease. Pediatr Blood Cancer 2011;57(4):648-53. 2011	Retrospective chart review	48 children with all forms of SCD and diagnosis of H1N1 or influenza A	The most common diagnosis in hospitalized patients was ACS. No mechanical ventilation was required, or death reported. History of ACS or reactive airway disease was correlated with a higher rate of admission and of ACS incidence during the acute illness.
Colombatti et al.,²⁰20 Colombatti R, Perrotta S, Masera N, Palazzi G, Notarangelo LD, Pusiol A, et al. Lessons learned from the H1N1 pandemic: the need to improve systematic vaccination in sickle cell disease children. A multi center survey in Italy. Vaccine 2011;29(6): 1126-8. 2011	Retrospective survey	17 patients < 17 yo with SCD and H1N1	15 HbS/HbS and 2 HbS/betha patients. Mean age: 7 years (range 1-17). 8 (47%) patients had ACS; 8 (47%), flu-like syndrome with vaso-occlusive crises; and 1 (6%), acute splenic sequestration. 7 (41%) patients received a simple transfusion and 5 (29%) underwent erythrocytapheresis.

Author, year	Design	Study population	Main findings
Telfer et al.,²⁵25 Telfer P, De la Fuente J, Sohal M, Brown R, Eleftheriou P, Roy N, et al. Real-time national survey of COVID-19 in hemoglobinopathy and rare inherited anemia patients. Haematologica 2020;105(11):2651-4. 2020	Real-time survey	195 patients (17 children) with confirmed and suspected diagnoses of COVID-19 and hemoglobinopathy or rare inherited anemia	166 patients had SCD; 26, thalassemia; and 3, rare inherited anemia. None required non-invasive and/or mechanical ventilation. No death was reported in this group.
Singh et al.,²⁶26 Singh A, Brandow AM, Panepinto JA. COVID-19 in individuals with sickle cell disease/trait compared with other Black individuals. Blood Adv 2021;5(7):1915-21. 2021	Retrospective cohort	624 black patients with diagnoses of COVID-19, 312 with SCD/SCT and 312 without SCD/SCT trait	Patients with SCD had a higher risk of hospitalization (RR = 2.0) and development of pneumonia (RR = 2.4) and pain (RR = 3.4) compared with those without SCD/SCT. The fatality rate was not significantly different. No comparison between adults and children was made.
Minniti et al.,²⁸28 Minniti CP, Zaidi AU, Nouraie M, Manwani D, Crouch GD, Crouch AS, et al. Clinical predictors of poor outcomes in patients with sickle cell disease and COVID-19 infection. Blood Adv 2021;5(1):207-15. 2021	Cohort	66 patients with SCD and diagnosis of COVID-19	Patients aged > 50 years, with preexisting cardiopulmonary, renal disease, and/or stroke who were not receiving hydroxyurea had as risk factors for death high serum creatinine, lactate dehydrogenase, and D-dimer levels, irrespective of genotype or sex. 75% required hospitalization, and 10.6% died. No children died.