Effects of Zika infection on growth<sup>,</sup>

Prata-Barbosa, Arnaldo; Martins, Marlos Melo; Guastavino, Andreia Bittencourt; Cunha, Antônio José Ledo Alves da

doi:10.1016/j.jped.2018.10.016

Abstract

Objectives:

To present the currently available evidence of the effects of congenital Zika virus infection on infant growth, to discuss possible intervening factors, and to describe preliminary data on this growth in a cohort of exposed children.

Source of data:

Non-systematic review in PubMed, BVS, CAPES, Scopus, Web of Science, Cochrane and Google Scholar databases in the last 5 years, using the terms infection/disease by Zika virus and growth/nutrition/nutritional status/infant nutrition and nutritional needs. Additionally, the anthropometric data of the first 2.5 years of a cohort of children exposed to the Zika virus during pregnancy were reviewed.

Synthesis of data:

Both intrauterine growth restriction and low birth weight were reported in series of cases of children with congenital Zika syndrome. The postnatal growth deficit of these children appears to be directly proportional to the degree of neurological impairment. The etiology is multifactorial, and nutritional and non-nutritional factors are probably involved. The data from the present cohort show that the head circumference evolution depends on this measurement at birth and that weight-height growth has a trend toward lower weight and length in children with congenital microcephaly and normocephalic at birth who develop some neurological abnormality.

Conclusions:

The few existing data suggest that, in children with congenital Zika, the greater the degree of neurological impairment, the greater the impact on growth, whether or not associated with microcephaly at birth.

KEYWORDS
Zika virus infection; Growth; Microcephaly

Resumo

Objetivos:

Apresentar as evidências atualmente disponíveis das repercussões da infecção congênita pelo vírus Zika no crescimento infantil, discutir possíveis fatores intervenientes e descrever dados preliminares desse crescimento em uma coorte de crianças expostas.

Fonte dos dados:

Revisão não sistemática nos portais de banco de dados PubMed, BVS, Capes, Scopus, Web of Science, Cochrane e Google Scholar nos últimos cinco anos, com o uso dos termos infecção/doença pelo vírus Zika e crescimento/nutrição/status nutricional/nutrição infantil e necessidades nutricionais. Além disso, foram revistos os dados antropométricos dos primeiros dois anos e meio de uma coorte de crianças expostas ao vírus Zika durante a gestação.

Síntese dos dados:

Tanto a restrição do crescimento intrauterino como o baixo peso ao nascer têm sido relatados em séries de casos de crianças com síndrome de Zika congênita. O déficit de crescimento pós-natal dessas crianças parece ser diretamente proporcional ao grau de comprometimento neurológico. A etiologia é multifatorial, com fatores nutricionais e não nutricionais provavelmente envolvidos. Os dados de nossa coorte mostram que a evolução do perímetro cefálico é dependente do valor dessa medida ao nascimento e que o crescimento pondero-estatural apresenta uma tendência de menor peso e comprimento em crianças com microcefalia congênita e normocefálicas ao nascimento, mas com alguma anormalidade neurológica evolutiva.

Conclusões:

Os poucos dados existentes sugerem que em crianças com Zika congênita, o impacto sobre o crescimento será tanto maior quanto maior for o grau de comprometimento neurológico, associado ou não à microcefalia ao nascimento.

PALAVRAS-CHAVE
Infecção pelo Zika vírus; Crescimento; Microcefalia

Introduction

In October 2015, the Brazilian Ministry of Health notified the World Health Organization (WHO) of a significant increase in cases of congenital microcephaly in northeastern Brazil, in association with the epidemic of Zika virus infection in the region.¹1 Brasil. Ministério da Saúde. Secretaria de Vigilância em Saúde. Boletim epidemiológico volume 46 n(34. Situação epidemiológica de ocorrência de microcefalias no Brasil, 2015. Brasília: Ministério da Saúde; 2015. [cited on 2018 Sep 26]. Available from: http://portalarquivos2.saude.gov.br/images/pdf/2015/novembro/19/Microcefalia-bol-final.pdf.
http://portalarquivos2.saude.gov.br/imag... In February 2016, the WHO declared this association a Public Health Emergency of International Concern.²2 WHO. WHO statement on the first meeting of the International Health Regulations (2005) (IHR 2005) Emergency Committee on Zika virus and observed increase in neurological disorders and neonatal malformations. [cited on 2018 Sep 26]. Available from: http://www.who.int/mediacentre/news/statements/2016/1st-emergency-committee-zika/en/.
http://www.who.int/mediacentre/news/stat...

Evidence has been accumulating in favor of the association between Zika virus infection during pregnancy and the development of congenital microcephaly and other neurological abnormalities in newborns.³3 Cauchemez S, Besnard M, Bompard P, Dub T, Guillemette-Artur P, Eyrolle-Guignot D, et al. Association between Zika virus and microcephaly in French Polynesia, 2013-15: a retrospective study. Lancet. 2016;387:2125-2132.

4 Magalhães-Barbosa MC, Prata-Barbosa A, Robaina JR, Raymundo CE, Lima-Setta F, Cunha AJ. Trends of the microcephaly and Zika virus outbreak in Brazil, January-July 2016. Travel Med Infect Dis. 2016;14:458-463.^-⁵5 De Oliveira WK, de França GV, Carmo EH, Duncan BB, de Souza Kuchenbecker R, Schmidt MI. Infection-related microcephaly after the 2015 and 2016 Zika virus outbreaks in Brazil: a surveillance-based analysis. Lancet. 2017;390:861-870. Public health authorities in Europe and the United States have warned of the risk of worldwide dissemination of the Zika virus and the importance of increased surveillance, as well as disease prevention and control measures.⁶6 European Centre for Disease Prevention and Control. Rapid risk assessment: Zika virus epidemic in the Americas: potential association with microcephaly and Guillain-Barré syndrome - 10 December 2015. Stockholm: ECDC; 2015.

While microcephaly was the most striking clinical sign for the monitoring of this group of children, it is now believed that the spectrum of congenital infections by Zika virus can reach far beyond microcephaly, requiring special attention from pediatricians and the health care teams.⁷7 Van der Linden V, Pessoa A, Dobyns W, Barkovich AJ, Júnior HV, Filho EL, et al. Description of 13 infants born during October 2015-January 2016 with congenital Zika virus infection without microcephaly at birth - Brazil. MMWR Morb Mortal Wkly Rep. 2016;65:1343-8.^,⁸8 Cardoso TF, Santos RS, Corrêa RM, Campos JV, Silva RB, Tobias CC, et al. Congenital Zika infection: neurology can occur without microcephaly. Arch Dis Child. 2019;104:199-200.

Children with microcephaly and chronic non-progressive encephalopathy, as observed in congenital Zika syndrome (CZS), usually grow less, having shorter stature and weighing less than their healthy peers of the same age.⁹9 Penagini F, Mameli C, Fabiano V, Brunetti D, Dilillo D, Zuccotti GV. Dietary intakes and nutritional issues in neurologically impaired children. Nutrients. 2015;7:9400-15. The etiology of this growth deficit is multifactorial and may be related to both nutritional and non-nutritional factors, secondary to brain malformations.⁹9 Penagini F, Mameli C, Fabiano V, Brunetti D, Dilillo D, Zuccotti GV. Dietary intakes and nutritional issues in neurologically impaired children. Nutrients. 2015;7:9400-15.

Regardless of microcephaly status, reports on the growth of children exposed to the Zika virus during pregnancy are still scarce. To date, studies have given more emphasis to their development. Thus, the aim of this review was to present the currently available evidence of the effects of congenital Zika virus infection on infant growth, to discuss possible intervening factors, and to describe preliminary data on this growth in a cohort of exposed children.

Source of data

A non-systematic review was carried out at PubMed, BVS, CAPES, Scopus, Web of Science, and Cochrane databases, comprising the last 5 years, using the terms ("Zika Virus Infection", "ZikV Infection", "Zika Virus Disease") and ("Growth", "Failure to Thrive", "Growth and Development", "Nutrition Assessment", "Nutritional Status", "Deficiency Diseases", "Child Nutrition", "Infant Nutrition", "Recommended Dietary Allowances", "Diet, Food and Nutrition", "Nutritional Requirements", "Nutrition Status", "Nutrition Assessment"). The search was also carried out in Google Scholar. A total of 182 articles were found. After careful evaluation by two authors (MMM and ABG), based on their association to the proposed theme, 171 articles were excluded after reading the title and six after reading the abstract; thus, a total of eight articles that analyzed the growth of children exposed to intrauterine infection by the Zika virus were (Table 1).⁷7 Van der Linden V, Pessoa A, Dobyns W, Barkovich AJ, Júnior HV, Filho EL, et al. Description of 13 infants born during October 2015-January 2016 with congenital Zika virus infection without microcephaly at birth - Brazil. MMWR Morb Mortal Wkly Rep. 2016;65:1343-8.^,¹⁰10 Moura da Silva AA, Ganz JSS, Sousa PS, Doriqui MJR, Ribeiro MRC, Branco MRFC, et al. Early growth and neurologic outcomes of infants with probable congenital Zika virus syndrome. Emerg Infect Dis. 2016;22:1953-6.

11 Paul AM, Acharya D, Neupane B, Thompson A, Gonzales-Fernandez G, Copeland KM, et al. Congenital Zika virus infection in immunocompetent mice causes postnatal growth impediment and neurobehavioral deficits. Front Microbiol. 2018;9:2028.

12 Valentine GC, Seferovic MD, Stephanie WF, Major AM, Gorchakov R, Berry R, et al. Time of gestational exposure to Zika virus is associated with postnatal growth restriction in a murine model. Am J Obstet Gynecol. 2018;219:403.e1-403.e9.

13 Walker CL, Merriam AA, Ohuma EO, Dighe MK, Gale Jr M, Rajagopal L, et al. Femur-sparing pattern of abnormal fetal growth in pregnant women from New York City after maternal Zika virus infection. Am J Obstet Gynecol. 2018;219:187.e1-187.e20.

14 Leandro CG. Nutritional status and gross motor function in children with cerebral palsy, and implications for Zika virus infection. Dev Med Child Neurol. 2016;58:893-4.

15 Subissi L, Dub T, Besnard M, Mariteragi-Helle T, Nhan T, Lutringer-Magnin D, et al. Zika virus infection during pregnancy and effects on early childhood development, French Polynesia, 2013-2016. Emerg Infect Dis. 2018;24:1850-8.^-¹⁶16 França TL, Medeiros WR, Souza NL, Longo E, Pereira SA, França TB, et al. Growth and development of children with microcephaly associated with congenital Zika virus syndrome in Brazil. Int J Environ Res Public Health. 2018, doi:10.3390/ijerph15091990.
https://doi.org/10.3390/ijerph15091990...

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Table 1
Selected scientific articles that addressed the growth of children exposed to intrauterine infection by Zika virus.

Additionally, the anthropometric data of a cohort of children followed-up at the Follow-up Outpatient Clinic at the UFRJ School Maternity Unit were reviewed as part of a research protocol approved by the institution's Research Ethics Committee (REC) under No. 1,541,109 (CAAE 55465616.0.0000.5275). In this cohort, all participating children were found to be exposed to the Zika virus during pregnancy, based on: (1) positive result of polymerase chain reaction (PCR) test for Zika virus in maternal blood; (2) presence of positive IgM for Zika virus in maternal blood, or (3) probable congenital infection with Zika virus, according to the clinical-epidemiological criteria of the Brazilian Ministry of Health.

These patients were followed-up from birth to 2.5 years of age, from February 2016 to August 2018. At each consultation, weight, length, and head circumference measurements were performed by a previously trained team. A calibrated digital scale, stadiometer, and non-extensible measuring tape were used for measuring the head circumference. The measured values were entered in the WHO charts according to age and gender. This cohort was divided into three distinct groups: (1) microcephalic, (2) normocephalic, with some neurological abnormality detected during the follow-up, (3) normocephalic, without neurological abnormalities.

Synthesis of data and discussion

Congenital Zika syndrome

Small case series have described some congenital and postnatal characteristics of intrauterine infection by the Zika virus. In addition to microcephaly, this group of children may present intrauterine growth retardation, reduced brain volume, brain malformations (especially subcortical calcifications, ventriculomegaly and cortical migration defects), craniofacial disproportion, skin accumulation in the occipital region, hyperexcitability, hypertonia, irritability, epilepsy, dysphagia, and arthrogryposis.¹⁷17 Soares de Oliveira-Szejnfeld P, Levine D, Melo AS, Amorim MM, Batista AG, Chimelli L, et al. Congenital brain abnormalities and Zika virus: what the radiologist can expect to see prenatally and postnatally. Radiology. 2016;281:203-18.

18 Van der Linden V, Filho EL, Lins OG, Van der Linden A, Aragão Mde F, Brainer-Lima AM, et al. Congenital Zika syndrome with arthrogryposis: retrospective case series study. BMJ. 2016;354:i3899.^-¹⁹19 Saad T, Penna e Costa AA, de Góes FV, de Freitas M, de Almeida JV, Ignêz LJ, et al. Neurological manifestations of congenital Zika virus infection. Childs Nerv Syst. 2018;34:73-8.

During the evolution follow-up, there is a delay in the acquisition of developmental milestones, with difficulty in sustaining cervical and appendicular hypertonia. The persistence of primitive reflexes is also observed, in addition to pyramidal (hypertonia, hyperreflexia, clonus, and persistence of primitive reflexes), and extrapyramidal (fluctuating tonus and symmetrical dyskinesia of the extremities during wakefulness) signs and symptoms¹⁰10 Moura da Silva AA, Ganz JSS, Sousa PS, Doriqui MJR, Ribeiro MRC, Branco MRFC, et al. Early growth and neurologic outcomes of infants with probable congenital Zika virus syndrome. Emerg Infect Dis. 2016;22:1953-6.^,²⁰20 Pessoa A, van der Linden V, Yeargin-Allsopp M, Carvalho MD, Ribeiro EM, Braun KV, et al. Motor abnormalities and epilepsy in infants and children with evidence of congenital Zika virus infection. Pediatrics. 2018;141:S167. in children with and without microcephaly at birth.⁷7 Van der Linden V, Pessoa A, Dobyns W, Barkovich AJ, Júnior HV, Filho EL, et al. Description of 13 infants born during October 2015-January 2016 with congenital Zika virus infection without microcephaly at birth - Brazil. MMWR Morb Mortal Wkly Rep. 2016;65:1343-8.^,⁸8 Cardoso TF, Santos RS, Corrêa RM, Campos JV, Silva RB, Tobias CC, et al. Congenital Zika infection: neurology can occur without microcephaly. Arch Dis Child. 2019;104:199-200. Ocular abnormalities, such as the presence of pigmented macules, chorioretinal atrophy in the macular region, and loss of visual function, probably associated with cortical visual loss, have also been described in 21-55% of the cases.²¹21 Ventura LO. Ophthalmologic manifestations associated with Zika virus infection. Pediatrics. 2018;141:S161-6.

22 Ventura CV, Maia M, Travassos SB, Martins TT, Patriota F, Nunes ME, et al. Risk factors associated with the ophthalmologic findings identified in infants with presumed Zika virus congenital infection. JAMA Ophthalmol. 2016;134:912-8.^-²³23 Ventura LO, Ventura CV, Lawrence L, van der Linden V, van der Linden A, Gois AL, et al. Visual impairment in children with congenital Zika syndrome. J AAPOS. 2017;21:9-295.

Although they have an important impact, these changes reported as part of CZS are found mainly in children who have microcephaly at birth. However, there has been an increasing interest by researchers and healthcare teams regarding the consequences of congenital Zika infection in non-microcephalic newborns, and the first reports on the evolution of this group are beginning to appear.⁷7 Van der Linden V, Pessoa A, Dobyns W, Barkovich AJ, Júnior HV, Filho EL, et al. Description of 13 infants born during October 2015-January 2016 with congenital Zika virus infection without microcephaly at birth - Brazil. MMWR Morb Mortal Wkly Rep. 2016;65:1343-8.^,⁸8 Cardoso TF, Santos RS, Corrêa RM, Campos JV, Silva RB, Tobias CC, et al. Congenital Zika infection: neurology can occur without microcephaly. Arch Dis Child. 2019;104:199-200. Animal studies have demonstrated the occurrence of growth and developmental changes in oligosymptomatic animals at birth,¹¹11 Paul AM, Acharya D, Neupane B, Thompson A, Gonzales-Fernandez G, Copeland KM, et al. Congenital Zika virus infection in immunocompetent mice causes postnatal growth impediment and neurobehavioral deficits. Front Microbiol. 2018;9:2028. which appears to be associated with the gestational period during which the infection occurred.¹²12 Valentine GC, Seferovic MD, Stephanie WF, Major AM, Gorchakov R, Berry R, et al. Time of gestational exposure to Zika virus is associated with postnatal growth restriction in a murine model. Am J Obstet Gynecol. 2018;219:403.e1-403.e9.

Intrauterine growth

Intrauterine growth restriction, represented by fetal weight <10th percentile in the standard curves used, has been observed in approximately 10-18% of the pregnancies that report infection of the pregnant woman by the Zika virus.¹³13 Walker CL, Merriam AA, Ohuma EO, Dighe MK, Gale Jr M, Rajagopal L, et al. Femur-sparing pattern of abnormal fetal growth in pregnant women from New York City after maternal Zika virus infection. Am J Obstet Gynecol. 2018;219:187.e1-187.e20.^,²⁴24 Brasil P, Pereira JP Jr, Moreira ME, Ribeiro Nogueira RM, Damasceno L, Wakimoto M, et al. Zika virus infection in pregnant women in Rio de Janeiro. N Engl J Med. 2016;375:2321-34. In these cases, ultrasonography studies present a pattern of head and abdominal circumference reduction, with relative preservation of the femoral length, leading to a disproportion in the head circumference/femoral length and abdominal circumference/femoral length ratios (<10th percentile).¹³13 Walker CL, Merriam AA, Ohuma EO, Dighe MK, Gale Jr M, Rajagopal L, et al. Femur-sparing pattern of abnormal fetal growth in pregnant women from New York City after maternal Zika virus infection. Am J Obstet Gynecol. 2018;219:187.e1-187.e20.

Regarding cerebral growth impairment, which leads to microcephaly, reports have shown that the earlier in the pregnancy the maternal infection occurs, the greater the risk of microcephaly.²⁴24 Brasil P, Pereira JP Jr, Moreira ME, Ribeiro Nogueira RM, Damasceno L, Wakimoto M, et al. Zika virus infection in pregnant women in Rio de Janeiro. N Engl J Med. 2016;375:2321-34. Sophisticated bench studies using mini-brains originated from induced pluripotent stem cells (iPS), infected early with Zika virus, demonstrated the great destructive power of the virus on the formation of neural spheres and cortical neural precursors.²⁵25 Garcez PP, Loiola EC, Costa RM, Higa LM, Trindade P, Delvecchio R, et al. Zika virus impairs growth in human neurospheres and brain organoids. Science. 2016;352:816-8.^,²⁶26 Tang H, Hammack C, Ogden SC, Wen Z, Qian X, Li Y, et al. Zika virus infects human cortical neural precursors and attenuates their growth. Cell Stem Cell. 2016;18:587-90.

Birth weight

The case series of children exposed to Zika virus during pregnancy show that the prevalence of low birth weight and of infants born small for gestational age may be twice the usual rate.¹⁰10 Moura da Silva AA, Ganz JSS, Sousa PS, Doriqui MJR, Ribeiro MRC, Branco MRFC, et al. Early growth and neurologic outcomes of infants with probable congenital Zika virus syndrome. Emerg Infect Dis. 2016;22:1953-6.^,²⁴24 Brasil P, Pereira JP Jr, Moreira ME, Ribeiro Nogueira RM, Damasceno L, Wakimoto M, et al. Zika virus infection in pregnant women in Rio de Janeiro. N Engl J Med. 2016;375:2321-34.^,²⁷27 De Araújo TVB, Rodrigues LC, De Alencar Ximenes RA, De Barros Miranda-Filho D, Montarroyos UR, De Melo AP, et al. Association between Zika virus infection and microcephaly in Brazil, January to May, 2016: preliminary report of a case-control study. Lancet Infect Dis. 2016;16:1356-63.^,²⁸28 Santa Rita TH, Barra RB, Peixoto GP, Mesquita PG, Barra GB. Association between suspected Zika virus disease during pregnancy and giving birth to a newborn with congenital microcephaly: a matched case-control study. BMC Res Notes. 2017;10:457. Children with low birth weight or those who are small for gestational age usually achieve lower weight, height, and head circumference during the growth process, in addition to having less lean mass and a higher percentage of body fat mass.¹⁴14 Leandro CG. Nutritional status and gross motor function in children with cerebral palsy, and implications for Zika virus infection. Dev Med Child Neurol. 2016;58:893-4.^,²⁹29 Moura-Dos-Santos M, Wellington-Barros J, Brito-Almeida M, Manhães-de-Castro R, Maia J, Góis Leandro C. Permanent deficits in handgrip strength and running speed performance in low birth weight children. Am J Hum Biol. 2013;25:58-62.

Postnatal growth and intervening factors

In a cohort of 45 children with probable congenital Zika syndrome, Moura da Silva et al.¹⁰10 Moura da Silva AA, Ganz JSS, Sousa PS, Doriqui MJR, Ribeiro MRC, Branco MRFC, et al. Early growth and neurologic outcomes of infants with probable congenital Zika virus syndrome. Emerg Infect Dis. 2016;22:1953-6. observed short length in 43.2% and low weight in 19.6% of newborns as early as at birth. Moreover, during the prospective follow-up of these children, the latter maintained short length and low weight at 8 months of age.

Poor dietary intake is one of the main factors leading to inadequate nutritional status in children with some type of neurological impairment.⁹9 Penagini F, Mameli C, Fabiano V, Brunetti D, Dilillo D, Zuccotti GV. Dietary intakes and nutritional issues in neurologically impaired children. Nutrients. 2015;7:9400-15. Only 20% of these children receive adequate caloric intake. The energy requirements of this group of children is associated with body composition, motor impairment degree, and physical activity level, including rehabilitation, which may increase the daily energy requirements.³⁰30 Quitadamo P, Thapar N, Staiano A, Borrelli O. Gastrointestinal and nutrition problems in neurologically impaired children. Eur J Paediatric Neurol. 2016;20:810-5. These patients usually require more energy for ambulation, while those who do not ambulate require approximately 60-70% of the energy needs when compared to children without neurological impairment of the same age group and gender.³¹31 Romano C, van Wynckel M, Hulst J, Broekaert I, Bronsky J, Dall'Oglio L, et al. European Society for Paediatric Gastroenterology, Hepatology and nutrition guidelines for the evaluation and treatment of gastrointestinal and nutritional complications in children with neurological impairment. JPGN. 2017;65:242-64. In general, multiple factors can affect the adequate dietary intake of these children, even with different degrees of neurological impairment. Sensory factors related to the texture and taste of food may lead to a limited consumption of certain food groups. Fatigue is another contributing factor to an inadequate food intake, both the fatigue that can be observed before meals and that which occurs due to the effort during the feeding process of these patients.³²32 Rempel G. The importance of good nutrition in children with cerebral palsy. Phys Med Rehabil Clin N Am. 2015;26:39-56. Meals that last a very long time result in stress and fatigue to both the child and the parents, leading to negative behaviors being associated with feeding moments. Other factors include disturbances in the feeling of hunger and satiety, inability to communicate about one's nutritional needs, dental caries, dental malocclusion, and secondary conditions such as gastroesophageal reflux and constipation.³³33 Sullivan RB, Lambert B, Rose M, Ford-Adams M, Johnson A, Griffiths P. Prevalence and severity of feeding and nutritional problems in children with neurological impairment: Oxford Feeding Study. Dev Med Child Neurol. 2000;42:674-80. Micronutrient deficiencies (calcium, iron, zinc, selenium, and vitamins C, D, and E) are also common in these children with neurological impairment and may contribute to growth deficit.³⁴34 Kalra S, Aggarwal A, Chillar N. Comparison of micronutrient levels in children with cerebral palsy and neurologically normal controls. Indian J Pediatr. 2015;82:140-4.

35 Le Roy C, Barja S, Sepúlveda C, Guzmán ML, Olivarez M, Figueroa MJ, et al. Deficiencia de vitamina D y de hierro en niños y adolescentes con parálisis cerebral. Neurologia. 2017. doi: 10.1016/j.nrl.2017.11.005.
https://doi.org/10.1016/j.nrl.2017.11.00... ^-³⁶36 Papadopoulos A, Ntaios G, Kaiafa G, Girtovitis F, Saouli Z, Kontoninas Z, et al. Increased incidence of iron deficiency anemia secondary to inadequate iron intake in institutionalized Young patients with cerebral palsy. Int J Hematol. 2008;88:495-7.

Other non-nutritional factors may affect the weight-height growth of children with CZS-associated microcephaly. Children with intellectual disability are at increased risk of malnutrition and growth deficits, especially when the intellectual disability is associated with cerebral palsy; this association is observed in approximately 50% of cases. Obesity may also be a nutritional problem in this population, especially in those with low physical activity and who do not have swallowing dysfunction.³⁷37 Sánchez-lastres J, Eiris-Punal J, Otero-Cepeda JL, Pavon-Belinchón P, Castro-Gago M. Nutritional status of mentally retarded children in north-west Spain, I. Anthropometric indicators. Acta Paediatr. 2003;92:747-53.

The use of antiepileptic drugs, common in children with microcephaly due to CZS, is also associated with weight gain, and can be observed in up to 57% of patients with chronic use of valproic acid, probably due to metabolic changes due to the decrease in the beta-oxidation of fatty acids and increase in insulin and leptin levels.³⁸38 Yacubian EM, Cotreras-Caicedo G, Ríos-Pohl L. Tratamento medicamentoso das epilepsias. São Paulo: Leitura Médica Ltda; 2014. In turn, weight loss is commonly observed with chronic use of topiramate, possibly involving a reduction in the caloric intake, hormonal involvement (especially adiponectin), and changes in lipid and glucose metabolism.³⁹39 Verrotti A, Scaparrotta A, Agostinelli S, Di Pillo S, Chiarelli F, Grosso S. Topiramate-induced weight loss: a review. Epilepsy Res. 2011;5:189-99.

Growth curves

The Brazilian Ministry of Health recommends monitoring the growth of children with congenital Zika virus infection by using the growth curves of The International Fetal and Newborn Growth Consortium for the 21st Century (Intergrowth 21st) for preterm infants up to 64 weeks of corrected gestational age and the WHO growth curves for children born full-term and post-term.⁴⁰40 Brasil Ministério da Saúde. Secretaria de Vigilância em Saúde. Secretaria de Atenção à Saúde. Orientações integradas de vigilância e atenção à saúde no âmbito da emergência de saúde pública de importância nacional. Brasília: Ministério da Saúde; 2017.^,⁴¹41 De Onis M, World Health Organization. WHO Child Growth Standards; methods and development. Geneva: World Health Organization 2006. [cited on 2018 Sep 26]. Available from: www.who.int/childgrowth/standards/en.
www.who.int/childgrowth/standards/en... The equations proposed by Stevenson allow the evaluation of stature in children aged 2-12 years who are unable to stand upright.⁴²42 Stevenson RD. Use of segmental measures to estimate stature in children with cerebral palsy. Arch Pediatr Adolesc Med. 1995;149:658-62.

Weight-length and head circumference growth in a cohort exposed to intrauterine infection by Zika virus

Due to the lack of data in the literature on the growth of children whose mothers were at risk for Zika virus infection during pregnancy, the authors present the evolution of the anthropometric data of a cohort of 29 patients divided as follows: (a) five children with congenital microcephaly and severe neurological impairment; (b) 11 children normocephalic at birth, with some mild neurological abnormality detected during follow-up; and (c) 13 children normocephalic at birth, with no neurological abnormalities detected during follow-up (Table 2).

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Table 2
Evolution of a cohort of 29 patients whose mothers were proven to have been exposed to the Zika virus during pregnancy.

The anthropometric data (head circumference and length [in cm] and weight [in kg]) obtained during the prospective follow-up of these children were plotted into the following WHO charts:⁴¹41 De Onis M, World Health Organization. WHO Child Growth Standards; methods and development. Geneva: World Health Organization 2006. [cited on 2018 Sep 26]. Available from: www.who.int/childgrowth/standards/en.
www.who.int/childgrowth/standards/en... head circumference × age (months), weight × age (months) and length × age (months) for boys and girls (Figs. 1^-3).

Figure 1
Head circumference evolution in the first 2.5 years of life in a cohort of 29 children whose mothers were exposed to Zika virus during pregnancy, five of whom had congenital microcephaly and severe neurological impairment, 11 normocephalic children at birth, with some type of neurological abnormality detected during follow-up, and 13 normocephalic children at birth, without neurological abnormalities during follow-up.

Figure 2
Weight gain in the first 2.5 years of life in a cohort of 29 children whose mothers were exposed to Zika virus during pregnancy, five of whom had congenital microcephaly and severe neurological impairment, 11 normocephalic children at birth, with some mild neurological abnormality detected during follow-up, and 13 normocephalic children at birth, without neurological abnormalities during follow-up.

Figure 3
Height evolution in the first 2.5 years of life in a cohort of 29 children whose mothers were exposed to Zika virus during pregnancy, five of whom had congenital microcephaly and severe neurological impairment, 11 normocephalic children at birth, with some mild neurological abnormality detected during follow-up, and 13 normocephalic children at birth, without neurological abnormalities during follow-up.

Children born with microcephaly maintained a head circumference measurement below three standard deviations (SD) during the first 2 years of life. Normocephalic children had adequate head circumference growth during the same period. The weight gain, however, remained within the range of +1SD to −2SD for microcephalic boys and for normocephalic children with neurological abnormalities, whereas normocephalic children without neurological abnormalities remained between the median and +2SD. In girls, no difference was observed in weight gain between normocephalic patients with or without neurological abnormalities, whereas lower weight gain was observed in microcephalic girls (between the median and -3DP). Regarding length, the evolution during the first 2 years of life was similar between boys and girls, with values ranging from −3SD to +2SD, but with a tendency toward lower values in microcephalic children (below the median) and more intense in girls.

These data suggest there is an association between the presence of neurological impairment and weight-height deficit in children exposed to Zika virus during pregnancy. The probable risk for growth deficiency appears to be associated with the presence of some degree of neurological impairment, even in children born without microcephaly. In the present cohort, head circumference growth during the first 2 years of life was associated with head circumference at birth. Children born with microcephaly remained microcephalic and normocephalic children remained with normal values for age. This behavior is probably associated with the higher degree of brain structure impairment in children born with microcephaly, since cranial growth depends on adequate brain growth and the latter is lower in the presence of more severe brain malformations. Weight-height growth was not as poor as the head circumference growth, but there was a trend toward lower weight and length during the first 2 years of life in children with congenital microcephaly and in normocephalic children who presented minor neurological abnormalities (more often observed in girls than in boys). Children with some degree of neurological impairment have a higher risk of weight-height deficit, directly related to the degree of neurological impairment, which is in agreement with the recent literature on the subject.⁹9 Penagini F, Mameli C, Fabiano V, Brunetti D, Dilillo D, Zuccotti GV. Dietary intakes and nutritional issues in neurologically impaired children. Nutrients. 2015;7:9400-15.^,³⁰30 Quitadamo P, Thapar N, Staiano A, Borrelli O. Gastrointestinal and nutrition problems in neurologically impaired children. Eur J Paediatric Neurol. 2016;20:810-5.^,⁴³43 Herrera-Anaya E, Angarita-Fonseca A, Herrera-Galindo V, Rodríguez-Bayona C. Association between gross motor function and nutritional status in children with cerebral palsy: a cross-sectional study from Colombia. Dev Med Child Neurol. 2016;58:936-41. Nutritional and non-nutritional factors may contribute to weight-height deficits in these children. Nevertheless, the children in the present cohort did not show significant weight-height deficit. This may be due to the fact that they were followed-up since birth at a multiprofessional service of a university hospital, where different professionals in the areas of pediatrics, child neurology, physical therapy, nutrition, and speech therapy contributed to the prevention and early approach of factors that could contribute to the weight-height deficit in this group of children.

Conclusions

To date, there are scarce data in the literature demonstrating that congenital Zika virus infection can affect infant weight-height growth. The few existing data suggest that, in children with congenital Zika, the greater the degree of neurological impairment, the greater the impact on growth, whether or not associated with microcephaly at birth.

☆
Please cite this article as: Prata-Barbosa A, Martins MM, Guastavino AB, Cunha AJ. Effects of Zika infection on growth. J Pediatr (Rio J). 2019;95:S30-S41.
☆☆
Please add 2 more stars here connected to: Study conducted at Universidade Federal do Rio de Janeiro (UFRJ), Rio de Janeiro, RJ, Brazil.

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Publication Dates

Publication in this collection
18 Apr 2019
Date of issue
2019

History

Received
30 Sept 2018
Accepted
15 Oct 2018

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivative License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

[1] ☆
Please cite this article as: Prata-Barbosa A, Martins MM, Guastavino AB, Cunha AJ. Effects of Zika infection on growth. J Pediatr (Rio J). 2019;95:S30-S41.

[2] ☆☆
Please add 2 more stars here connected to: Study conducted at Universidade Federal do Rio de Janeiro (UFRJ), Rio de Janeiro, RJ, Brazil.

Authors	Year of publication	Main findings
Van der Linden V et al.	2016⁷7 Van der Linden V, Pessoa A, Dobyns W, Barkovich AJ, Júnior HV, Filho EL, et al. Description of 13 infants born during October 2015-January 2016 with congenital Zika virus infection without microcephaly at birth - Brazil. MMWR Morb Mortal Wkly Rep. 2016;65:1343-8.	Case series on 13 children exposed to intrauterine Zika virus, born with normal head circumference (0.30 to −2 SD). All children showed a decline in head circumference growth at follow-up visits (ranging from 5 to 12 months of age) with progression to microcephaly. All patients also had clinical neurological abnormalities.
Moura da Silva AA et al.	2016¹⁰10 Moura da Silva AA, Ganz JSS, Sousa PS, Doriqui MJR, Ribeiro MRC, Branco MRFC, et al. Early growth and neurologic outcomes of infants with probable congenital Zika virus syndrome. Emerg Infect Dis. 2016;22:1953-6.	Prospective follow-up of 48 children diagnosed with probable congenital Zika syndrome. The Z-score for head circumference at birth ranged between >2 and <3 SD in 22.2% of the children and ≤3 SD in 64.5%. The Z-score for birth weight was ≤2 SD in 19.6% and, for birth length, it was ≤2 SD in 43.2%. Throughout the 8 months of follow-up, it was observed that the mean Z-score for head circumference decreased −0.46 per month, −0.08 per month for weight, and −0.16 per month for length.
Paul AM et al.	2018¹¹11 Paul AM, Acharya D, Neupane B, Thompson A, Gonzales-Fernandez G, Copeland KM, et al. Congenital Zika virus infection in immunocompetent mice causes postnatal growth impediment and neurobehavioral deficits. Front Microbiol. 2018;9:2028.	A study describing pups of immunocompetent female rats exposed to the Zika virus during pregnancy, which showed no apparent birth defects, but developed postnatal growth and neurobehavioral (motor and cognitive) deficits.
Valentine GC et al.	2018¹²12 Valentine GC, Seferovic MD, Stephanie WF, Major AM, Gorchakov R, Berry R, et al. Time of gestational exposure to Zika virus is associated with postnatal growth restriction in a murine model. Am J Obstet Gynecol. 2018;219:403.e1-403.e9.	Exposure of 15 pregnant female rats to the Zika virus on days 4, 8, and 12 of gestation. Intrauterine growth restriction was observed in those with earlier exposure to the virus (days 4 and 8). Growth deficit was observed in all exposed rats at 6 weeks of age. Zika virus appears to interfere with intrauterine growth, as well as with postnatal growth.
Walker CL et al.	2018¹³13 Walker CL, Merriam AA, Ohuma EO, Dighe MK, Gale Jr M, Rajagopal L, et al. Femur-sparing pattern of abnormal fetal growth in pregnant women from New York City after maternal Zika virus infection. Am J Obstet Gynecol. 2018;219:187.e1-187.e20.	Follow-up of the fetal growth of 56 pregnant women with Zika virus infection confirmed during pregnancy. Head circumference, abdominal circumference, and femur length measurements were performed in fetuses exposed throughout gestation. They observed three cases with microcephaly and ten cases with intrauterine growth restriction (IUGR). Measurements of head and abdominal circumference were more sensitive to detect IUGR because most fetuses showed lower impairment in femur length measurements.
Leandro CG.	2016¹⁴14 Leandro CG. Nutritional status and gross motor function in children with cerebral palsy, and implications for Zika virus infection. Dev Med Child Neurol. 2016;58:893-4.	Comment to the article by Herrera-Anaya et al. The author comments on the possible association between Zika virus exposure during pregnancy and postnatal growth impairment, since growth can be affected according to the degree of motor impairment in children with cerebral palsy.
Subissi L et al.	2018¹⁵15 Subissi L, Dub T, Besnard M, Mariteragi-Helle T, Nhan T, Lutringer-Magnin D, et al. Zika virus infection during pregnancy and effects on early childhood development, French Polynesia, 2013-2016. Emerg Infect Dis. 2018;24:1850-8.	Case-control study with children from the French Guiana exposed or not to the Zika virus during intrauterine life. A higher percentage of low birth weight was observed in children exposed to the Zika virus, but no difference in weight and length was observed in those who were clinically evaluated close to 2 years of age.
França TL et al.	2018¹⁶16 França TL, Medeiros WR, Souza NL, Longo E, Pereira SA, França TB, et al. Growth and development of children with microcephaly associated with congenital Zika virus syndrome in Brazil. Int J Environ Res Public Health. 2018, doi:10.3390/ijerph15091990. https://doi.org/10.3390/ijerph15091990...	Observational cross-sectional study of eight children with congenital Zika syndrome compared to 16 children without congenital infection, with a mean age 20.5 months, in northeastern Brazil. They observed that children with congenital Zika, in addition to motor and cognitive delay, also had lower rates of head circumference growth and weight gain.

Case	HC at birth	GA at the infection (weeks)	GA at birth (weeks)	Weight at birth (g)	Length at birth (cm)	HC at birth (cm)	Apgar 5th minute	Z-score for growth	Neuroimaging (findings)	Development (Gesell)	Treatment
1	Microcephalic	10	39	2690	47	30	9	Weight: −1.23 to −0.86 Length: −1.15 to −0.43 HC: -3.53 to −4.43	Findings "a"	Important overall developmental delay	Physical therapy, speech therapy, and stimulation. Use of clonazepam and topiramate.
2	Microcephalic	12	38 + 1	3140	45	29.5	9	Weight: −0.52 to −1.29 Length: −2.58 to −1.68 HC: −3.91 to −4.81	Findings "b"	Important overall developmental delay	Physical therapy, speech therapy, and stimulation.
3	Microcephalic	No symptoms	39	3570	48.5	31.5	9	Weight: −0.51 to −0.98 Length: −0.73 to −1.38 HC: −2.33 to −3.15	Findings "c"	Important overall developmental delay	Physical therapy, speech therapy, and stimulation.
4	Microcephalic	No symptoms	37 + 1	2110	43	27.5	9	Weight: −2.95 to −2.06 Length: −3.64 to −1.73 HC: −5.48 to −5.46	Findings "d"	Important overall developmental delay	Physical therapy, speech therapy, and stimulation.
5	Microcephalic	12	38 + 3	2005	40	29	9	Weight: −3.09 to −4.74 Length: −4.37 to −3.10 HC: −4.12 to −6.48	Findings "e"	Important overall developmental delay	Physical therapy, speech therapy, and stimulation.
6	Normocephalic	25	31 + 3	1620	38.5	28.5	9	Weight: −0.02 to −1.26 Length: −1.21 to −3.83 HC: −0.27 to −1.64	Normal	Adaptive, fine motor and language delay	Physical therapy, speech therapy, and stimulation.
7	Normocephalic	38 + 5	39	3395	51	35	9	Weight: 0.36 to 1.17 Length: 0.99 to 1.01 HC: 0.95 to −0.17	Normal	Adaptive, fine motor language and personal-social delay	Physical therapy, speech therapy, and stimulation.
8	Normocephalic (twin 1)	21	32	1905	44	30	8	Weight: 0.74 to 0.92 Length: 0.78 to 1.23 HC: 0.51 to 0.23	Normal	Language delay	Speech therapy and stimulation.
9	Normocephalic (twin 2)	21	32	1650	40.5	31.5	8	Weight: −0.88 to 0.02 Length: −1.05 to −0.55 HC: 0.59 to 1.48	Normal	Language delay	Speech therapy and stimulation.
10	Normocephalic	21	39 + 1	3540	48.5	34	9	Weight: 0.31 to 0.83 Length: −0.73 to 0.40 HC: −0.36 to 0.29	Normal	Adaptive, fine motor language and Personal-Social delay	Physical therapy, speech therapy and stimulation.
11	Normocephalic	12 + 5	40 + 4	3570	49	36	9	Weight: 1.18 to 0.55 Length: −0.08 to 0.74 HC: 1.79 to 1.68	Subcortical calcification in frontal and parietal lobes	Normal	Stimulation.
12	Normocephalic	37 + 3	39	2995	47.5	35	9	Weight: −0.73 to −0.31 Length: −1.26 to −0.43 HC: 0.42 to −0.31	Normal	Fine motor delay	Physical therapy and stimulation.
13	Normocephalic	34	39	2870	46	35	9	Weight: −0.75 to −0.99 Length: −1.69 to −0.85 HC: −0.99 to −1.04	Myelination is more evident than usual	Normal	Stimulation.
14	Normocephalic	8	38 + 4	2785	48	34	7	Weight: −0.75 to −0.39 Length: −0.62 to −0.20 HC: 0.10 to 0.56	Slight increase in the frontal CSF space with mild ectasia of lateral ventricles	Language delay	Speech therapy and stimulation.
15	Normocephalic	16 + 2	39 + 4	3080	49.5	33	10	Weight: −0.29 to 1.06 Length: 0.19 to 1.63 HC: 3.48 to 2.70	Normal	Normal	Stimulation.
16	Normocephalic	35	39	3340	50	33.5	9	Weight: 0.15 to −0.57 Length: 0.46 to −0.92 HC: −0.32 to −0.08	Discrete prominent perivascular spaces in peritrigonal regions	Normal	Stimulation.
17	Normocephalic	28 + 4	38 + 2	2620	47	34	9	Weight: −1.655 to −0.67 Length: −1.52 to −0.25 HC: −0.36 to −0.50	Normal	Normal	Stimulation.
18	Normocephalic	26 + 6	37	2855	48.5	33.5	9	Weight: −0.75 to −1.68 Length: −0.35 to −0.91 HC: −0.32 to −0.43	Normal	Normal	Stimulation.
19	Normocephalic	21	40 + 4	3350	50.5	34.5	9	Weight: 0.36 to 1.50 Length: 0.73 to 1.00 HC: 0.52 to 2.43	Not performed	Normal	Stimulation.
20	Normocephalic	5	40 + 4	3750	51	35	8	Weight: 1.18 to 1.40 Length: 0.99 to 1.34 HC: 0.95 to 1.66	Not performed	Normal	Stimulation.
21	Normocephalic	9	40 + 1	3535	50.5	34.5	9	Weight: 0.78 to 0.42 Length: 0.73 to 0.33 HC: 0.52 to 1.4	Normal	Normal	Stimulation.
22	Normocephalic	9	38	2160	43.4	31.7	9	Weight: −2.53 to −0.31 Length: −3.09 to −1.86 HC: −1.84 to 1.24	Normal	Normal	Stimulation.
23	Normocephalic	9	39 + 5	3490	48	34	9	Weight: 0.57 to 0.56 Length: −0.62 to −0.07 HC: 0.10 to 1.50	Normal	Normal	Stimulation.
24	Normocephalic	19 + 4	38 + 4	3055	47.5	34	9	Weight: −0.29 to −0.14 Length: −0.88 to 0.42 HC: 0.10 to 0.93	Not performed	Normal	Stimulation.
25	Normocephalic	18	S/I	4130	52	36	9	Weight: 1.76 to 1.35 Length: 1.53 to 1.97 HC: 1.79 to 2.43	Normal	Normal	Stimulation.
26	Normocephalic	11 + 4	36 + 3	2990	46.5	33	9	Weight: −0.52 to 1.50 Length: −1.42 to 0.59 HC: −0.74 to 1.13	Normal	Normal	Stimulation.
27	Normocephalic	10	38 + 3	3220	48	35	9	Weight: 0.15 to 0.33 Length: −0.62 to 0.72 HC: 0.95 to 0.18	Normal	Normal	Stimulation.
28	Normocephalic	16	41 + 1	3850	46.7	35.7	9	Weight: 1.08 to 0.37 Length: −1.68 to −0.28 HC: 0.97 to 1.20		Normal	Stimulation.
29	Normocephalic	12	37 + 6	3200	48	36	9	Weight: −0.30 to 1.86 Length: −1.00 to 0.75 HC: 1.21 to 2.56	Normal	Normal	Stimulation.