Neonatal infection

Neonatal infections are infections of the neonate (newborn) acquired during prenatal development or in the first four weeks of life (neonatal period).[1] Neonatal infections may be contracted by mother to child transmission, in the birth canal during childbirth, or contracted after birth.[2] Some neonatal infections are apparent soon after delivery, while others may develop in the postnatal period. Some neonatal infections such as HIV, hepatitis B, and malaria do not become apparent until much later.

Neonatal infection
26-week gestation, premature infant, weighing <990gm with ventilator
SpecialtyInfectious disease, Pediatrics

There is a higher risk of infection for preterm or low birth weight neonates. Infant respiratory distress syndrome is often a condition of preterm neonates that can have long-term negative consequences, it can also arise following an infection. In some instances, neonatal respiratory tract diseases may increase the susceptibility to future respiratory infections and inflammatory responses related to lung disease.[3]

Antibiotics can be effective for neonatal infections, especially when the pathogen is quickly identified. Instead of relying solely on culturing techniques, pathogen identification has improved substantially with advancing technology; however, neonate mortality reduction has not kept pace and remains 20% to 50%.[4] While preterm neonates are at a particularly high risk, all neonates can develop infection. Neonatal infection may also be associated with premature rupture of membranes (breakage of the amniotic sac) which substantially increases the risk of neonatal sepsis by allowing passage for bacteria to enter the womb prior to the birth of the infant.[5][6] Neonatal infection can be distressing to the family and it initiates concentrated effort to treat it by clinicians. Research to improve treatment of infections and prophylactic treatment of the mother to avoid infections of the infant is ongoing.

Causes

In industrialized countries, treatment for neonatal infections takes place in the neonatal intensive care unit (NICU). The causes and reasons for neonatal infection are many. The origin of infectious bacteria and some other pathogens is often the maternal gastrointestinal and genitourinary tract. Many of the maternal infections with these organisms are asymptomatic in the mother. Other maternal infections that may be transmitted to the infant in utero or during birth are bacterial and viral sexually transmitted infections.[7] The infant's ability to resist infection is limited by its immature immune system. The causative agents of neonatal infection are bacteria, viruses, and fungi. In addition, the immune system of the neonate may respond in ways that can create problems that complicate treatment, such as the release of inflammatory chemicals. Congenital defects of the immune system also affect the infants ability to fight off the infection.[8][9]

Bacteria

Listeria monocytogenes

Group B streptococcus are typically identified as the cause of the majority of early-onset infections in the neonate.[7][10][11] This pathogen is vertically transmitted (transmitted directly from the mother) to the infant.[12] Enteric bacilli that originate from the digestive system of the mother have become as prevalent as the group B streptococcus pathogens and are currently as likely to cause infection. With the advances in preventing group B streptococcus infections, β-lactam-resistant Escherichia coli infections have increased in causing neonatal deaths in very low birthweight and premature infants.[12] Infections with Staphylococcus aureus are also diagnosed, but not as frequently as group B streptococcus infections.[5]

Listeria monocytogenes can also cause infection acquired from tainted food and present in the mother.[4][13] The presence of this pathogen can sometimes be determined by the symptoms that appear as a gastrointestinal illness in the mother. The mother acquires infection from ingesting food that contains animal products such as hot dogs, unpasteurized milk, delicatessen meats, and cheese.

Neonatal infection can also occur in term and post-term infants.[14] Infections that develop one month after the birth of the infant are more likely due to Gram-positive bacteria and coagulase positive staphylococci.[15] Acquired maternal infection and subsequent inflammation from Ureaplasma urealyticum is accompanied by a strong immune response and is correlated with the need for prolonged mechanical ventilation.[3][7]

Clostridium tetani can cause a generalised form of tetanus in the neonate. This usually occurs when the mother has not been vaccinated against tetanus and the baby has not acquired passive immunity. The umbilical cord region is the most susceptible.[16]

Other bacterial pathogens include Streptococcus agalactiae, Streptococcus pyogenes, Viridans streptococci, Streptococcus pneumoniae, Haemophilus influenzae, and Pseudomonas aeruginosa.[17]

Viruses

HIV

Human immunodeficiency virus type I (HIV) infection can occur during labor and delivery, in utero through mother-to-child transmission or postnatally by way of breastfeeding.[18] Transmission can occur during pregnancy, delivery or breastfeeding. Most transmission occurs during delivery. In women with low detectable levels of the virus, the incidence of transmission is lower.[19] Transmission risk can be reduced by:

  • providing antiretroviral therapy during pregnancy and immediately after birth
  • delivery by caesarean section
  • not breastfeeding
  • antiretroviral prophylaxis in infants born to mothers with HIV.[19]

A low number of women whose HIV status are unknown until after the birth, do not benefit from interventions that could help lower the risk of mother-to-child HIV transmission.[20]

Cytomegalovirus

Sixty percent of mothers of preterm infants are infected with cytomegalovirus (CMV). Infection is asymptomatic in most instances but 9% to 12% of postnatally infected low birth weight, preterm infants have severe, sepsis-like infection. CMV infection duration can be long and result in pneumonitis in association with fibrosis. CMV infection in infants has an unexpected effect on the white blood cells of the immune system causing them to prematurely age. This leads to a reduced immune response similar to that found in the elderly.[3]

HSV

Herpes simplex virus (HSV) can infect the infant during birth. Most women with HVS genital herpes develop asymptomatic infection during pregnancy. HVS inoculation from mother to fetus has a high likelihood of occurring. Mothers who are treated with antiviral prophylaxis are less prone to have an active, symptomatic case at the time of birth. Mothers who have received prophylactic antiviral medication have been shown to be less likely to require a cesarean section. At delivery, mothers treated with antiviral medication are less likely to have a viral shedding at the time of birth.[21]

Zika

Zika fever is caused by a virus that is acquired by the mother and then transmitted to the infant in utero. The CDC is concerned with the potential that this viral infection may cause microcephaly in newborns.[22][23][24]

Rubella

Congential rubella is still a risk with higher risk among immigrant women from countries without adequate vaccination programs.[20]

Other

Other viral infections such as respiratory syncytial virus (RSV), metapneumovirus (hMPV), rhinovirus, parainfluenza (PIV), and human coronavirus in the neonatal period are associated with recurrent wheezing in later childhood. RSV infections can be prolonged. Premature infants born at less than 32 weeks gestation have more days of cough and wheeze at 1 year of age than those uninfected with RSV.[3]

Fungi

In very low birth weight infants (VLBWI), systemic fungus infection is a hospital-acquired infection with serious consequences. The pathogens are usually Candida albicans and Candida parapsilosis. A small percentage of fungal infections are caused by Aspergillus, Zygomycetes, Malassezia, and Trichosporon.[25][26] Infection is usually late-onset. Up to 9% of VLBWI with birth weights of <1,000 g develop these fungus infections leading to sepsis or meningitis. As many as one-third of these infants can die. Candidiasis is associated with retinopathy, prematurity and negative neurodevelopmental consequences. Candida can colonize the gastrointestinal tract of low birthweight infants (LBI). This gastrointestinal colonization is often a precursor to a more serious invasive infection. The risk of serious candida infection increases when multiple factors are present. These are: thrombocytopenia, the presence of candidal dermatitis, the use of systemic steroids, birth weights of <1,000 g, presence of a central catheter, postponing enteral feeding, vaginal delivery, and the amount of time broad-spectrum antibiotics were given.[26]

Protozoans

Infants born with malaria can be infected with a variety of species; Plasmodium vivax, Plasmodium malariae, Plasmodium ovale, and Plasmodium falciparum. In most instances of congenital malaria is caused by P. vivax and P. falciparum. Women living in areas where malaria is prevalent and common are repeatedly exposed to malaria. In response to maternal infection, mothers develop antimalarial antibodies. It is probable that the antibodies present in the mother offers protection for the baby. Bacterial infection can develop with malaria.[25]

Infants that are infected by the protozoanToxoplasma gondii in utero can be born with chorioretinitis or ocular toxoplasmosis. Globally, it is the most common cause of infections of the back of the eye. (posterior segment). The most common sign is decreased vision in one eye. Other signs and symptoms may appear after the neonatal period and include: chorioretinitis development later in life, intracranial calcification hydrocephalus or central nervous system abnormalities.[27]

Risk factors

Risk factors are those conditions which increase the likelihood that an infant will be born with or develop an infection.

Risk factors for neonatal infection within the first week
FactorNotesReferences
prematuritybirth before 40 weeks gestation[8]
meconium aspirationinspiration of stool in utero[14]
Postpartum endometritisinflammation of the uterus after the birth[14]
low birth weight< 40 weeks gestation[8][15]
premature rupture of membranes<12 hours[5][8][15][28]
prolonged premature rupture of membranes>12 hours[5][28]
pre-term onset of laborlabor begins before 40 weeks gestation[8][15]
chorioamnionitisinflammation of the fetal membranes(amnion and chorion) due to a bacterial infection[8]
vaginal dischargeabnormal discharge can be a result of an infection[8]
tender uterusdiscomfort when the uterus is examined[29]
rupture of membranes<12 hours[5]
prolonged rupture of membranes>12 hours)[8][29]
in utero infection with pathogensthe period of infection
allows for the logarithmic growth
of pathogens
[7]
maternal urinary tract infectionbladder and/or kidney infection[8]
prolonged labor[29]
vaginal examinations during laborrisk increases with the number of vaginal examinations during labor[8][29]
maternal colonization with group B streptococcusthe presence of this bacterium is usually asymptomatic[5][8]
previous baby with early-onset GBS infection[8][29]
gendermales are more susceptible;This risk declines
after respiratory distress syndrome is treated
[15]
multiplesrisk is increased for the firstborn[15]
iron supplementationiron is a growth factor for
some bacteria
[15]
maternal intrapartum fever> 38 °C[8][28]
after insertion of intravenous linemay introduce pathogens into the circulation[15]
immature immune system[15]
invasive medical proceduresmay introduce pathogens into the circulation[15]
hypoxiaunexpected resuscitation
after birth
[15][29]
low socioeconomic status[15]
hypothermiarelatively low blood temperature[15]
metabolic acidosisa pH imbalance in the blood[15]
obstetrical complications[15]
prevalence of resistant bacteria in the neonatal intensive care unitnosomial populations[15]
maternal exposure to Toxoplasmosis gondiia parasite present in cat litter and other animal excrement[27]
Risk factors for late onset for neonatal infection >one week after birth
FactorNotesReferences
after insertion of an intravenous linehypothermia
poor feeding
lethargy
more likely to develop osteoarthritis
soft tissue infection
meningitits[15]
Mother resides in endemic malaria
area
[25]

The risk for developing catheter-related infections is offset by the increased survival rate of premature infants that have early onset sepsis. Intravenous administration of prophylactic immunoglobin enhances immunity of the immature infant and is used for treatment.[15]

Mechanism

Chorioamnionitis

Inflammation accompanies infection and is likely to complicate treatment and recovery. Inflammation is linked to reduced growth of the lungs of the premature baby.[3]

Pathogenesis

The recent identification of the presence of microorganisms in maternal-infant body fluids that were previously thought to be sterile has provided one explanation for the presence of the inflammatory response in both the mother and infant. Sixty-one percent of pregnant women with chorioamnionitis, or inflammation of the amniotic fluid, were found to be infected by microorganisms. Often, more than one pathogen was present. In fifteen percent of pregnant women inflammation was still evident even though there was no evidence of pathogens. This may indicate that there are other causes. A high percentage, 51% to 62%, of pregnant women who had chorioamnionitis also had inflammation of the placenta.[3]

Diagnosis

Diagnosis of infection is based upon the recovery of the pathogen or pathogens from the typically sterile sites in the mother or the baby. Unfortunately, as many half of pregnant women are asymptomatic with a gonorrhea infection and other sexually transmitted infections.[30][31][32] Samples are obtained from urine, blood or cerebrospinal fluid. Diagnosis of infection can also be aided by the use of more nonspecific tests such as determining the total white blood cell count, cytokine levels and other blood tests and signs.[15]

Signs of infectionNotesReferences
abnormal complete blood countlooking for signs of infection
in the blood:
increased white cell count; presence of immature neutrophils
[5][29]
increased C-reactive proteina chemical in the blood that shows
that the baby's immune system is actively reacting
to infection
[5][29][33]
accessory muscle useusing the intercostal muscles to assist in
breathing
[29]
tachycardiaa heart rate that is faster than normal[5]
bradycardiaa heart rate that is slower than normal[5]
chest recession[29]
respiratory distressthe baby has trouble breathing[5][29]
nasal flaringthe baby's nostrils expand
when it inhales
[29]
expiratory grunta sound of effort when the baby exhales[29][34]
apneathe baby stops breathing[5][29]
rash[29]
positive urine culture[5]
positive cerebral spinal fluid[5]
other positive culturesfrom eyes, ear canal, umbilicus
axilla anus
[5]
lethargythe baby seems tired and has slow or no movements[5][29]
hypotoniathe muscles seem flabby and weak[5][29]
hypothermia[5]
irritabilityinfant appears uncomfortable and
has difficulty being soothed
[5][29]
weak cry[29]
pneumonia[5]
poor perfusionpoor circulation[5][29]
hypotensionlow blood pressure[29]
acidosispH imbalance in the blood[5][29]
diarrheawater-like, unformed stools[29]
poor feeding[5]
oxygen requirement[5]
bulging fontanelthe soft spot on the head is bulging[29]
seizures[5][29]
fever[5]
disseminated intravascular coagulationwidespread clotting of blood[29]
renal failurekidneys do not function[29]
bacteremiabacteria cultured from the blood
of the newborn
[5]

Viral infection

Symptoms and the isolation of the virus pathogen the upper respiratory tract is diagnostic. Virus identification is specific immunologic methods and PCR. The presence of the virus can be rapidly confirmed by the detection of the virus antigen. The methods and materials used for identifying the RSV virus has a specificity and sensitivity approaching 85% to 95%. Not all studies confirm this sensitivity. Antigen detection has comparatively lower sensitivity rates that approach 65% to 75%.[35]

Protozoan infection

Congential malaria has its own set of signs:

Signs of congenital malaria infectionNotesReferences
splenomegalyenlarged speen
fever
anemia
jaundice
poor feeding
hepatomegalyenlarged liver
failure to thrive
loose stools
irritability
hyperbilirubinemia
central nervous system infection
splenic rupture
renal failure
blackwater feverinfection with
P. falciparum only
[25]

Neonatal sepsis

Neonatal sepsis of the newborn is an infection that has spread through the entire body. The inflammatory response to this systematic infection can be as serious as the infection itself.[3] In infants that weigh under 1500 g, sepsis is the most common cause of death. Three to four percent of infants per 1000 births contract sepsis. The mortality rate from sepsis is near 25%.[4] Infected sepsis in an infant can be identified by culturing the blood and spinal fluid and if suspected, intravenous antibiotics are usually started. Lumbar puncture is controversial because in some cases it has found not to be necessary while concurrently, without it estimates of missing up to one third of infants with meningitis is predicted.[15]

Prevention

To reduce neonatal infection, screening of pregnant women for HIV, hepatitis B, and syphilis, is available in the UK.[36]

Treatment with an vaginal antibiotic wash prior to birth does not prevent infection with group B streptococcus bacteria (GBS).[5][37] Treatment with vaginal chlorhexidine prior to birth does not prevent neonatal infections.[38]

Because GBS bacteria can colonize the lower reproductive tract of 30% of women, typically pregnant women are tested for this pathogen from 35 to 37 weeks of pregnancy. Before delivery treatment of the mother with antibiotics reduces the rate of neonatal infection.[5] Prevention of the infection of the baby is done by treating the mother with penicillin. Since the adoption of this prophylatic treatment, infant mortality from GBS infection has decreased by 80%.[4]

Mothers with symptomatic genital herpes and who are treated with antiviral prophylaxis are less prone to have an active, symptomatic case at the time of birth and it may be able to reduce the risk of passing on HSV during birth. Cesarean delivery reduces the risk of infection of the infant.[21]

Breastfeeding has been shown to protect the neonate from some infections. .[39][40][41][42][43] Breast milk protects against necrotizing enterocolitis.[8]

Treatment

Neonatal infection treatment is typically started before the diagnosis of the cause can be confirmed. Neonatal infection can be prophylactically treated with antibiotics.[7] Maternal treatment with antibiotics is primarily used to protect against group B streptococcus.[15]

Women with a history of genital herpes, can be treated with antiviral drugs to prevent symptomatic lesions and viral shedding that could infect the infant at birth. The antiviral medications used include acyclovir, penciclovir, valacyclovir, and famciclovir. Only very small amounts of the drug can be detected in the fetus. There are no increases in drug-related abnormalities in the infant that could be attributed to acyclovir. Long-term effects of antiviral medications have not been evaluated for their effects after growth and development of the child occurs. Neutropenia can be a complication of acyclovir treatment of neonatal HSV infection, but is usually transient.[21] Treatment with immunoglobulin therapy has not been proven to be effective.[44]


Epidemiology

Up to 3.3 million newborns die each year and 23.4% of these die of neonatal infection. About half of the deaths caused by sepsis or pneumonia happen in the first week postpartum. In industrialized countries, prophylactic antibiotic treatment of the mothers identified with group B streptococcus, early identification of sepsis in the newborn, and administration of antibiotics to the newborn has reduced mortality.[5] Neonatal herpes in North America is estimated to be from 5 – 80 per 100,000 live births. HSV has a lower prevalence in mothers outside the United States. In the United Kingdom the incidence is much lower and estimated to be 1.6 per 100,000 live births. Approximately 70% to 80% of infected infants are born to mothers with no reported history of HSV infection.[21]

Regions with low neonatal mortality include Europe, the Western Pacific, and the Americas, which have sepsis rates that account for 9.1% to 15.3% of the total neonatal deaths worldwide. This is in contrast with the 22.5 to 27.2% percentage of total deaths in resource-poor countries such as Nigeria, the Democratic Republic of the Congo, India, Pakistan, and China.[5]

In the UK, the proportions of pregnant women who are newly screened positive for hepatitis B, syphilis, and HIV have remained constant since 2010 at about 0.4%, 0.14% and 0.15%, respectively. Estimated prevalence levels among pregnant women for hepatitis B and HIV, including previous diagnoses, were higher at 0.67% and 0.27%. Pregnant women evaluated as susceptible to rubella due to low antibody levels have increased by over 60%, to about 7.2%. However, this increase is probably due to changes in testing methods and evaluation criteria.[45]

In North America, prior to the 1950s, group A β-hemolytic streptococcus (GAS) was the most common pathogen associated with neonatal sepsis prior to the 1960s. In the past twenty years, the most common pathogen causing sepsis is coagulase-negative staphylococci that exist as biofilms associated with infected central venous or arterial catheters.[7] Infections can be fatal and contribute to long-term morbidity and disability among the infants who survive into childhood.[7] Neonatal sepsis effects 128 cases per 1000 live births. Meningitis can occur in the septic infant.[15] Expectant mothers with HVS have a 75% chance of at least one flare-up during their pregnancy.[21] In limited studies it was found that infants in Africa born to mothers with malaria have a 7% of acquiring congenital malaria.[25]

Early-onset infections

Early onset sepsis can occur in the first week of life. It usually is apparent on the first day after birth. This type of infection is usually acquired before the birth of the infant. Premature rupture of membranes and other obstetrical complications can add to the risk of early-onset sepsis. If the amniotic membrane has been ruptured greater than 18 hours before delivery the infant may be at more risk for this complication. Prematurity, low birth weight, chorioamnionitis, maternal urinary tract infection and/or maternal fever are complications that increase the risk for early-onset sepsis. Early onset sepsis is indicated by serious respiratory symptoms. The infant usually suffers from pneumonia, hypothermia, or shock. The mortality rate is 30 to 50%.[15]

Late onset infections

Infections that occur after the first week of life but before the age of 30 days are considered late onset infections. Obstetrical and maternal complications are not typically the cause of these late onset infections; they are usually acquired by the infant in the hospital neonatal intensive care unit. The widespread use of broad-spectrum antibiotics in the nursery intensive care unit can cause a higher prevalence of invasive antibiotic resistant bacteria.[15] Meconium aspiration syndrome has a mortality rate just over 4%. This accounts for 2% for all neonatal deaths.[14]

Research

The susceptibility to risk of infection and immune deficiencies are active areas of research. Studies regarding the role of viruses in neonatal infections are lacking. Research also continues into the role and protective effect of gut, skin and other human microbiomes and the colonization during the neonatal period.[3][15] The comparison between both resource rich and poor countries makes it difficult to compare the diagnosis success; as industrialized regions are able to confirm the diagnosis and presence of pathogens in the clinical laboratory. Clinical testing may not be available in all settings and clinicians must rely on the signs of infection in the newborn. Research data from Africa and Southeast Asia is scarce.[5]

The result of some research has been the identification of diagnostic tools and procedures that could identify mothers with group B streptococcus infection in resource-poor regions. These procedures would be easy and inexpensive to use. Those mothers who are identified as being infected could then be prophylactly treated prior to the birth of the baby.[5]

Probiotic administration of Lactobacillus species has shown some success.[17]

A GBS vaccine is currently being tested but not currently available. Vaccination is estimated to being able to prevent 4% of GBS infections for preterm births and 60–70% for neonatal GBS infections in the US. The projected benefits of maternal vaccination is the prevention of 899 cases of GBS disease and 35 deaths among infants. The cost savings in the prevention of GBS may be over 43 million dollars. Vaccination may be especially beneficial in low to middle income countries where screening and prophylactic treatment is not possible. Analysts project that GBS vaccination would prevent 30–54% of infant GBS cases. Screening, prophylactic antibiotics and vaccine would prevent 48% of infection.[46]

See also

References

  1. Neil K. Kaneshiro, David Zieve, Isla Ogilvie, A.D.A.M. Editorial team, eds. (December 4, 2013). "Neonate". U.S. National Library of Medicine. Retrieved January 16, 2016.CS1 maint: uses editors parameter (link)
  2. Mary T. Caserta (October 2015). "Overview of Neonatal Infections". Merck Sharp & Dohme Corporation. Retrieved January 16, 2015.
  3. Pryhuber, Gloria S. (2015). "Postnatal Infections and Immunology Affecting Chronic Lung Disease of Prematurity". Clinics in Perinatology. 42 (4): 697–718. doi:10.1016/j.clp.2015.08.002. ISSN 0095-5108. PMC 4660246. PMID 26593074; Access provided by the University of Pittsburgh.
  4. Florin, Todd (2011). Netter's pediatrics. Philadelphia, PA: Elsevier Saunders. ISBN 978-1-4377-1155-4.
  5. Santosham, Mathuram; Chan, Grace J.; Lee, Anne CC; Baqui, Abdullah H.; Tan, Jingwen; Black, Robert E. (2013). "Risk of Early-Onset Neonatal Infection with Maternal Infection or Colonization: A Global Systematic Review and Meta-Analysis". PLoS Medicine. 10 (8): e1001502. doi:10.1371/journal.pmed.1001502. ISSN 1549-1676. PMC 3747995. PMID 23976885.
  6. Ann L Anderson-Berry, Linda L Bellig, Bryan L Ohning (December 31, 2015). "Neonatal Sepsis Clinical Presentation". WebMD LLC. Retrieved January 16, 2016.CS1 maint: uses authors parameter (link)
  7. MacDonald, Mhairi (2015). Avery's neonatology : pathophysiology and management of the newborn. Philadelphia: Wolters Kluwer. ISBN 978-1-4511-9268-1; Access provided by the University of Pittsburgh.
  8. Isaacs, David (2014). Evidence-based neonatal infections. Chichester, West Sussex, UK: Wiley Blackwell. ISBN 978-0-470-65460-6; Access provided by the University of Pittsburgh.
  9. Leveno, Kenneth (2013). Williams manual of pregnancy complications. New York: McGraw-Hill Medical. p. 507. ISBN 9780071765626.
  10. Li, Shunming; Huang, Jingya; Chen, Zhiyao; Guo, Dan; Yao, Zhenjiang; Ye, Xiaohua (2017). "Antibiotic Prevention for Maternal Group B Streptococcal Colonization on Neonatal GBS-Related Adverse Outcomes: A Meta-Analysis". Frontiers in Microbiology. 8: 374. doi:10.3389/fmicb.2017.00374. ISSN 1664-302X. PMC 5355432. PMID 28367139.
  11. Ohlsson, A; Shah, VS (10 June 2014). "Intrapartum antibiotics for known maternal Group B streptococcal colonization". The Cochrane Database of Systematic Reviews (6): CD007467. doi:10.1002/14651858.CD007467.pub4. PMID 24915629.
  12. Bennett, John (2015). Mandell, Douglas, and Bennett's principles and practice of infectious diseases. Philadelphia, PA: Elsevier/Saunders. ISBN 978-1-4557-4801-3; Access provided by the University of Pittsburgh.
  13. "Listeria (Listeriosis)". Centers for Disease Control and Prevention. 22 October 2015. Retrieved 2015-12-23.
  14. Siriwachirachai, Thitiporn; Sangkomkamhang, Ussanee S; Lumbiganon, Pisake; Laopaiboon, Malinee; Siriwachirachai, Thitiporn (2014). "Antibiotics for meconium-stained amniotic fluid in labour for preventing maternal and neonatal infections". Reviews (11): CD007772. doi:10.1002/14651858.CD007772.pub3. PMID 25374369; Access provided by the University of Pittsburgh
  15. Fanaroff, Avroy (2013). Klaus & Fanaroff's care of the high-risk neonate. Philadelphia, PA: Elsevier/Saunders. ISBN 978-1-4160-4001-9; Access provided by the University of Pittsburgh.
  16. "Tetanus and neonatal tetanus (NT)". WHO Western Pacific Region. Archived from the original on 2014-05-03.
  17. Baucells, B.J.; Mercadal Hally, M.; Álvarez Sánchez, A.T.; Figueras Aloy, J. (2015). "Asociaciones de probióticos para la prevención de la enterocolitis necrosante y la reducción de la sepsis tardía y la mortalidad neonatal en recién nacidos pretérmino de menos de 1.500g: una revisión sistemática". Anales de Pediatría. 85 (5): 247–255. doi:10.1016/j.anpedi.2015.07.038. ISSN 1695-4033. PMID 26611880.
  18. Polin, Richard (2014). Fetal and neonatal secrets. Philadelphia: Elsevier Saunders. ISBN 978-0-323-09139-8.
  19. Health, Australian Government Department of. "Human Immunodeficiency virus (HIV)". www.health.gov.au. Retrieved 2017-12-16.
  20. Ageing, Australian Government Department of Health and. "Australian Paediatric Surveillance Unit annual report, 2010". www.health.gov.au. Retrieved 2017-12-16.
  21. Hollier, Lisa M; Wendel, George D; Hollier, Lisa M (2008). "Third trimester antiviral prophylaxis for preventing maternal genital herpes simplex virus (HSV) recurrences and neonatal infection". Reviews (1): CD004946. doi:10.1002/14651858.CD004946.pub2. PMID 18254066; Access provided by the University of Pittsburgh.
  22. Leonardo Aguiar. "Ministério da Saúde confirma relação entre vírus Zika e microcefalia" [Ministry of Health confirms relationship between Zika virus and microcephaly]. Portal da Saúde – Ministério da Saúde. Archived from the original on 2016-01-29. Retrieved 2016-02-01.
  23. Oliveira Melo, A. S.; Malinger, G.; Ximenes, R.; Szejnfeld, P. O.; Alves Sampaio, S.; Bispo de Filippis, A. M. (1 January 2016). "Zika virus intrauterine infection causes fetal brain abnormality and microcephaly: tip of the iceberg?". Ultrasound in Obstetrics & Gynecology. 47 (1): 6–7. doi:10.1002/uog.15831. ISSN 1469-0705. PMID 26731034.
  24. "Epidemiological update: Outbreaks of Zika virus and complications potentially linked to the Zika virus infection". European Centre for Disease Prevention and Control. Retrieved 18 January 2016.
  25. Martin, Richard (2015). Fanaroff and Martin's neonatal-perinatal medicine : diseases of the fetus and infant. Philadelphia, PA: Elsevier/Saunders. ISBN 978-1-4557-5617-9; Access provided by the University of Pittsburgh.
  26. Cloherty, John (2012). Manual of neonatal care. Philadelphia: Wolters Kluwer Health/Lippincott Williams & Wilkins. ISBN 978-1-60831-777-6; Access provided by the University of Pittsburgh.
  27. Torgerson, Paul R; Mastroiacovo, Pierpaolo (2013). "The global burden of congenital toxoplasmosis: a systematic review" (PDF). Bulletin of the World Health Organization. 91 (7): 501–508. doi:10.2471/BLT.12.111732. ISSN 0042-9686. PMC 3699792. PMID 23825877. Retrieved 16 January 2016.
  28. Ungerer, Regina LS; Lincetto, Ornella; McGuire, William; Saloojee, Haroon H; Gülmezoglu, A Metin; Ungerer, Regina LS (2004). "Prophylactic versus selective antibiotics for term newborn infants of mothers with risk factors for neonatal infection". Reviews (4): CD003957. doi:10.1002/14651858.CD003957.pub2. PMID 15495071.
  29. Sinha, Sunil (2012). Essential neonatal medicine. Chichester, West Sussex: John Wiley & Sons. ISBN 978-0-470-67040-8; Access provided by the University of Pittsburgh.
  30. Kumar, Ritu; Bronze, Michael Stuart (2015). "Pelvic Inflammatory Disease Empiric Therapy". Medscape. Retrieved 23 January 2019.
  31. Zakher, Bernadette; Cantor MD, Amy G.; Daeges, Monica; Nelson MD, Heidi (December 16, 2014). "Review: Screening for Gonorrhea and Chlamydia: A Systematic Review for the U.S. Prevententive Services Task Force". Annals of Internal Medicine. 161 (12): 884–894. CiteSeerX 10.1.1.691.6232. doi:10.7326/M14-1022. PMID 25244000.
  32. Kenner, Carole (2014). Comprehensive neonatal nursing care (5th ed.). New York, NY: Springer Publishing Company, LLC. ISBN 978-0-8261-0975-0. Access provided by the University of Pittsburgh.
  33. van de Laar, Rafli; van der Ham, David P.; Oei, S. Guid; Willekes, Christine; Weiner, Carl P.; Mol, Ben W.J. (2009). "Accuracy of C-reactive protein determination in predicting chorioamnionitis and neonatal infection in pregnant women with premature rupture of membranes: A systematic review". European Journal of Obstetrics & Gynecology and Reproductive Biology. 147 (2): 124–129. doi:10.1016/j.ejogrb.2009.09.017. ISSN 0301-2115. PMID 19819609.
  34. "Grunting in Neonates - General Practice Notebook". www.gpnotebook.co.uk. (subscription required)
  35. Mayhall, C (2012). Hospital epidemiology and infection control. Philadelphia: Wolters Kluwer Health/Lippincott Williams & Wilkins. ISBN 978-1-60831-300-6; Access provided by the University of Pittsburgh.
  36. "Infectious diseases in pregnancy screening: programme overview; Detailed guidance". GOV.UK. 1 January 2015. Retrieved 2016-01-07.
  37. Ohlsson, Arne; Shah, Vibhuti S; Stade, Brenda C; Ohlsson, Arne (2014). "Vaginal chlorhexidine during labour to prevent early-onset neonatal group B streptococcal infection". Reviews. 12 (12): CD003520. doi:10.1002/14651858.CD003520.pub3. PMID 25504106.
  38. Lumbiganon, Pisake; Thinkhamrop, Jadsada; Thinkhamrop, Bandit; Tolosa, Jorge E. (2014-09-14). "Vaginal chlorhexidine during labour for preventing maternal and neonatal infections (excluding Group B Streptococcal and HIV)". The Cochrane Database of Systematic Reviews (9): CD004070. doi:10.1002/14651858.CD004070.pub3. ISSN 1469-493X. PMID 25218725.
  39. Kunz C, Rodriguez-Palmero M, Koletzko B, Jensen R (June 1999). "Nutritional and biochemical properties of human milk, Part I: General aspects, proteins, and carbohydrates". Clinics in Perinatology. 26 (2): 307–33. PMID 10394490.
  40. Rodriguez-Palmero M, Koletzko B, Kunz C, Jensen R (June 1999). "Nutritional and biochemical properties of human milk: II. Lipids, micronutrients, and bioactive factors". Clinics in Perinatology. 26 (2): 335–59. PMID 10394491.
  41. Hanson LA, Söderström T (1981). "Human milk: Defense against infection". Progress in Clinical and Biological Research. 61: 147–59. PMID 6798576.
  42. Van de Perre P (July 2003). "Transfer of antibody via mother's milk". Vaccine. 21 (24): 3374–6. doi:10.1016/S0264-410X(03)00336-0. PMID 12850343.
  43. Jackson KM, Nazar AM (April 2006). "Breastfeeding, the immune response, and long-term health". The Journal of the American Osteopathic Association. 106 (4): 203–7. PMID 16627775.
  44. Ohlsson, Arne; Lacy, Janet B; Ohlsson, Arne (2015). "Intravenous immunoglobulin for suspected or proven infection in neonates". Reviews (3): CD001239. doi:10.1002/14651858.CD001239.pub5. PMID 25815707.
  45. Infection reports; HIV – STIs Antenatal screening for infectious diseases in England: summary report for 2014 (PDF). Infection reports Volume 9 Number 43 Published on: 4 December 2015 HIV – STIs Antenatal screening for infectious diseases in England: summary report for 2014 (Report). 9. Public Health England. 4 December 2015. Retrieved 8 January 2016.
  46. Cortese, Francesca; Scicchitano, Pietro; Gesualdo, Michele; Filaninno, Antonella; De Giorgi, Elsa; Schettini, Federico; Laforgia, Nicola; Ciccone, Marco Matteo (2015). "Early and Late Infections in Newborns: Where Do We Stand? A Review". Pediatrics & Neonatology. 57 (4): 265–273. doi:10.1016/j.pedneo.2015.09.007. ISSN 1875-9572. PMID 26750406.

Further reading

Classification
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.