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. 2020 Aug 6;11:964. doi: 10.3389/fphar.2020.00964

Serious Adverse Drug Reactions and Safety Signals in Children: A Nationwide Database Study

Jean Mendes de Lucena Vieira 1, Guacira Corrêa de Matos 1, Fabrício Alves Barbosa da Silva 2, Louise E Bracken 3, Matthew Peak 3, Elisangela da Costa Lima 1,*
PMCID: PMC7424036  PMID: 32848722

Abstract

Children are more exposed to inappropriate medicine use and its consequent harms. Spontaneous reporting of suspected Serious Adverse Drug Reactions (SADR) increases knowledge and prevention of pharmacotherapy risk. Disproportionality measures are useful to quantify unexpected safety issues associated with a given drug-event pair (signals of disproportionality). This cross-sectional study aimed to assess SADR reporting and safety signals for Brazilian children from 0-12 years old, notified between January 2008 and December 2013 from the Brazilian Surveillance Agency (Notivisa). Information from serious reports (gender and age of the patient, event description, suspected drug) was included. Disproportionality analysis based on Reporting Odds Ratios with a confidence interval of 95% was conducted to identify possible signals of disproportionate reporting (SDR). Almost 30% of 1,977 suspected SADR was related to babies (0-1-year-old). 69% of reports happened with intravenous dosage forms, and 35% of suspected SADR involved off label use according to age. Laronidase, miglustat, imipenem/cilastatin, and clofarabine were involved in six or more suspected deaths among 75 deaths reported. There were 107 SDRs, of which 16 events (15%) were not described in the product labels. There was a relatively higher number of SADRs in Brazilian children compared with studies from other countries. SDRs found, (especially drug-event pairs ‘imipenen/cilastatin–pneumonia’ and ‘laronidase–respiratory insufficiency’) should be investigated more. The reports of SADR with IV dosage forms and OL drug use suggest the need for drug research and the use of better dosage forms for children in Brazil.

Keywords: serious adverse drug reactions, children, spontaneous reports, off label drug use, safety signals

Introduction

Ensuring safety, efficacy, and quality of medicines for the pediatric population is a challenge because data on many medicines are scarce due to the lack of clinical trials involving children (Joseph et al., 2015). As a result, children may be exposed to age-inappropriate medicines that can lead to increased incidence of Adverse Drug Reactions (ADRs) (Bellis et al., 2014). Risk factors associated with ADRs in children include polypharmacy, age, off-label (OL) use, and unlicensed (UL) use (Bellis et al., 2014; Lombardi et al., 2018).

Reports of ADRs screening from surveillance systems may offer information about a different drug‐event combination (or pairs) by the mining of a large volume of data (Harpaz et al., 2012). Such safety signals—a potentially causal association or a new aspect of a known association between an intervention and a set of related events—may be critical for drug regulation and improvements in child health (CIOMS, 2010; Osokogu et al., 2016).

Electronic data use for children’s safety is increasing, especially in North America and Europe (Black et al., 2015). ADR prevalence may vary due to differences in pharmacovigilance and polypharmacy management among low and middle-income countries (Olsson et al., 2015; Angamo et al., 2016). In Brazil, the first exclusive investigation about children from the Brazilian database (Notivisa) assessed 3,330 spontaneous reports of suspected ADRs and showed approximately 60% were classified as serious events (Lima et al., 2019). This new study aimed to analyze deaths and other serious ADR reports and to identify safety signals in children.

Materials and Methods

We carried out a cross-sectional study of children with suspected SADRs notified on the Notivisa, created in 2008. Notivisa is a computerized system developed by the National Health Surveillance Agency (Anvisa) to receive notifications of incidents, adverse events, and technical complaints related to the use of health products and medicines by manufacturers, users, health professionals, and health services—mainly those within the Sentinel Network observatory.

The Sentinel Network is an observatory constituting around 200 (general and specialized) accredited hospitals and other health services for monitoring and reporting adverse drug events. Sentinel functions include strategies for surveillance of ADRs and precise mechanisms for identification and investigation, dissemination of results, mandatory risk minimization plans and integration of other institutions for network hospitals. Training for this network was carried out by Anvisa, and it considers the elements described above, including the seriousness and causality assessment of ADRs. SADRs are investigated in health services by patient safety teams before being reported to Notivisa (Brazil, 2011; Brazil, 2015; Teixeira et al., 2017; Mota et al., 2018; Brazil, 2019a).

Anvisa supplied data on Notivisa website reports as a Microsoft Excel® file for the first years of reporting system consolidation, and only complete data between 2008 to 2013 were available for analysis.

Data on suspected ADRs in children (0-12 years old) were identified and selected by age information on the date of the adverse event or the calculation of the difference between the date of onset event and the patient’s birth date. There were no linkage processes with other databases.

The events were described according to the WHO Adverse Reaction Terminology (WHO-ART) and classified following the International Conference on Harmonisation guidance (CIOMS, 1987; ICH Expert Working Group, 2003; WHO, 2018) on the Notivisa database as serious outcomes (i) death; life-threatening; hospitalization; disability (significant or persistent); congenital anomaly, medically important events, and (ii) not serious. All reports classified as ‘not serious’ were excluded.

Information about all suspected drugs reported, including pharmaceutical form and administration route, were collected and encoded using the Anatomic Therapeutic Chemical (ATC) classification system (1st and 5th level). OL use in children was verified from the Brazilian labels (summary of product characteristics) of each drug (approved by Anvisa). Drugs not approved for use by the children’s age group were classified as OL use, and drugs not licensed in Brazil were classified as UL (Gonçalves and Heineck, 2016; Aronson and Ferner, 2017). Age group classification was based on the pediatric stage of development (AAP, 2019).

Disproportionality analysis of ADR reporting was used to identify signals of disproportionate reporting (SDR). SDR refers to statistical associations between drugs and adverse events. The disproportionality analysis method recommended by the European Medicines Agency, namely Reporting Odds Ratio (ROR) and thresholds, is based on its 95% confidence interval and the number of individual cases (European Medicines Agency, 2016). ROR measure is defined by the formula [(a.d)/(c.b)], based on a two-dimensional contingency table where value “a” indicates the number of individual cases that list the target drug P and the target ADR R; value “b” indicates the number of individual cases that list the target drug P but not the target ADR R; value “c” indicates the number of individual cases that list the target ADR R but not the target drug P, and value “d” indicates the number of individual cases that do not list the target ADR R or the target drug P. They should be distinguished from signals that can originate from individual case analysis and epidemiological studies. This method assumes that when a signal (involving a particular adverse event) is identified for a drug, this adverse event is reported relatively more frequently in association with this drug than with other drugs (European Medicines Agency, 2006).

We adopted the following criteria to define a SDR (European Medicines Agency, 2016): number of individual cases is greater than or equal to 3 for active substances contained in medicinal products included in an additional monitoring list defined by the EMA; number of individual cases is greater than or equal to 5 for the other active substances and event belongs to the important medical event terms list. ROR calculations were performed for all drugs with a ≥ 3. Nevertheless, we differentiate between the cases where 3 ≤ a < 5 and a ≥ 5. A situation occurs when c=0, or when all database reports containing a target ADR are associated with only one drug. In this case, ROR cannot be computed. ROR value is arbitrarily set at 99.9 to reflect the presence of a possible SDR.

Other analyses were conducted using SPSS version 22.0 for Windows (IBM Corporation, USA). The chi-square test with a significance level of 5% was used to assess the association between the seriousness of ADR, age group, and the number of drugs prescribed as OL.

The use of Notivisa data was formally authorized by Anvisa. This study was approved by the Hospital Universitário Clementino Fraga Filho Ethics Committee (registration number 931.400).

Results

General Findings

One-thousand-nine-hundred-and-seventy-seven SADRs were assessed, and almost 30% involved 0-1-year-olds. The frequency of serious events was significantly different between pediatric age groups (p < 0.05) ( Table 1 ). SADRs were more common in boys (54%) than in girls. However, 1% of the total reports of suspected SADRs did not include a specification of gender. More than 70% of reports were done from hospitals, mainly from the Sentinel Network, by patient safety teams. Approximately 28% of suspected SADRs were associated with death, were life-threatening, and caused prolonged hospitalization ( Table 1 ).

Table 1.

Distribution of SADR reports (n=1977) by patient age in Brazil between 2008-2013.

Seriousness Baby (aged 0 – 1 y) Toddler(aged 1 - 3 y) Preschool(aged 3 - 5 y) Primary school (aged 5 - 8 y) Secondary school (aged 8 - 12 y) Total (%)
1 – Death 24 14 10 13 14 75 (4,0)
2 - Life threatening 102 36 26 19 33 216 (11,0)
3 - Prolonged hospitalization 65 61 44 28 65 263 (13,0)
4 - Congenital abnormalities 2 1 0 0 0 3 (0,2)
5 - Persistent or significant disability 4 3 9 4 7 27 (1,3)
6 - Medically important events 345 230 192 203 423 1393 (70,5)
Total 542 345 281 267 542 1977
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SADR, Serious Adverse Drug Reaction; y = year(s). Congenital abnormalities: SADR in children related to medicine use during the mother’s pregnancy. Source: Notivisa/Anvisa. P value < 0,001 (Chi Square test).

Two-thousand-two-hundred-and-twenty-nine drugs were identified as being associated with reports of SADRs (mean: 1.1 drugs by report; range from 1 to 6). Anti-infectives for systemic use (n = 1048; 47%), drugs for the nervous system, including non-steroidal anti-inflammatory drugs, (n=384; 17.2%) and antineoplastic, and immunomodulating agents (n=221; 10%) were most commonly involved in suspected SADRs ( Table 2 ).

Table 2.

Distribution of suspected drugs by ATC classification involved in 1977 reports of SADRs in Brazil between 2008-2013.

Description Frequency
[n] %
Drug class (ATC) 2229 100
Alimentary tract and metabolism (A) 153 6,9
Blood and blood forming organs (B) 100 4,5
Cardiovascular system (C) 54 2,4
Dermatological (D) 9 0,4
Genito urinary system and sex hormones (G) 2 0,1
Systemic hormonal preparations (H) 56 2,5
Anti-infectives for systemic use (J) 1048 47,0
Antineoplastic and immunomodulating agents (L) 221 10,0
Musculo-skeletal system (M) 51 2,3
Nervous system (N) 384 17,2
Antiparasitic products, insecticides and repellents (P) 24 1,0
Respiratory system (R) 47 2,1
Sensory organs (S) 43 1,9
Various (V) 37 1,7
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ATC, Anatomical Therapeutic Chemical Code; SADR, Serious Adverse Drug Reactions. Source: Notivisa/Anvisa.

Intravenous powder or solutions were the main pharmaceutical forms reported (69%), followed by tablets (9,3%), oral solutions (4,5%), and oral suspensions (3,7%). Administration route and pharmaceutical form was indeterminate in 9,6% of reports.

Twenty-five percent (n=564) of drugs present in suspected SADRs reports involved OL use by age, according to the Brazilian label, and less than 1% (n=11) of cases were classified as UL use. The frequency of OL prescriptions was significantly higher in events reported, such as persistent disability, prolonged hospitalization, and death (p<0.05) ( Table 3 ).

Table 3.

Distribution of suspected drugs (total and OL prescription by age) by seriousness of SADR in children in Brazil between 2008-2013.

Seriousness classification Number of drugs
Total Prescribed as OL (%) P value
Death 89 26 (29%) 0.043*
Life threatening 239 50 (21%)
Prolonged hospitalization 306 89 (29%)
Congenital abnormalities 3 2 (67%)
Persistent or significant disability 31 12 (39%)
Medically important events 1561 385 (25%)
Total 2229 564 (25%)
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OL, Off-label; SADR, Serious Adverse Drug Reaction. Values in parenthesis are percentages. *Statistically significant at level of P < 0.05 (Chi Square test).

Deaths

There were 75 deaths involving 89 suspected drugs. The majority of deaths were related to either cardiovascular events (22%), respiratory disorders (19%), or general disorders (23%). Sixty-seven percent of these fatal events were not described on Brazilian labels.

Three ATC groups concentrated the major part of suspected drugs: alimentary tract and metabolism (n=26; 29%), antineoplastic (n=19; 22%), and anti-infectives (n=18; 20%). Miglustat and imipenem/cilastatin showed 88% and 25% of OL age use, respectively. Drug indication, as represented by ICD (International Classification of Diseases) classification, showed the predominance of metabolic disorders and infections. These findings are presented in Table 4 .

Table 4.

Description of suspected drugs (from main ATC groups reported) involved in child deaths on Notivisa between 2008-2013.

Suspected Drug ICD Classification (drug indication) Total reports by drugs (n)/OL or UL* use (n) Main events1 classified by System Organ Class
A - Alimentary tract and metabolism 26 (12)
Alfaglicosidase Glycogen storage disease 3 (0) Cardiovascular/Respiratory
Calcium gluconate Not reported 1 (0) General disorders
Imiglucerase Lipid deposit disorders 3 (0) General disorders/Respiratory
Laronidase Mucopolysaccharidosis type I 6 (0) General disorders/Cardiovascular/Respiratory
Metoclopramide Nausea and vomiting 3 (3) Blood/Cardiovascular
Miglustat Not reported 9 (8) General disorders/Gastro-intestinal system/Neurologic/Respiratory
Ondansetron Nausea and vomiting 1(1) Cardiovascular
J - Anti-infectives for systemic use 18 (4)
Ampiciline Not reported 3 (0) Neurologic
Benzylpenicillin Not reported 1 (0) Neurologic
Caspofungin Localized infections of the skin and subcutaneous tissue 1 (1) General disorders
Ceftriaxone Acute upper airway infection 1 (1) Respiratory
Imipenem/Cilastatin Complications of heart defects; Bacterial pneumonia; Infections due to other mycobacteria; Other bacterial diseases; Unspecified microorganism pneumonia 8 (2) Blood/General disorders/Cardiovascular/Endocrine/Gastro-intestinal/Musculo-skeletal system/Neurologic/Respiratory system/Urinary
Imunoglobuline (human) Not reported 1 (0) Cardiovascular
Meropenem Not reported 1 (0) Neurologic
Metronidazole Other venous embolism and thrombosis 1 (0) Blood
Oxacillin Not reported 1 (0) Skin
L - Antineoplastic and immunomodulating agents 19 (14)
Carboplatin Not reported 1 (1) General disorders
Carmustine + Cytarabine + Etoposide + Melphalan Not reported 4 (4) Cardiovascular
Clofarabine Lymphoid leukemia 8 (8)* Blood/General disorders/Cardiovascular/Respiratory
Ifosfamide Not reported 2 (0) Gastro-intestinal
Methotrexate Not reported 2 (0) Blood/General disorders/Cardiovascular/Gastro-intestinal system/Neurologic/Respiratory/Skin
Rituximab Adverse effects of primarily systemic action substances 1 (1) Endocrine
Vincristine Lymphoid leukemia 1 (0) General disorders
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ATC, Anatomical Therapeutic Chemical Code; ICD, International Classification of Diseases; OL, Off-label; UL*, Unlicensed use; Not reported, no information about drug indication on database.

Drugs classified in other groups: heparin, bosentan, furosemide, gentamicin, hydrocortisone, methylprednisolone, ibuprofen, metamizole sodium, methadone, alpha poractant, fenoterol, fluticasone and salmeterol, technetium (99mtc) ethylenedicysteine, coagulation factor viii, coagulation factor IX, II, VII, and X in combination, were also reported. There were four cases, all involving newborns, related to contamination of solutions (parenteral nutrition and sodium chloride).

Safety Signals

Using the disproportionality analysis, applying a signal threshold of (N) ≥3, results pointed to 65 SDRs involving mostly anti-infectives for systemic use (34%), antineoplastic agents (15%), nervous system drugs (12%), and alimentary tract and metabolism drugs (11%). For (N) ≥5, 42 signals were involved mostly with anti-infectives for systemic use (55%), nervous system (17%), antineoplastic agents (12%), and sensory organs drugs (12%). From 107 signals of disproportionate reporting, 16 events (15%) were not described on the Brazilian label, ( Table 5 ). Two pairs were suspected with deaths: imipenen/cilastatin–pneumonia, and laronidase–respiratory insufficiency.

Table 5.

Drug-event pairs associated with Signals of Disproportionate Reporting (SDR) not described in drug label (Brazilian label).

Suspected Drug Event description ROR Lower bound 95% Seriousness of suspected ADRs found Thresholds of number of cases (n)
Alphaglucosidase Asthenia 66.77 27.10 Medically important ≥5
Amphotericin B Hypokalemia 54.24 24.95 Life threatening
Prolonged hospitalization
Medically important		 ≥5
Ciclosporin Nystagmus 47.11 13.70 Medically important events ≥3
Psychosis 15.30 4.30 Medically important events ≥3
Blurred vision 212.5 37.38 Life threatening
Prolonged hospitalization
Persistent or significant disability
Medically important		 ≥3
Imipenem and Cilastatin Pneumonia 42.80 11.68 Death ≥3
Laronidase Respiratory insufficiency 29.05 7.53 Death
Prolonged hospitalization		 ≥3
Papules 15.02 3.70 Medically important ≥3
Metoclopramide Psychosis 15.30 54.27 Medically important ≥3
Oxacillin Cough 2.94 1.00 Life threatening
Prolonged hospitalization
Medically important		 ≥3
Tropicamide Apnea 75.95 18.33 Life threatening
Medically important events		 ≥3
Asthenia 33.67 13.89 ≥5
Bradycardia 33.67 13.89 ≥5
Persistent crying 677.71 82.54 ≥5
Dyspnea 11.11 4.72 ≥5
Vancomycin Petechiae 3.38 1.23 Medically important events ≥5
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ROR, Reporting Odds Ratio; ADR, Adverse Drug Reaction.

Discussion

Our study found a higher frequency of SADRs in children (60%) than is generally reported compared to other pediatric studies, in which rates of SADRs reported in national databases ranged from 0% to 66.7% (Aagaard et al., 2010; Smyth et al., 2012). The relatively high reported frequency of SADRs in children in this study may be due to the high proportion of Notivisa data attributed to inpatients. Another hypothesis is that this database does not discriminate the adverse drug reactions caused by medication errors. The Adverse Drug Reactions in Children (ADRIC) program in the UK reported the incidence of ADRs for hospitalized children as 15.9% (Smyth et al., 2014). A retrospective analysis based on 5 years of pharmacovigilance studies (2012-2016) in an Italian hospital observed 834 ADRs, of which 239 (29%) were serious (Lombardi et al., 2018).

One study reported age as a risk factor for an ADR (Lombardi et al., 2018). Our results suggest evidence of an association (p<0.05) between age and the seriousness of an ADR ( Table 1 ).

Vancomycin (n=9,2%), Ceftriaxone (5,9%), and Oxacillin (n=5,7%) were the specific drugs most commonly reported as being associated with a suspected SADR in the current study. Anti-infectives and antiepileptics represent the most frequently reported therapeutic classes associated with ADRs in children admitted to hospital, and non-steroidal anti-inflammatory drugs were often reported as associated with ADRs in outpatient children (Smyth et al., 2012). Our findings agree with this review, although the proportion of ADRs associated with antiepileptic drugs was small (1%).

The intravenous route represented the most common dosage form (69%) associated with a suspected SADR, which also may be attributable to the Sentinel Network notifications being dominated by inpatients. However, this route represents a higher risk for the incidence of medical errors than with other formulations (Grissinger, 2010), which reinforces the necessity of discussions about the selection and development of better formulations for children in Brazil. Furthermore, cases of contamination of sterile solutions have been reported, which may be related to problems in preparing and administering these products for newborns.

The Food and Drug Administration (FDA) and EMA implemented regulatory initiatives for pediatric medicines in the early 2000s. Both agencies created legislation to perform studies in children for products seeking marketing authorization in adults that meet certain criteria based on the relevance to public health (Turner et al., 2014). These initiatives have had a positive impact on pediatric drug development, and pediatric considerations have become an integral part of pharmaceutical development across the US and Europe (European Comission, 2016; Food and Drug Administration, 2016).

In Brazil, even with the participation of Anvisa in the Pediatric medicines Regulators’ Network (PmRN) (WHO, 2010), no similar initiative was taken by any Brazilian regulatory authority regarding pediatric drug development. Nevertheless, prioritization of license analysis of a new drug, further pharmaceutical form, new therapeutic indication, and new concentrations for children (fast track) can be requested (Brazil, 2017).

Regarding other policies to ensure safer pharmacotherapy, Brazilian regulatory standards for manufacturers currently do not provide differentiated strategies for monitoring drugs used in children. Anvisa became a member of the International Council for Harmonization of Technical Requirements for Pharmaceuticals for Human Use (ICH) in 2016. There was a public consultation for update rules (in 2018) in which the Periodic Benefit-Risk Evaluation Report (PBRER) and the pharmacovigilance planning would meet the criteria adopted by ICH, concerning the information on the benefit-risk profile of drugs in special populations, such as children. Unfortunately, the new regulation is not yet published due to challenges in the resources required to complete the guidance Anvisa (Brazil, 2019b). Such challenges in the development and dissemination of territory-specific safety guidance can increase the risk associated with the use of children’s medicines in middle-income countries like Brazil.

The percentage of drugs associated with any serious SADR level, which used OL, was 25% (range 21-67%) ( Table 3 ). Children are especially vulnerable to SADRs due to the lack of data for this age group and the extensive use of OL and UL drugs (Elzagallaai et al., 2017). Reducing OL use in children could decrease the impact of SADRs, such as prolonged hospitalization, persistent disability, and death, as shown in Table 3 (p<0.05). In 2013, a prospective cohort study conducted in a pediatric hospital in the United Kingdom evaluating the impact of OL and UL prescribing on ADRs causing admissions to a pediatric hospital showed a 23% increase in ADR risk due to OL use (Bellis et al., 2014).

Of the SADR reports which were associated with deaths, babies (0-1-year-old) (n=24; 32%) were the age group most implicated ( Table 1 ). Neoplasms, respiratory, infectious and parasitic, related nervous or cardiovascular system diseases, and chromosomal abnormalities or congenital malformation stand out as causes of mortality and or morbidity in Brazilian children (Vieira et al., 2017). Considering that most records were from hospitalized children, it was expected that serious ADRs in Brazil would involve babies and drugs with related indications, as shown in Table 4 . Furthermore, drugs indicated for metabolism disorders (ICD class E) and infection diseases (ICD class J), as observed in Table 4 , are well described in literature such as patterns of off-label prescribing in children (Luedtke and Buck, 2014; Gonçalves et al., 2017). In severe clinical conditions, there is a complex assessment of the balance between risks and benefits, and, even if there is a higher chance of a fatal adverse event, the use of the drug might be the best medical decision. However, labels are a primary source of safety information from manufacturers for healthcare professionals and must be up to date with the frequency of ADRs in order to take precautionary and management measures in case of serious events (Brazil, 2010).

There were only three reports classified as congenital anomalies. Although these are not drugs directly administered to children, damage to the fetus was suspected, making this information relevant for the pharmacotherapy monitoring and evaluation in special populations, including pregnant women. The pediatric disease burden in low-and middle-income countries is particularly affected by congenital anomalies, and the spontaneous notification of these events, as expected, was meager, which reinforces the demand for studies with better power to recognize these cases (WHO, 2020).

The present analysis described a high number of fatal events (67%) and were also associated with signals of disproportionate reporting (15%) ( Table 5 ) not expressed in the product label.

Three drugs were suspected of eight or more fatal events: Miglustat, imipenem/cilastatin, and clofarabine. Of the suspected drugs associated with death, there was a high proportion of OL/UL use and specifically OK use, and, specifically the OL use (e.g., miglustat and imipenem/cilastatin) and UL use (e.g., clofarabine) associated with them ( Table 4 ).

Disturbances such as diarrhea and flatulence are the most common adverse effects associated with miglustat therapy (Belmatoug et al., 2011; Remenova et al., 2015. In one fatal case, this event was present ( Table 4 ). For imipenem/cilastatin, nausea and vomiting were also reported in the literature (Oliva et al., 2005) and was present in cases of deaths. Most of the events reported in the literature for clofarabine, such as blood disorders (e.g., neutropenia) and respiratory disorders (e.g., respiratory distress), have been described (Jeha et al., 2006; O’Connor et al., 2011) ( Table 4 ).

Star et al. analyzed (2019) pediatric individual case safety reports from Vigibase and founded 27 potential signals. After an in-depth assessment, they pointed out eight signals involving dextromethorphan (OL use), olanzapine (accidental overdose), atomoxetine (two signals), temozolomide, deferasirox, levetiracetam, and desloratadine. They used a data-driven predictive model that prioritized reporting a series of emergent signals by weighing disproportionate reporting patterns, completeness, recency, and geographic spread of individual case reporting and availability of case narratives.

Although it is one of Anvisa’s goals, the Notivisa data analyzed in this study could not be sent to the Uppsala Monitoring Center, due to the incompatibility of notification systems, this study suggests the identification of new signals. However, we acknowledge that local practices, specific characteristics of the pediatric population, and pharmaceutical characteristics used in Brazil may have influenced our results.

We found 16 pairs involving serious events that need more assessment and follow-up. Imipenem/cilastatin and laronidase must be monitored for the risk of pneumonia and respiratory insufficiency, respectively. These pairs were reported as fatal events. A case report of imipenem/cilastatin-induced acute eosinophilic pneumonia in a 60-year-old woman (Foong et al., 2016) reinforces a suspected link of this ADR.

Disproportionality analysis in pharmacovigilance databases is an exploratory and reliable method to generate signals. Once a new disproportionality ratio for a drug has been observed, further studies can be conducted to confirm the signal (Montastruc et al., 2011).

Spontaneous reporting is considered an accessible and low-cost pharmacovigilance method that provides drug use assessment in real-life situations for large sample sizes (Pal et al., 2013). However, underreporting of adverse reactions makes it impossible to estimate the actual frequency of events. Another limitation of secondary database use is missing data, which is particularly important for causality assessment. Although notifiers were trained for a prior analysis of the suspected ADR, some of the necessary data had not been captured by Anvisa and cannot be undertaken retrospectively.

Conclusion

We found substantial SADRs reporting from the Brazilian database involving IV dosage forms and OL drug use in children. Imipenem and cilastatin, laronidase, clofarabine (unlicensed use), and miglustat (off label use) were suspected drugs related to deaths which were more frequently reported in the study period.

Moreover, the high number of signals of disproportionate reporting observed, mainly for anti-infectives, suggests that the safety profile of these medicines in children should be further investigated.

Finally, we recommend the dissemination and use of information from the periodic safety update reports for children, the development of pediatric formulations, and specific policy approval in Brazil following the examples of pediatric drug regulations in the US and Europe.

Data Availability Statement

The datasets generated for this study are available on request to the corresponding author.

Ethics Statement

The studies involving human participants were reviewed and approved by Hospital Universitário Clementino Fraga Filho Ethics Committee. Written informed consent from the participants’ legal guardian/next of kin was not required to participate in this study in accordance with the national legislation and the institutional requirements.

Author Contributions

EL conceptualized the study. JV and EL led data collection, carried out the analysis, and drafted the initial manuscript. GM, FS, LB, and MP assisted with interpretation of the data and preparation of the final version of the manuscript. All authors contributed to the article and approved the submitted version.

Funding

This study was funded by the National Council for Scientific and Technological Development (CNPq) (Grant number: 421992/2016-6).

Conflict of Interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Acknowledgments

The authors thank the National Health Surveillance Agency (ANVISA) for providing access to Notivisa data.

References

  1. Aagaard L., Christensen A., Hansen E. H. (2010). Information about adverse drug reactions reported in children: a qualitative review of empirical studies. Br. J. Clin. Pharmacol. 70 (4), 481–491. 10.1111/j.1365-2125.2010.03682.x [DOI] [PMC free article] [PubMed] [Google Scholar]
  2. AAP American Academy of Pediatrics (2019). Ages and stages. Available at: https://www.healthychildren.org/English/ages-stages/Pages/default.aspx (Accessed 11/01/2019).
  3. Angamo M. T., Chalmers L., Curtain C. M., Bereznick L. R. E. (2016). Adverse-drug-reaction-WHO adverse drug reaction terminology related hospitalisations in developed and developing countries: a review of prevalence and contributing factors. Drug Saf. 39, 847–857. 10.1007/s40264-016-0444-7 [DOI] [PubMed] [Google Scholar]
  4. Aronson J. K., Ferner R. E. (2017). Unlicensed and off-label uses of medicines: definitions and clarification of terminology. Br. J. Clin. Pharmacol. 83 (12), 2615–2625. 10.1111/bcp.13394 [DOI] [PMC free article] [PubMed] [Google Scholar]
  5. Bellis J. R., Kirkham J. J., Nunn A. J., Pirmohamed M. (2014). Adverse drug reactions and off-label and unlicensed medicines in children: a prospective cohort study of unplanned admissions to a paediatric hospital. Br. J. Clin. Pharmacol. 77 (3), 545–553. 10.1111/bcp.12222 [DOI] [PMC free article] [PubMed] [Google Scholar]
  6. Belmatoug N., Burlina A., Giraldo P., Hendriksz C. J., Kuter D. J., Menqel E., et al. (2011). Gastrointestinal disturbances and their management in miglustat-treated patients. J. Inherit. Metab. Dis. 34 (5), 991–1001. 10.1007/s10545-011-9368-7 [DOI] [PubMed] [Google Scholar]
  7. Black C., Tagiyeva-Milne N., Helms P., Moir D. (2015). Pharmacovigilance in children: adverse drug reactions in routine electronic healthcare records. A systematic review. Br. J. Clin. Pharmacol. 80 (4), 844–854. 10.1111/bcp.12645 [DOI] [PMC free article] [PubMed] [Google Scholar]
  8. Brazil (2010). Guias de Farmacovigilância para Detentores de Registro de Medicamentos. Agência Nacional de Vigilância Sanitária. Gerência de Farmacovigilância (Brasilia: Editora MS; ), 156. [Google Scholar]
  9. Brazil (2011). Agência Nacional de Vigilância Sanitária. Critérios para credenciamento de instituições na Rede Sentinela. Available at: http://portal.anvisa.gov.br/documents/33868/1853050/Crit%C3%A9rios+para+participa%C3%A7%C3%A3o+na+Rede+Sentinela/1e9915f2-180b-4581-9828-617c7629b2a0 (Accessed 05/14/2020).
  10. Brazil (2015). Agência Nacional de Vigilância Sanitária. Nota Técnica GVIMS/GGTES/ANVISA no 01/2015. Orientações gerais para a notificação de eventos adversos relacionados à assistência à saúde. Available at: http://portal.anvisa.gov.br/documents/33852/271858/Nota+t%C3%A9cnica+N%C2%BA+01+de+2015+-GVIMS-GGTES-ANVISA/b98ec033-1676-4443-9603-24a4edae1505 (Accessed 05/30/2020).
  11. Brazil (2017). Agência Nacional de Vigilância Sanitária. Resolução de Diretoria Colegiada no 204, de 27 de dezembro de 2017. Available at: http://portal.anvisa.gov.br/documents/10181/2718376/RDC_204_2017_.pdf/b2d4ae64-2d91-44e9-ad67-b883c752c094 (Accessed 05/14/2020).
  12. Brazil (2019. a). Agência Nacional de Vigilância Sanitária. Sistema de Notificação em Vigilância Sanitária (Notivisa). Available at: http://portal.anvisa.gov.br/notivisa (Accessed 12/17/2019).
  13. Brazil (2019. b). Agência Nacional de Vigilância Sanitária. Boletim de Farmacovigilância no. 6 [Online]. Available at: http://portal.anvisa.gov.br/documents/33868/2894786/Boletim+de+Farmacovigil%C3%A2ncia+n%C2%BA+06/33f0afc5-f188-4bef-9378-14c6a9c6f624 (Accessed 05/14/2020).
  14. CIOMS (1987). International reporting of adverse drug reactions. International reporting of adverse drug reactions. Work Group Report. Available at: https://cioms.ch/wp-content/uploads/2017/07/Int-Reporting-Adv-Drug-Reactions-1987.pdf (Accessed 05/07/2019).
  15. CIOMS (2010). Practical Aspects of Signal Detection in Pharmacovigilance (Geneva: Council for International Organizations of medical Sciences; ). Available at: https://cioms.ch/wp-content/uploads/2018/03/WG8-Signal-Detection.pdf (Accessed 02/02/2019). [Google Scholar]
  16. Elzagallaai A. A., Greff M., Rieder M. J. (2017). Adverse drug reactions in children: the double-edged sword of therapeutics. Clin. Pharmacol. Ther. 101 (6), 725–735. 10.1002/cpt.677 [DOI] [PubMed] [Google Scholar]
  17. European Comission (2016). 10-year Report to the European Commission: general report on the experience acquired as result of the application of the Paediatric Regulation. Available at: https://ec.europa.eu/health/sites/health/files/files/paediatrics/2016_pc_report_2017/ema_10_year_report_for_consultation.pdf 2016 (Accessed 06/20/2018).
  18. European Medicines Agency (2006). Guideline on the use of statistical signal detection methods in the Eudravigilance Data Analysis System. Available at: https://www.ema.europa.eu/documents/regulatory-procedural-guideline/draft-guideline-use-statistical-signal-detection-methods-eudravigilance-data-analysis-system_en.pdf (Accessed 05/14/2019).
  19. European Medicines Agency (2016). Screening for Adverse Reactions in EudraVigilance. 2016. Available at: http://www.ema.europa.eu/docs/en_GB/document_library/Other/2016/12/WC500218606.pdf (Accessed 02/06/2019).
  20. Food and Drug Administration (2016). Best pharmaceuticals for children act and pediatric research equity act. Available at: https://www.fda.gov/downloads/scienceresearch/specialtopics/pediatrictherapeuticsresearch/ucm509815.pdf (Accessed 04/02/2019).
  21. Foong K. S., Lee A., Pekez M., Bin W. (2016). Imipenem/cilastatin-induced acute eosinophilic pneumonia. BMJ Case Rep. 4.   10.1136/bcr-2016-214804 [DOI] [PMC free article] [PubMed] [Google Scholar]
  22. Gonçalves M. G., Heineck I. (2016). Frequency of prescriptions of off-label drugs and drugs not approved for pediatric use in primary health care in a southern municipality of Brazil. Rev. Paul Pediatr. 34 (1), 11–17. 10.1016/j.rppede.2015.06.023 [DOI] [PMC free article] [PubMed] [Google Scholar]
  23. Gonçalves A. C. S., Reis A. M. M., Marçal A. C. G., Bouzada M. C. F. (2017). Use of unlicensed and off-label drugs in neonates in a Brazilian university hospital. Braz. J. Pharm. Sci. 53 (3), e00252. [Google Scholar]
  24. Grissinger M. (2010). Reducing errors with injectable medications: unlabeled syringes are surprisingly common. Pharm. Ther. 35 (8), 428–451. [PMC free article] [PubMed] [Google Scholar]
  25. Harpaz R., DuMouchel W., Shah N. H., Madigan D., Ryan P., Friedman C. (2012). Novel data-mining methodologies for adverse drug event discovery and analysis. Clin. Pharmacol. Ther. 91 (6), 1010–1021. 10.1038/clpt.2012.50 [DOI] [PMC free article] [PubMed] [Google Scholar]
  26. ICH Expert Working Group (2003). International Conference on Harmonisation. Post-approval safety data management: definitions and standards for expedited reporting Published in the Federal Register Available at: https://www.ich.org/fileadmin/Public_Web_Site/ICH_Products/Guidelines/Efficacy/E2D/Step4/E2D_Guideline.pdf (Accessed 09/22/20190). [Google Scholar]
  27. Jeha S., Gaynon P. S., Razzouk B. I., Franklin J., Kadota R., Shen V., et al. (2006). Phase II study of clofarabine in pediatric patients with refractory or relapsed acute lymphoblastic leukemia. J. Clin. Oncol. 24 (12), 1917–1923. 10.1200/JCO.2005.03.8554 [DOI] [PubMed] [Google Scholar]
  28. Joseph P. D., Craig J. C., Caldwell P. H. (2015). Clinical trials in children. Br. J. Clin. Pharmacol. 79 (3), 357–369. 10.1111/bcp.12305 [DOI] [PMC free article] [PubMed] [Google Scholar]
  29. Lima E. C., Matos G. C., Vieira J. M. L., Gonçalves I. C. C. R., Cabral L. M., Turner M. (2019). Suspected adverse drug reactions reported for Brazilian children: cross-sectional study. J. Pediatr. (Rio J) 95 (6), 682–688.   10.1016/j.jped.2018.05.019 [DOI] [PubMed] [Google Scholar]
  30. Lombardi N., Crescioli G., Bettiol A., Marconi E., Vitiello A., Bonaiuti R., et al. (2018). Characterization of serious adverse drug reactions as cause of emergency department visit in children: a 5-years active pharmacovigilance study. BMC Pharmacol. Toxicol. 19 (1), 1–8.   10.1186/s40360-018-0207-4 [DOI] [PMC free article] [PubMed] [Google Scholar]
  31. Luedtke K. E., Buck M. L. (2014). Evaluation of off-label prescribing at a children’s rehabilitation center. J. Pdiatr Pharmacol. Ther. 19 (4), 296–301. 10.5863/1551-6776-19.4.296 [DOI] [PMC free article] [PubMed] [Google Scholar]
  32. Montastruc J. L., Sommet A., Bagheri H., Lapevre-Mestre M. (2011). Benefits and strengths of the disproportionality analysis for identification of adverse drug reactions in a pharmacovigilance database. Br. J. Clin. Pharmacol. 72, 905–908.   10.1111/j.1365-2125.2011. 04037.x. [DOI] [PMC free article] [PubMed] [Google Scholar]
  33. Mota D. M., Vigo A., Kuchenbecker R. S. (2018). Evolution and key elements of the Brazilian pharmacovigilance system: a scoping review beginning with the creation of the Brazilian Health Regulatory Agency. Cad Saúde Pública 34 (10), e00000218.   10.1590/0102-311x00000218 [DOI] [PubMed] [Google Scholar]
  34. Oliva M. E., Rekha A., Yellin A., Pasternak J., Campos M., Rose G. M., et al. (2005). A multicenter trial of the efficacy and safety of tigecycline versus imipenem/cilastatin in patients with complicated intra-abdominal infections [Study ID Numbers: 3074A1-301-WW; ClinicalTrials.gov Identifier: NCT00081744]. BMC Infect. Dis. 19;5, 88. 10.1186/1471-2334-5-88 [DOI] [PMC free article] [PubMed] [Google Scholar]
  35. Olsson S., Pal S. N., Dodoo A. (2015). Pharmacovigilance in resource-limited countries. Expert Rev. Clin. Pharmacol. 8 (4).   10.1586/17512433.2015.1053391 [DOI] [PubMed] [Google Scholar]
  36. O’Connor D., Sibson K., Caswell M., Connor P., Cummins M., Mitchel C., et al. (2011). Early UK experience in the use of clofarabine in the treatment of relapsed and refractory paediatric acute lymphoblastic leukaemia. Br. J. Haematol. 154 (4), 482–485. 10.1111/j.1365-2141.2011.08752.x [DOI] [PubMed] [Google Scholar]
  37. Osokogu O. U., Dodd C., Pacurariu A., Kaguelidou F., Weibel D., Sturkenboom M. C. J. M. (2016). Drug safety monitoring in children: performance of signal detection algorithms and impact of age stratification. Drug Saf. 39 (9), 873–881. 10.1007/s40264-016-0433-x [DOI] [PMC free article] [PubMed] [Google Scholar]
  38. Pal S. N., Duncombe C., Falzon D., Olsson S. (2013). WHO strategy for collecting safety data in public health programmes: complementing spontaneous reporting systems. Drug Saf. 36, 75–81. 10.1007/s40264-012-0014-6 [DOI] [PMC free article] [PubMed] [Google Scholar]
  39. Remenova T., Morand O., Amato D., Chadha-Boreham H., Tsurutani S., Marquardt T. (2015). A double-blind, randomized, placebo-controlled trial studying the effects of Saccharomyces boulardii on the gastrointestinal tolerability, safety, and pharmacokinetics of miglustat. Orphanet J. Rare Dis. 10, 81.   10.1186/s13023-015-0297-7 [DOI] [PMC free article] [PubMed] [Google Scholar]
  40. Smyth R. M. D., Gargon E., Kirkham J., Cresswell L., Golder S., Smyth R., et al. (2012). Adverse drug reactions in children—a systematic review. PloS One 7 (3), e24061. 10.1371/journal.pone.0024061 [DOI] [PMC free article] [PubMed] [Google Scholar]
  41. Smyth R. L., Peak M., Turner M. A., Nunn A. J., Williamson P. R., Young B., et al. (2014). ADRIC: Adverse Drug Reactions In Children–a programme of research using mixed methods (Southampton (UK: NIHR Journals Library; ), 214. [PubMed] [Google Scholar]
  42. Star K., Sandberg L., Bergvall T., Choonara I., Caduff-Janosa P., Edwards I. R. (2019). Paediatric safety signals identified in VigiBase: Methods and results from Uppsala Monitoring Centre. Pharmacoepidemiol. Drug Saf. 28 (5), 680–689. 10.1002/pds.4734 [DOI] [PMC free article] [PubMed] [Google Scholar]
  43. Teixeira A. P. C. P., Leitão L. O., Barbosa P. F. T., Cammarota D. M. O. T., Rocha V. L. C. (2017). Perfil de estabelecimentos de saúde brasileiros participantes da Rede Sentinela. Vigil. Sanit. Debate 5 (4), 88–93.   10.22239/2317-269x.01006 [DOI] [Google Scholar]
  44. Turner M. A., Catapano M., Hirschfeld S., Giaquinto C., GRIP (Global Research in Paediatrics) (2014). Paediatric drug development: the impact of evolving regulations. Adv. Drug Delivery Rev. 73: 30, 2–13. 10.1016/j.addr.2014.02.003 [DOI] [PubMed] [Google Scholar]
  45. Vieira J. M. L., Lima E. C., Land M. G. P., Ventura M., Coelho H. L. L. (2017). Profile of clinical trials enrolling Brazilian Children. Cad Saúde Pública 33 (5), e00169515. 10.1590/0102-311x00169515 [DOI] [PubMed] [Google Scholar]
  46. WHO. World Health Organization (2010). Paediatric Medicines Regulators" Network. Available at: http://www.who.int/childmedicines/paediatric_regulators/objectives/en/ (Accessed 08/11/2019).
  47. WHO. World Health Organization (2018). Adverse Reaction Terminology WHO-ART Uppsala (Sweden: The Uppsala Monitoring Center; ). Available at: http://www.umc-products.com/DynPage.aspx (Accessed 06/11/2019). [Google Scholar]
  48. WHO. World Health Organization (2020). Congenital anomalies. Available at: https://www.who.int/health-topics/congenital-anomalies#tab=tab_1 (Accessed 05/30/2020).

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Data Availability Statement

The datasets generated for this study are available on request to the corresponding author.

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