Treatment of children with COVID-19: position paper of the Italian Society of Pediatric Infectious Disease

A statement of consensus was formulated after reviewing available literature on pediatric treatment strategies for COVID-19 by the Steering and Scientific Committee of the Italian Society of Infectious Pediatric Diseases in connection with the Italian Society of Paediatrics.

Since December 2019, severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection has been reported in Hubei province, China, and from there it spread worldwide. Starting from the end of February 2020, the number of cases of coronavirus disease 2019 (COVID-19) outside China rapidly increased, urging the World Health Organization (WHO) to declare COVID-19 as a pandemic on March 11 [1].

Most children with SARS-CoV-2 infection develop none or mild symptoms, needing only supportive treatment [2, 3]. However, few cases of severe COVID-19 in children have been reported [3,4,5], including multisystem inflammatory syndromes [6, 7].

As no evidence of at least good quality is available regarding therapy of COVID-19, treatment regimens of COVID-19 are not standardized. At present, few clinical trials for COVID-19 treatment involving children are ongoing [8]. Moreover, evidences are rapidly evolving and the therapeutic indications can change very quickly and even this work has changed quite a bit in the course of its writing.

To date, many national and international guidelines have been issued for the adult population [9,10,11]. However, there is a need of guidance on COVID-19 management in children from scientific societies and expert groups. Recently, an expert opinion has been released by a group of pediatric infectious disease specialists from North America, suggesting that supportive care alone is indicated for the overwhelming majority of cases [12].

The Italian Society of Pediatric Infectious Diseases steering and scientific committee developed a position paper on treatment of children with COVID-19, reviewing the current literature on this topic and providing indications based on the available literature data.

Since new evidences will be available in the next weeks/months, the Italian Society of Pediatric Infectious Diseases will guarantee to maintain treatment indication updated on the website www.sitip.org (updated English and Italian versions of the present document).

The consensus statement was formulated by the steering and scientific committee of the Italian Society of Pediatric Infectious Diseases in connection with the Italian Society of Pediatrics.

Decision was made after reviewing available literature on pediatric treatment strategies for COVID-19 at 16 June 2020 on Pubmed with the following search strategies: (SARS-CoV-19 OR COVID-19 OR Coronavirus) AND treatment. Moreover, national and international recommendations of WHO and scientific societies available online were evaluated. Ongoing clinical trials were searched on https://clinicaltrials.gov/ and https://www.aifa.gov.it/sperimentazioni-cliniche-covid-19.

Definitions

Clinical syndromes associated with COVID-19 in children were defined adapting the WHO classification as follows [13,14,15].

Asymptomatic case: infection identified during screening or contact tracing without symptoms.

Mild case: fever and/or fatigue and/or upper airways symptoms without radiological/ultrasound findings (if performed).

Moderate case: fever and/or fatigue and/or upper airways symptoms (cough or mild respiratory distress) and/or poor feeding and/or pneumonia identified with chest X-ray or ultrasound.

Severe case:

• Fever and cough, plus at least one of the following:

• Oxygen saturation on finger pulse (SpO2) < 92% on room air

• Severe respiratory distress (grunting, severe chest indrawing), cyanosis, intermittent apnea

• Fast breathing (regardless of fever and crying): respiratory rate (RR) in breaths/minute > 60 < 3 months; > 50 3–12 months; > 40 1–5 years; > 30 > 5 years)

• Systemic symptoms: drowsiness, lethargy, seizures, dehydration

Critical case :

• Pediatric acute respiratory distress syndrome (PARDS)

• Sepsis-associated organ dysfunction

• Septic shock

• Coma

PARDS was defined according to Pediatric Acute Lung Injury Consensus Conference Group definition [16].

Sepsis-associated organ dysfunction and septic shock were defined according to Surviving Sepsis Campaign definition [17].

Regardless of the early stage of the disease, the following indicators should be assessed as related to an increased risk of rapid progression to the severe/critical stage.

Clinical early warning indicators :

• Increased tachypnoea, despite 2 h of intravenous rehydration and low flow nasal cannula oxygen therapy

• Impaired consciousness

• Progressive increasing of lactate values

• Bilateral lung infiltration or multiple lobes involvement, pleural effusion or rapid progression of the lesions in a short period of time

• Age < 3 months

• Underlying diseases (congenital heart disease, bronchopulmonary dysplasia, anomalies of respiratory tract, abnormal hemoglobin, anemia, severe malnutrition, congenital or acquired immunodeficiency)

Multisystem inflammatory syndrome

Children and adolescents 0–19 years of age with fever > 3 days AND two of the following:

• Skin rash or bilateral non-purulent conjunctivitis or muco-cutaneous inflammation signs (oral, hands or feet)

• Hypotension or shock

• Signs of myocardial dysfunction, pericarditis, valvulitis, or coronary abnormalities (including echocardiography findings or elevated Troponin/NT-proBNP)

• Evidence of coagulopathy

• Acute gastrointestinal problems (diarrhea, vomiting, or abdominal pain)

AND

Elevated markers of inflammation such as erythrocyte sedimentation rate, C-reactive protein, or procalcitonin.

AND

No other obvious microbial cause of inflammation, including bacterial sepsis, staphylococcal or streptococcal shock syndromes.

AND

Evidence of COVID-19 (positive real-time polymerase chain reaction, antigen test or serology), or a likely contact with patients with COVID-19.

Treatment approach based on the different scenarios

Asymptomatic cases: no treatment.

Moderate and mild cases: only antipyretic therapy.

Severe and critical cases :

all these drugs should be preferably administered within a clinical trial.

Warning: Hydroxychloroquine can cause QTc prolongation. Every 2 days perform electrocardiogram (ECG) and QTc assessment for QTc prolongation increased risk. For hydroxychloroquine, carry out glucose 6 phosphate dehydrogenase (G6PDH) dosage in case of risk factors for deficiency.

Remdesivir should be administered in patients with normal renal function. Liver function assessment should be performed in all patients prior to starting remdesivir and every other day while receiving remdesivir.

Duration of therapy: 5–7 days, extendable according to clinical course.

Immunomodulating therapy:

This therapy must be considered in case of:

- ARDS or progressive deterioration of respiratory function.

- Multisystem inflammatory syndrome.

- Marked alteration or increasing trend of IL-6 and/or D-dimer and/or ferritin and/or C-reactive protein.

- Interval of at least 7 days from the beginning of the symptoms.

The available dosages and formulations of the various drugs are indicated in the text. COVID-19 management and treatment in children, according to disease severity, are reported in Table 1.

Supportive care

Antipyretic therapy: prefer paracetamol (10–15 mg/kg every 4–6 h) in case of fever > 38.5 °C. Avoid ibuprofen in case of dehydration, vomiting and diarrhea, as it is associated with an increased risk of kidney failure. Some authors have suggested a correlation between the use of ibuprofen and an unfavorable course of SARS-Cov-2 infection [19]. However, these data are not currently confirmed and the European Medicines Agency does not contraindicate the use of non-steroidal anti-inflammatory drugs [20].

Inhalation therapy: if topic steroids and/or bronchodilators are needed (e.g. patient with recurrent wheezing undergoing exacerbation and suggestive symptoms or confirmed SARS-Cov-2 infection) the use of pressurized suspensions with spacer chamber is suggested. Conversely, the use of nebulisers is not recommended in order to avoid particles aerosolization and increased contagiousness.

Ongoing steroid treatment should not be stopped [21].

Venous thromboembolism prophylaxis: severe COVID-19 seems to be associated in adults with an increased risk of disseminated intravascular coagulation and venous thromboembolism. A study on 449 adult patients with severe infection showed a lower mortality rate in those receiving anticoagulant therapy [22]. Therefore, recently adults protocols suggest strategies for prevention and management of coagulative disorders secondary to COVID19 infection with low molecular-weight heparin, especially in case of ARDS [13, 23]. However, children have a much lower incidence of thrombotic complications than adults, even under higher risk conditions such as major surgery or polytrauma [24]. Therefore, such prophylaxis is not routinely suggested in children.

An exception can be made for neonatal age and adolescents, where constitutionally the incidence of thrombotic complications is higher [25]. Preventive anticoagulant therapy can therefore be considered for these age groups, in cases where severe inflammatory conditions occur and therefore hyperactivation of the clotting process could lead to the appearance of important thrombotic complications.

The suggested treatment is with subcutaneous enoxaparin 100–200 U/kg/day, that can be increased to 150–300 U/kg/day in neonates.

Antiviral treatment

Lopinavir/ritonavir

Lopinavir/ritonavir is a boosted protease inhibitor, used, in association with other drugs, in the therapy of Human Immunodeficiency Virus (HIV) infection, starting from the age of 14 days of live [26].

Its security profile is well known, as it has been largely used in HIV infections in the pediatric age,

It is available both in oral suspension and tablets.

On the base of some clinical trials, the Chinese guideline on SARS-Cov-2 pneumoniae recommend the early use of lopinavir/ritonavir [27].

On 18 March 2020, the results of a double blinded, randomized, open-label trial, which compared lopinavir/ritonavir associated to standard of care and standard of care alone, on 199 SARS-Cov-2 pneumonia hospitalized patients, have been published on New England Journal of Medicine [28]. The study did not evidence any statistically significant differences in the clinical improvement. Mortality at 28 days showed a 5.8% difference in favor of lopinavir/ritonavir use, although not statistically significant (95% Confidence Interval, CI95%: − 17.3-5.7). Patients in which lopinavir/ritonavir therapy has been started before the 12 days of symptoms had a significantly reduction of symptoms duration, hazard ratio: 1.25 (95%CI, 1.77–2.05). Data about mortality, stay in Intensive Care Unit and duration of hospitalization were not stratified for the start of therapy before and after 12 days. The results of this study cannot be transferred to pediatric population, to patients with mild-moderate symptoms, and to patients who underwent an early therapy.

Currently, American guidelines on COVID-19 treatment published in May 2020, recommend both in children and adults to use lopinavir/ritonavir only in the context of clinical trials, given the lack of effectiveness reported now in literature [9, 12]. The latest Chinese guidelines on SARS-Cov-2 pneumoniae do not recommend the use of a specific antiviral for the treatment of COVID-19, and nevertheless include lopinavir/ritonavir among the available therapeutic options for hospitalized patients [29]. Less than 40 clinical trials are currently registered to evaluate the effectiveness of lopinavir/ritonavir against COVID-19.

Lopinavir/ritonavir is not indicated in premature neonates before the 42 weeks of corrected age and in all cases before 14 days of live [30].

Available formulations:

Lopinavir/ritonavir tablets (200 mg + 50 mg).

Lopinavir/ritonavir oral suspension (80 mg + 20 mg/mL), which must be conserved in the fridge.

Dosage:

• Adults: 400/100 mg (2 tablets) twice a day

• 14 days − 12 months: 300 mg/75 mg/m² (corresponding to a 3.75 mL/kg) twice a day OR 16/4 mg/kg (corresponding to 0.2 mL/kg) twice a day

• > 12 months - 18 years: if < 15 kg: 12/3 mg/kg (corresponding to 0.15 mL/kg) twice a day; if > 15 kg: 10/2.5 mg/kg (corresponding to 0.125 mL/kg) twice a day

Simplified dosage

• if > 15 kg and able to swallow tablets:

15–25 kg: 1 tablet twice a day.

> 25 kg–35 kg: 1 + ½ tablet twice a day.

> 35 kg: 2 tablets twice a day

• if < 15 kg or unable to swallow tablets:

7–10 kg: 1.25 mL twice a day.

10–15 kg: 1.75 mL twice a day.

15–20 kg: 2.25 mL twice a day.

20–25 kg; 2.75 mL twice a day.

25–30 kg: 3.5 mL twice a day.

30–35 kg: 4 mL twice a day.

35–40 kg: 4.75 mL twice a day.

> 40 kg: 5 mL twice a day.

Remdesivir

Remdesivir is a nucleotide analogue, which is incorporated in the viral RNA chain, determining its premature termination. It has been developed from Gilead in 2017 for Ebola therapy. In vitro studies, its high spectrum efficacy against different coronavirus has been demonstrated [31, 32].

Interestingly, remdesivir seems to have a high genetic barrier to viral resistance development (demonstrated in SARS studies). It has a short plasmatic half-life, but it is rapidly converted into its active form (in 2 h from the infusion) and it has a 14 h intracellular half-life [33].

In May 2020, following an assessment of the emergency use authorization criteria and available scientific evidence, the FDA issued an emergency use authorization allowing for the administration of remdesivir intravenously by health care providers for the treatment of COVID-19 suspected or laboratory-confirmed in adults and pediatric patients hospitalized with severe disease [34].

In a guidance approved by the American Pediatric Infectious Diseases Society for COVID-19 treatment in children, if an antiviral is used, panel suggested remdesivir as the preferred agent [12]. Antivirals should preferably be used as part of a clinical trial, if available.

However, a warning has been issued on the co-administration of remdesivir and chloroquine phosphate or hydroxychloroquine sulfate as it may result in reduced antiviral activity of remdesivir [34].

As at 26 June 2020, there are 39 ongoing trials evaluating clinical efficacy of this drug in the therapy of moderate and severe SARS-Cov-2 infections [35]. Four studies (GS-US-540-5774, GS-US-540-5773, GS-US-540-5821 and GS-US-540-5823) are currently ongoing in Italy. All these studies are sponsored by Gilead and only one study involve children from birth to 18 years whereas the other three enroll children older than 12 years and adults [36].

Dosage:

• Adults: 1st day 200 mg IV in 30 min, followed by 100 mg IV /day for other 9 days

• Children (< 40 kg): 1st day 5 mg/kg IV (in 30 min), followed by 2.5 mg/kg IV (in 30 min)/day for other 9 days.

At present, the dosage has not been established for the first 2 weeks of life and weight < 2.5 kg.

Hydroxychloroquine

Hydroxychloroquine (and chloroquine) could have an antiviral activity [37]. The mechanism is currently not fully clarified. However, in vitro studies suggest that they could act by increasing the endosomal pH required for virus / host cell fusion and interfering with the glycosylation of the SARS-Cov-2 cell receptor [38]. In particular, hydroxychloroquine appears to have better in vitro activity towards SARS-CoV-2. The anti-inflammatory activity of these molecules, through the inhibition of the production of Interleukin (IL) -6 and Tumor Necrosis Factor (TNF)-α, could contribute to their effectiveness. In addition, these molecules have been in use for decades, showing a good safety profile. Compared to chloroquine, hydroxychloroquine is a drug more readily available and with a higher safety profile [39].

In February 2020, a panel of experts in China summarized the results of the use of chloroquine (500 mg every 12 h for 10 days) in adults with COVID-19, suggesting that its use would be associated with an improvement in the clinical success rate, reducing the hospitalization and improving the outcome [40].

Since then, hydroxychloroquine has been widely used in adult patients [41, 42]. To date, there are more than 200 registered clinical trials for pre-exposure or post-exposure prophylaxis of SARS-CoV-2 infection, and treatment of patients with mild, moderate, and severe COVID-19 [35].

However, it is not yet clear if the benefits outweigh the risks, especially in children. In fact, on 24 April 2020, the FDA warned against the use of hydroxychloroquine or chloroquine for COVID-19 outside hospital or clinical trial setting due to the risk of QT interval prolongation and ventricular tachycardia [43]. This risk could be also increased when combined with some antibiotics such as azithromycin.

Moreover, since the majority of children manifest only mild symptoms, a widespread use of hydroxychloroquine may confer only minimal benefit. Furthermore, pharmacokinetic modeling and simulation used to identify pediatric-specific dosages for hydroxychloroquine have raised concerns on plasma exposures lower than those needed to mediate an antiviral effect [44]. However, these findings do not exclude a potential utility of hydroxychloroquine for COVID-19 treatment based on different mechanisms of action, such as immunomodulation. Conclusive data are needed from ongoing trial to understand the possible role of this drug in children with COVID-19.

Available formulations:

Hydroxychloroquine tablets 200 mg.

Dosage:

Adults: 400 mg twice a day the first day, followed by 200 mg twice a day for overall 5–7 days.

Children: 6 mg/kg (maximum: 400 mg/dose) twice a day on day 1, followed by 3 mg/kg (maximum: 200 mg/dose) twice a day for up to 5 days. *.

* hydroxychloroquine solution preparation is recommended for children.

Precautions for use:

Perform ECG before administering the drug to rule out long QT.

In case of risk factors, dose G6PDH before use.

Other antiviral therapy

Favipiravir is an antiviral drug authorized in Japan for the treatment of flu. It works by inhibiting RNA polymerase-RNA-dependent. The medicine is not authorized in Europe or in the USA.

Preliminary results on 80 patients with non-serious SARS-Cov-2 infection, published only in Chinese, seems to show a better efficacy of this drug compared to lopinavir/ritonavir [37].

Few clinical trials are currently undergoing to evaluate the efficacy of Favipiravir in SARS-Cov-2 infection and the AIFA Scientific Technical Commission approved a clinical trial program for this drug [36, 45].

Ivermectin, an FDA-approved anti-parasitic, seems to have broad-spectrum anti-viral activity in vitro, is an inhibitor of the causative virus (SARS-CoV-2), 2 h post infection with SARS-CoV-2 able to effect 5000-fold reduction in viral RNA at 48 h [46]. A single center, double-blind, randomized, placebo-controlled trial is ongoing on ivermectin efficacy in reducing SARS-CoV-2 viral load in adult patients with low risk, non-severe COVID-19 [47].

Immunomodulant treatment

Steroids

At present, there are no clear evidences to support the use of systemic steroids during SARS-Cov-2 infection unless specific needs (e.g. asthmatic patient who does not respond to 3 doses of bronchodilator, severe allergic reaction). In particular, in patients on chronic systemic or inhaled steroid therapy, treatment stopping is not necessary. Some data suggest that methylprednisolone could have an immunomodulating activity in case of ARDS, decreasing the risk of death [48]. Its use is also indicated in case of a worsening of pulmonary function after at least 7 days from the beginning of symptoms, in association with marked alteration or tendency to increasing of IL- 6 and/or D-dimer and/or ferritin and/or C-reactive protein.

In these cases, can be used:

- Methylprednisolone 1–2 mg / kg (max 80 mg) once a day.

A short course is indicated (2–5 days).

In severe cases high doses (methylprednisolone 30 mg/kg) can be considered.

Recently some good results were reported by the interim analysis of the RECOVERY trial [49], a study where 2104 adult patients were randomised to receive dexamethasone 6 mg once per day (either orally or intravenously) for 10 days and 4321 patients were randomised to usual care alone. Dexamethasone significantly reduced deaths by one-third in ventilated patients (relative risk, RR 0.65) and by one fifth in those receiving only oxygen (RR 0.80), but there was no benefit among patients who did not require respiratory support. Based on these results, a treatment with dexamethasone (0.2–0.4 mg/kg, maximum 6 mg) in patients requiring oxygen should be considered.

Anakinra

The multisystem inflammatory syndrome reported in patients with COVID-19 shares considerable biochemical overlapping with the cytokine storm complicating macrophage activation syndrome associated with rheumatic disease. Anakinra is licensed for treating people with rheumatoid arthritis, aged at least 8 months. This is a 17 kD recombinant, non-glycosylated human IL-1 receptor antagonist who inhibits the proinflammatory cytokines interleukin (IL)-1α and IL-1β, with a short half-life of about 3–4 h and good safety profile. Anakinra has also been used with some success to treat macrophage activation syndrome caused by various inflammatory conditions.

Several case series report that Anakinra reduced both need for invasive mechanical ventilation in the intensive care unit and mortality among patients with severe forms of COVID-19, without serious side-effects [50, 51]. Currently, there are 10 ongoing clinical trials on Anakinra use in COVID-19, all in adults [52]. However, there are few pediatric reports of children treated with Anakinra showing that such treatment in serious cases can be safe and beneficial [53, 54].

Indeed, anakinra has been proposed as the best option if such treatment is considered necessary, because it has a relatively short half-life and may be discontinued rapidly in case of adverse effect or concern of worsening the infection [55]. Anakinra can be administered intravenously (off label) or subcutaneously and has a wide therapeutic window; when anakinra is effective for cytokine storm syndromes, it works within 2 to 3 days [56].

Therapeutic scheme:

• Anakinra vial 100 mg/0.67 ml

• intravenously: 8–10 mg/kg/day in 2 or 4 administrations depending on the total dose (up to a maximum of 100 mg 4 times a day)

After 48–72 h, repeat the plasma dosage of IL-6 and/or D-dimer.

Tocilizumab

Tocilizumab is a recombinant humanized monoclonal antibody belonging to the G1 immunoglobulin subclass and directed against both soluble and membrane IL-6 receptors [57].

This drug is indicated for the treatment of moderate and severe rheumatoid arthritis, systemic juvenile idiopathic arthritis (from the age of 1 year), juvenile idiopathic polyarthritis (from the age of 2 years) and severe release of cytokines induced by CAR-T lymphocytes (chimeric antigen receptor t cell) (from the age of 2 years).

Studies suggested that the alveolar damage in COVID-19 is caused by a cytokine storm (including IL-6) and that symptoms improve with the use of Tocilizumab [58, 59].

Based on these results, different clinical trials have been started. The Italian multicenter study TOCIVID-19 has been promoted by the National Cancer Institute, IRCCS, G. Pascale Foundation, Naples. The recruitment of the prospective phase has been completed, while the observational study continues. The protocol includes the enrollment of patients of any age.

Two other studies started at the end of March in Italy, but not enrolling pediatric patients. One of them, aimed at assessing the efficacy of the early tocilizumab administered early in patients suffering from recently emerging Covid-19 pneumonia and requiring hospital care but not invasive or semi-invasive ventilation, was concluded early because it was not effective [36].

Therapeutic scheme:

• Tocilizumab vial 20 mg/mL

• First infusion at a dosage of 10–12 mg/kg < 30 kg and 8 mg/kg > 30 kg, (maximum dosage 800 mg, duration of infusion at least 60 min)

• Second infusion 12 h after the first (at the discretion of the doctor, in case of no response)

• A possible third infusion after 24 h may be considered.

After 24 h from the last administration, repeat the plasma dosage of IL-6 and / or D-dimer.

When to use biologic drugs:

• Serious or critical cases.

• End of the initial phase of high viral load of COVID-19 (afebrile> 72 h and/or at least 7 days after the onset of symptoms).

• High levels of IL-6 (> 40 pg/ml); alternatively, high levels of d-dimer and/or PCR and/or ferritin and/or fibrinogen increasing progressively.

When not to use biologic drugs:

• AST / ALT value above 5 times normal levels.

• Neutrophils value lower than 500 cells/mL.

• Platelets value lower than 50,000 cells /mL.

• Documented sepsis from other pathogens other than COVID-19.

• Presence of comorbidities related, according to clinical judgment, to an unfavorable outcome.

• Complicated diverticulitis or intestinal perforation.

• Immunomodulating and anti-rejection therapy.

• Known hypersensitivity to the drug.

It is also recommended to avoid administration of biologics if anti-MRPV vaccination has been carried out in the past 30 days.

If possible, before starting therapy:

• Quantiferon test

• HBV and HCV markers

Other immunomodulant therapies

In view of the fact that the alveolar damage of severe forms of SARS-Cov-2 infection is caused by a cytokine storm [60], two other clinical trials have been started in Italy on the use of emapalumab (anti-interferon gamma monoclonal antibody) and associated anakinra (IL-1 receptor antagonist) and the use of sarilumab (monoclonal antibody that binds to the IL-6 receptor). A Belgian study comparing tocilizumab, anakinra and siltuximab is going to start soon.

Information and forms relating to the studies are available on AIFA website, but there is no prevision for enrollment of pediatric patients [36].

Among the new therapies planned for the future is the infusion of hyperimmune plasma from cured patients. This approach, already used in China and previously for Ebola and SARS, seems to give good results at least in the most serious cases. In the USA 3 studies have been launched that will evaluate this approach [61].

Antibiotic therapy

The choice to add empirical antibiotic therapy should only be made if there is reasonable evidence of bacterial superinfection. An increased procalcitonin, C-reactive protein and the presence of neutrophilic leukocytosis represent laboratory parameters suggestive of bacterial infection. From a clinical point of view, the persistence of fever for more than 3 days can be suggestive of bacterial infection [62]. Tests for atypical bacteria (i.e. mycoplasma) should be performed in case of clinical suspect, in order to start targeted therapy.

The start of an empirical antibiotic therapy is also recommended in the presence of comorbidities, such as immunodeficiency, cystic fibrosis, other chronic diseases of the respiratory tract, severe neuromotor disability.

In case of productive cough, the collection of a sputum sample for culture examination before the start of antibiotic therapy would be indicated.

In patients without risk factors, we recommend:

• Amoxicillin 90 mg /kg/day in 3 doses, in case of possible oral intake

• Ceftriaxone 80–100 mg/kg/day, in case of impossibility of oral intake. This drug is also recommended for the possibility of administering once a day and therefore reducing the risks for healthcare professionals.

Azithromycin

Preliminary data have suggested a possible efficacy of azithromycin in combination with hydroxychloroquine as a background therapy for SARS-Cov-2 infection. The exact role of this drug in COVID-19 is unknown, as no in vitro data are available at present. It has been supposed a dual role, antiviral and anti-inflammatory. The anti-inflammatory action of azithromycin has been already demonstrated in many conditions. Regarding the theoretical antiviral activity, the first published study was on a small sample size (36 patients, of whom only 6 receiving the combination of azithromycin/hydroxychloroquine) [41]. In this study, by Gautret and colleagues, 100% of the patients taking hydroxychloroquine and azithromycin had negative nasopharyngeal swab 6 days from the start of therapy, compared to 57.1% of the hydroxychloroquine alone and 12.5% ​​of the control group. The same results have been replicated in a larger population [63]. However, a more recent study on virological and clinical results of 11 adult patients with a serious disease raises doubts about the antiviral efficacy of this combination, as it reports results in contrast with those of Gautret et al. [64].

This combination have been also evaluated in a larger observational study including 1061 adults, resulting to be safe and associate with a very low fatality rate. However, its efficacy has been doubted in a study on a large adult population in New York among hospitalized patients with COVID-19, where treatment with hydroxychloroquine, azithromycin, or both were not associated with significantly lower in-hospital mortality [65]. Considering the lack of a strong rationale and the absence of evidence of certain effectiveness in the treatment of COVID-19 patients, the use of azithromycin should be considered carefully and the QTc interval strongly monitored. In fact, on April 2020, European Medicines Agency (EMA) warned about risk of serious side effects particularly if associated with chloroquine and hydroxychloroquine [66].

Dosage:

• Adults: 500 mg the first day, then 250 mg/day for other 4 days

• Children: 15 mg/kg the first day, then 7.5 mg/kg once a day for other 4 days

Drug interactions

The drugs used for the therapy of SARS-Cov-2 infection, especially lopinavir/ritonavir and azithromycin/ hydroxychloroquine, can have interactions with other drugs.

Before administering those treatment, evaluate possible interactions on drugs [67].

Informed consent

For all drugs, consent for off-label use must be requested and the procedures provided by the reference Healthcare Company must be followed.

As for Remdesivir, since it is an experimental drug, the procedures for compassionate use must be followed.

In conclusion this position paper summarizes the suggested treatments in COVID-19 infected children based on a review of the current literature carried out by the Scientific Committee of the Italian Society of Infectious Pediatric Diseases. Since most SARS-CoV-2 infections in children have a benign course, pharmacological treatment, other than supportive therapy, should be reserved to those with more severe cases.

As new evidences are expected to be available in the next weeks/months, the Italian Society of Pediatric Infectious Diseases will guarantee to maintain treatment indication updated on the website www.sitip.org

All the publication are listed in bibliography.

AIFA:

Agenzia Italiana del Farmaco

AST / ALT:

Aspartate & Alkaline transaminase

COVID-19:

Coronavirus 2019

ECG:

electrocardiogram

FDA:

Food and Drug Administration

HIV:

Human Immunodeficiency Virus

PARDS:

Pediatric acute respiratory distress syndrome

SARS-CoV-2:

severe acute respiratory syndrome coronavirus 2

SpO2:

Oxygen saturation

TNF:

Tumor Necrosis Factor

WHO:

World Health Organization

Not applicable.

No funding was received.

1. Venturini Elisabetta and Montagnani Carlotta contributed equally to this work.

Authors and Affiliations

1. Infection Disease Unit, Meyer Children’s University Hospital, Florence, Italy

   Elisabetta Venturini & Carlotta Montagnani

2. Pediatric Infectious Disease Unit, Regina Margherita Children’s Hospital, University of Turin, Turin, Italy

   Silvia Garazzino

3. Division of Pediatric Infectious Diseases, Department for Woman and Child Health, University of Padua, Padua, Italy

   Daniele Donà

4. Pediatric Emergency Unit, Policlinico di Sant’Orsola, Bologna, Italy

   Luca Pierantoni

5. Department of Translational Medical Science, Section of Pediatrics, University of Naples Federico II, Naples, Italy

   Andrea Lo Vecchio

6. UOC Pediatria, San Martino Hospital, Belluno, Italy

   Giangiacomo Nicolini

7. Department of Pediatrics, ASST Santi Paolo e Carlo Hospital, Milan, Italy

   Sonia Bianchini

8. Universitarian-Hospital Department Ospedale Bambino Gesù IRCCS, Rome, Italy

   Andrzej Krzysztofiak, Alberto Villani & Guido Castelli-Gattinara

9. Department of Health Sciences, University of Florence, Florence, Italy

   Luisa Galli

Consortia

Contributions

All authors contribute to prepare the manuscript read and approved the final version.

Corresponding author

Correspondence to Guido Castelli-Gattinara.

Ethics approval and consent to participate

Not applicable.

Consent for publication

All authors have agreed to the publication.

Competing interests

All authors declared that there is no competing interest.

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