Evaluation of Placental and Fetal Tissue Specimens for Zika Virus Infection — 50 States and District of Columbia, January–December, 2016
Weekly / June 23, 2017 / 66(24);636–643
Sarah Reagan-Steiner, MD1; Regina Simeone, MPH2; Elizabeth Simon, MPH2; Julu Bhatnagar, PhD1; Titilope Oduyebo, MD3; Rebecca Free, MD4; Amy M. Denison, PhD1; Demi B. Rabeneck, MS1; Sascha Ellington, MSPH2; Emily Petersen, MD2; Joy Gary, DVM1; Gillian Hale, MD1; M. Kelly Keating, DVM1; Roosecelis B. Martines, MD1; Atis Muehlenbachs, MD1; Jana Ritter, DVM1; Ellen Lee, MD5; Alexander Davidson, MPH5; Erin Conners, PhD5; Sarah Scotland, MPH6; Kayleigh Sandhu, MPH6; Andrea Bingham, PhD7; Elizabeth Kassens7; Lou Smith, MD8; Kirsten St. George, MD8; Nina Ahmad, MD8; Mary Tanner, MD9,10; Suzanne Beavers, MD11; Brooke Miers, MS1,12; Kelley VanMaldeghem, MPH2; Sumaiya Khan, MPH2; Ingrid Rabe, MBChB13; Carolyn Gould, MD13; Dana Meaney-Delman, MD14; Margaret A. Honein, PhD2; Wun-Ju Shieh, MD1; Denise J. Jamieson, MD3; Marc Fischer, MD13; Sherif R. Zaki, MD1; U.S. Zika Pregnancy Registry Collaboration; Zika Virus Response Epidemiology and Surveillance Task Force Pathology Team (View author affiliations)
View suggested citationSummary
What is already known about this topic?
Zika virus infection during pregnancy can cause microcephaly and other brain abnormalities. Diagnosis of Zika virus infection is challenging because of serologic cross-reactivity with other related flaviviruses and limited duration of viremia. Zika virus RNA can be detected in placental and fetal tissues, which can provide an opportunity to diagnose maternal Zika virus infection and can be considered when maternal serologic testing is not definitive or is negative outside the optimal testing window.
What is added by this report?
In the 50 U.S. states and District of Columbia, placental testing provided a confirmed diagnosis of recent maternal Zika virus infection for 10% of live births with possible maternal exposure to Zika virus that lacked definitive evidence of a maternal or congenital Zika virus infection. This included pregnancies with clinical laboratory evidence of recent unspecified maternal flavivirus infection, and those with negative maternal Zika virus IgM, where possible maternal exposure occurred >12 weeks before serum collection.
What are the implications for public health practice?
Testing of placental tissues from live births provided definitive evidence of maternal Zika virus infection. Although the proportion of live births for which placental tissue was RT-PCR–positive for Zika virus was relatively low, testing of placental tissues from live births can continue to be considered when results of maternal Zika virus testing are not definitive or testing is not performed within the optimal time. Ensuring appropriate Zika virus testing and clinical follow-up of infants, according to published CDC guidance is critical in order to identify congenital Zika virus infection.
Zika virus infection during pregnancy can cause congenital microcephaly and brain abnormalities (1), and detection of Zika virus RNA in clinical and tissue specimens can provide definitive laboratory evidence of recent Zika virus infection. Whereas duration of viremia is typically short, prolonged detection of Zika virus RNA in placental, fetal, and neonatal brain tissue has been reported and can provide key diagnostic information by confirming recent Zika virus infection (2). In accordance with recent guidance (3,4), CDC provides Zika virus testing of placental and fetal tissues in clinical situations where this information could add diagnostic value. This report describes the evaluation of formalin-fixed paraffin-embedded (FFPE) tissue specimens tested for Zika virus infection in 2016 and the contribution of this testing to the public health response. Among 546 live births with possible maternal Zika virus exposure, for which placental tissues were submitted by the 50 states and District of Columbia (DC), 60 (11%) were positive by Zika virus reverse transcription–polymerase chain reaction (RT-PCR). Among 81 pregnancy losses for which placental and/or fetal tissues were submitted, 18 (22%) were positive by Zika virus RT-PCR. Zika virus RT-PCR was positive on placental tissues from 38/363 (10%) live births with maternal serologic evidence of recent unspecified flavivirus infection and from 9/86 (10%) with negative maternal Zika virus immunoglobulin M (IgM) where possible maternal exposure occurred >12 weeks before serum collection. These results demonstrate that Zika virus RT-PCR testing of tissue specimens can provide a confirmed diagnosis of recent maternal Zika virus infection.
Zika virus RT-PCR and, in selected cases, immunohistochemical (IHC) testing, were performed at CDC’s Infectious Diseases Pathology Branch (IDPB) on FFPE tissue specimens submitted from completed pregnancies (i.e., live births and pregnancy losses of any gestational age) with possible maternal Zika virus exposure.* Completed pregnancies in this report include those with evidence of possible recent Zika virus infection (from maternal, fetal, or infant specimens) and those that ultimately demonstrated no laboratory evidence of possible Zika virus infection. To determine the added diagnostic value of Zika virus tissue RT-PCR testing, results from nontissue clinical samples (i.e., serum and/or urine) reported by the submitting health department or CDC’s Arboviral Diseases Branch, were categorized by maternal test results (Table 1) (5) and infant test results.† Tissue RT-PCR results are also summarized by maternal symptom status and trimester of infection or possible exposure.§ A subset of pregnancies that were also reported to the U.S. Zika Pregnancy Registry (USZPR)¶ were systematically reviewed to determine the presence of possible Zika virus–associated birth defects. Thus, the analysis of tissue RT-PCR results by the presence of possible birth defects was limited to these pregnancies. Infants and pregnancy losses with possible Zika virus–associated birth defects included pregnancies completed by December 25, 2016 that were reported to the USZPR and met the CDC surveillance case definition for possible Zika virus–associated birth defects as of May 18, 2017.** Completed pregnancies were classified as “tissue Zika virus RT-PCR–positive” if at least one placental (e.g., placental disc, umbilical cord, or fetal membranes) specimen or fetal/infant tissue specimen was positive by conventional Zika virus RT-PCR and confirmed by sequencing of PCR products (2). A positive Zika virus RT-PCR test result on placental tissues is evidence of maternal Zika virus infection. This report includes cases reported previously (2,6–8).
During 2016, tissue specimens from 627 completed pregnancies with possible maternal Zika virus exposure from the 50 states and DC were submitted to CDC and were tested by Zika virus tissue RT-PCR. These specimens included placental tissues from 546 live births and placental and/or fetal tissues from 81 pregnancy losses; IHC testing for Zika virus was also performed on specimens from 91 live births and pregnancy losses (15%), criteria for which are specified below. Overall, 78/627 (12%) had one or more placental or fetal tissue specimen that was positive for Zika virus by RT-PCR. Among the 91 completed pregnancies with tissue specimens tested by IHC, seven (8%) demonstrated IHC evidence of Zika virus infection (six from first trimester pregnancy losses and one from a second trimester pregnancy loss). All seven IHC-positive pregnancy losses were also tissue RT-PCR–positive. Because none of the placental specimens tested by IHC from third trimester pregnancy losses (n = 4) or live births (n = 47) was IHC-positive, beginning in March 2016, IHC testing of these specimen types was no longer routinely performed.
Among 546 live births, placental tissues from 60 (11%) were RT-PCR positive for Zika virus, including 38/363 (10%) from pregnancies with recent unspecified maternal flavivirus infection and 9/86 (10%) with negative maternal Zika virus IgM, where possible maternal exposure occurred >12 weeks before serum collection (after which time maternal Zika virus IgM antibodies might have waned) (5) (Table 2). Zika virus RT-PCR was negative on placental tissues from 34/47 (72%) live births with confirmed recent maternal Zika virus infection, and from all three live births in which the infant had confirmed congenital Zika virus infection based on infant testing. Among live births with no evidence of maternal Zika virus infection (n = 14) or no maternal clinical specimens tested (n = 34), none was tissue RT-PCR–positive. Overall, Zika virus RT-PCR was positive on placental tissues from 47/482 (10%) live births without a confirmed diagnosis by Zika virus testing on maternal or infant clinical specimens, confirming a diagnosis of recent maternal Zika virus infection (Figure).
Placental or fetal tissues from 18 (22%) of the 81 pregnancy losses tested positive for Zika virus by RT-PCR, including 4/13 (31%) with recent unspecified maternal flavivirus infection, 2/18 (11%) with negative maternal Zika virus IgM, where possible maternal exposure occurred >12 weeks before serum collection, and 1/16 (6%) with no maternal clinical samples tested (Table 2). Among 14 pregnancy losses with no evidence of maternal Zika virus infection, no placental or fetal tissues tested RT-PCR–positive. Ten of 28 (36%) first trimester pregnancy losses and 5/17 (29%) third trimester pregnancy losses were tissue RT-PCR–positive, compared with only 3/35 (9%) second trimester losses (Table 2). However, 13/28 (46%) first trimester pregnancy losses had evidence of confirmed recent maternal Zika virus infection from clinical specimens, compared with 5/35 (14%) of second trimester and 1/17 (6%) third trimester pregnancy losses.
Among the 627 completed pregnancies included in this report, 449 (72%) were included in the USZPR (Table 2). Thirty live births were reported to have possible Zika virus–associated birth defects. Sixteen of these (53%) were Zika virus RT-PCR–positive on placental tissues; however, a positive placental tissue RT-PCR cannot distinguish between maternal and congenital infection. Ten of these 16 had recent unspecified maternal flavivirus infection, and six had negative maternal Zika virus IgM, where possible maternal exposure occurred >12 weeks before serum collection. Among nine live births with negative maternal Zika IgM, where possible maternal exposure occurred >12 weeks before serum collection, and placental tissue RT-PCR was positive, six had possible Zika virus–associated birth defects.
Discussion
Among live births, placental tissue RT-PCR provided confirmation of recent maternal Zika virus infection for 47 (10%) women who otherwise did not have a definitive diagnosis. Given the complexity of Zika virus testing and interpretation, tissue specimen analysis provides another opportunity to confirm maternal Zika virus infection. A definitive maternal diagnosis of Zika virus infection provides valuable information to guide the evaluation and management of infants with possible congenital exposure.
Placental tissue RT-PCR testing was positive in a relatively low proportion of live births with recent unspecified maternal flavivirus infection (10%) or negative maternal Zika virus IgM on serum collected >12 weeks after possible exposure (10%). Placental testing might provide additional diagnostic information and can continue to be considered in these scenarios (https://www.cdc.gov/zika/pdfs/placental-testing-guidance.pdf), depending on the availability of public health resources. The yield of Zika virus testing of placental tissues should continue to be reassessed as additional data are collected.
Placental tissues have both maternal and fetal components, and Zika RT-PCR cannot discriminate between viral RNA from maternal and fetal areas (9). Although placental testing cannot confirm or exclude congenital Zika virus infection, infants might be more likely to receive appropriate clinical evaluation when a mother has confirmed recent Zika virus infection. Negative placental RT-PCR results do not rule out maternal or congenital Zika virus infection; evaluation of pregnant women and infants for Zika virus in accordance with CDC guidance is essential to direct appropriate infant clinical management and follow-up (3,4). Infant Zika virus testing and neuroimaging should not be delayed while results of placental testing are pending.
Among live births with possible Zika virus–associated birth defects reported to the USZPR and included in this analysis, 53% were Zika virus RT-PCR–positive on placental tissues. The implications of a positive placental Zika virus RT-PCR for infant clinical outcomes are currently unknown. However, further study could explore the relationship between the presence of Zika virus RNA in placental specimens, fetal infection, and development of possible Zika virus–associated birth defects.
In this report, Zika virus IHC was only positive on fetal and placental tissues from first and second trimester pregnancy losses. Zika virus IHC-positivity in brain tissues from infant deaths has been reported in other studies (9,10). Although all IHC-positive cases were also RT-PCR–positive, IHC can provide valuable insight into viral localization and pathogenesis in pregnancy losses and infant deaths.
The findings in this report are subject to at least five limitations. First, a negative Zika virus RT-PCR on placental tissues does not exclude maternal Zika virus infection. Factors that could lead to false-negative results include levels of viral RNA below the limit of assay detection, variability in tissue sampling, and degradation of viral RNA because of insufficient tissue fixation or prolonged formalin-fixation.†† Second, pregnancy outcomes in this analysis might not be representative of all pregnancies with possible Zika virus exposure, maternal Zika virus infection, or Zika virus–associated birth defects in the United States. Pregnancies ending in a loss or with fetuses or infants with birth defects might be more likely to have tissue specimens submitted, particularly among pregnancies with negative maternal Zika virus IgM >12 weeks after possible exposure. Third, possible testing bias limits the ability to compare placental test results by results of infant clinical laboratory testing, because infants with possible Zika virus–associated birth defects might be more likely to have Zika virus testing performed. Fourth, the approach to testing of placental and fetal tissues changed over time, which might have resulted in variability in testing bias over the reporting period. Changes included routinely testing tissue specimens for completed pregnancies where maternal Zika virus IgM was negative >12 weeks after possible exposure (beginning in August 2016) (3,4), and focusing testing of placental specimens from live births on those without a confirmed recent maternal Zika virus infection diagnosis (https://www.cdc.gov/zika/pdfs/placental-testing-guidance.pdf). Finally, clinical, epidemiologic, and laboratory information reflects data reported to USZPR and CDC’s IDPB as of the date of this report, and might be incomplete.
These findings describe the contributions of testing placental and fetal tissue specimens for Zika virus infection to the diagnosis of maternal infection. Although the proportion of live births with placental tissues positive for Zika virus by RT-PCR was low, tissue analysis can be valuable when maternal serologic testing either cannot differentiate between Zika virus and other related flaviviruses, or has been conducted >12 weeks after possible maternal exposure, and infant Zika virus testing is not definitive, negative, or not performed. Tissue analysis provides another opportunity to confirm maternal Zika virus infection, which can be important to both families and health care providers. However, because a positive Zika virus RT-PCR on placental tissues cannot distinguish between maternal and congenital infection, following current CDC guidance for clinical diagnostic testing and management of pregnant women with possible Zika virus exposure and infants with possible congenital Zika virus infection continues to be important (3,4).
Acknowledgments
Alabama Zika Response Team, Alabama Department of Public Health; Alaska Division of Public Health; American Samoa Department of Health; Delaware Division of Public Health; Division of Epidemiology-Disease Surveillance and Investigation, District of Columbia Department of Health; Iowa Department of Public Health; Kansas Department of Health and Environment; Kentucky Department for Public Health Zika Pregnancy Workgroup, Kentucky Department for Public Health; Michigan Department of Health and Human Services Zika Pregnancy Registry Workgroup; Office of Public Health Informatics and Epidemiology, Nevada Division of Public and Behavioral Health; Ohio Department of Health Zoonotic Disease Program; Oklahoma State Department of Health Acute Disease Service; Oregon Public Health Division Acute and Communicable Disease Program; Ministry of Health, Republic of the Marshall Islands; United States Virgin Islands Department of Health; Virginia Department of Health’s Office of Epidemiology and the Division of Surveillance and Investigation; Virginia Department of Health’s 35 Local Health Districts and their respective Epidemiologists and Public Health Nurses; Virginia Division of Consolidated Laboratory Services; West Virginia Bureau of Public Health, Office of Maternal, Child and Family Health, Office of Epidemiology and Prevention Services; Wisconsin Division of Public Health.
U.S. Zika Pregnancy Registry Collaboration
Melissa Kretschmer, MA, Maricopa County Department of Public Health, Arizona Department of Health Services; Kara Tarter, MPH, Arizona Department of Health Services; Hayley Yaglom, MS, MPH, Arizona Department of Health Services; Shoruq Alhajmohammad, California Department of Public Health; Dildeep Chhabra, MBBS, California Department of Public Health; Wendy Jilek, MPH, California Department of Public Health; Meghana Madala, California Department of Public Health; Sharon Messenger, PhD, California Department of Public Health; Charsey Cole Porse, PhD, California Department of Public Health; Maria Salas, MPH, California Department of Public Health; Diana Singh, California Department of Public Health; Sarah Skallet, MPH, California Department of Public Health; Similoluwa Sowunmi, MPH, California Department of Public Health; Natalie S. Marzec, MD, Colorado Department of Public Health and Environment; Karin Davis, Connecticut Department of Public Health; Brenda Esponda-Morrison, Connecticut Department of Public Health; M. Zachariah Fraser, Connecticut Department of Public Health; Colleen Ann O’Connor, MPH, Connecticut Department of Public Health; Wendy M. Chung, MD, Dallas County Health and Human Services; Folasuyi Richardson, MPH, Dallas County Health and Human Services; Meredith E. Stocks, MPH, Dallas County Health and Human Services; Amanda Marie Bundek, Delaware Division of Public Health; Jennifer L. Zambri, MBA, Delaware Division of Public Health; Ashley Allen, Florida Department of Health, Bureau of Public Health Laboratories-Miami; Marie Ketty Etienne, MPH, Florida Department of Health in Miami-Dade County; Jennifer Jackson, MPH, Florida Department of Health in Orange County; Vanessa Landis, MPH, Florida Department of Health; Teresa Logue, MPH, Florida Department of Health in Miami-Dade County; Nicole Muse, MPH, Florida Department of Health in Miami-Dade County; Juliana Prieto, MPH, Florida Department of Health; Mercedes Rojas, Florida Department of Health in Miami-Dade County; Amanda Feldpausch, MPH, Georgia Department of Public Health; Teri Graham, MPH, Georgia Department of Public Health; Sylvia Mann, MS, Hawaii Department of Health; Sarah Y. Park, MD, Hawaii Department of Health; Debbie Freeman, Illinois Department of Public Health; Emily J. Potts, MPH, Indiana State Department of Health; Taryn Stevens, MPH, Indiana State Department of Health; Sean Simonson, MPH, Louisiana Department of Health; Julius L. Tonzel, MPH, Louisiana Department of Health; Shari Davis, MPH, Maine Department of Health and Human Services; Sara Robinson, MPH, Maine Department of Health and Human Services; Judie K. Hyun, MHS, Maryland Department of Health and Mental Hygiene; Erin Maureen Jenkins, MPH, Maryland Department of Health and Mental Hygiene; Catherine Brown, DVM, Massachusetts Department of Public Health; Susan Soliva, MPH, Massachusetts Department of Public Health; Elizabeth Schiffman, MPH, MA, Minnesota Department of Health; Paul Byers, MD, Mississippi State Department of Health; Sheryl Hand, Mississippi State Department of Health; Christine L. Mulgrew, PhD, Montana Department of Health and Human Services; Jeff Hamik, MS, Division of Public Health, Nebraska Department of Health and Human Services; Samir Koirala, MSc, Division of Public Health, Nebraska Department of Health and Human Services; Elizabeth Ludwig, MD, Division of Public Health, Nebraska Department of Health and Human Services; Carolyn R. Fredette, MPH, New Hampshire Department of Health and Human Services; Abigail A. Mathewson, DVM, New Hampshire Department of Health and Human Services; Kristin Garafalo, MPH, New Jersey Department of Health; Karen Worthington, MS, New Jersey Department of Health; Abubakar Ropri, MPH, New Mexico Department of Health; Danielle Bloch, MPH, New York City Department of Health & Mental Hygiene; Sandhya Clark, MPH, New York City Department of Health & Mental Hygiene; Hannah Cooper, MBChB, New York City Department of Health & Mental Hygiene; Annie D. Fine, MD, New York City Department of Health & Mental Hygiene; Gili Hrusa, MPH, New York City Department of Health & Mental Hygiene; Martha Iwamoto, MD, New York City Department of Health & Mental Hygiene; Hannah Kubinson, MPH, New York City Department of Health & Mental Hygiene; Christopher T. Lee, MD, New York City Department of Health & Mental Hygiene; Sally Slavinski, DVM, New York City Department of Health & Mental Hygiene; Eliza Wilson, New York City Department of Health & Mental Hygiene; Ann Winters, MD, New York City Department of Health & Mental Hygiene; David Yi Yang, New York City Department of Health & Mental Hygiene; Julius N. Ade, MD, New York State Department of Health; Zahra Alaali, MPH, New York State Department of Health; Kimberly Alvarez, MPH, New York State Department of Health; P. Bryon Backenson, MS, New York State Department of Health; Debra Blog, MD, New York State Department of Health; Amy Dean, PhD, Wadsworth Center, New York State Department of Health; Elizabeth Dufort, MD, New York State Department of Health; Andrea Marias Furuya, PhD, Wadsworth Center, New York State Department of Health; Meghan Fuschino, MS, Wadsworth Center, New York State Department of Health; Rene Hull, Wadsworth Center, New York State Department of Health; Matthew Kleabonas, Wadsworth Center, New York State Department of Health; Karen Kulas, Wadsworth Center, New York State Department of Health; Philip Kurpiel, PhD, New York State Department of Health; Lou Ann Lance, MSN, New York State Department of Health; Emaly Leak, MS, Wadsworth Center, New York State Department of Health; Ronald J. Limberger, PhD, Wadsworth Center, New York State Department of Health; Stephanie Ostrowski, PhD, New York State Department of Health; MaryJo Polfleit, New York State Department of Health; Amy Robbins, MPH, New York State Department of Health, Bureau of Communicable Disease Control; Jemma V. Rowlands, MPH, New York State Department of Health; Inderbir Sohi, MSPH, New York State Department of Health, CDC; Jamie N. Sommer, MS, New York State Department of Health, Bureau of Communicable Disease Control; Jennifer White, MPH, New York State Department of Health; Dorothy Wiley, New York State Department of Health; Li Zeng, Wadsworth Center, New York State Department of Health; Ronna L. Chan, PhD, North Carolina Department of Health and Human Services, Division of Public Health; Jennifer MacFarquhar, MPH, North Carolina Department of Health and Human Services, Division of Public Health; Laura Cronquist, North Dakota Department of Health; Leah Lind, MPH, Pennsylvania Department of Health; Kumar Nalluswami, MD, Pennsylvania Department of Health; Dana Perella, MPH, Philadelphia Department of Public Health; Diane S. Brady, MS, Rhode Island Department of Health; Michael Gosciminski, MPH, Rhode Island Department of Health; Patricia McAuley, MSN, Rhode Island Department of Health; Bridget E. Teevan, MPH, Rhode Island Department of Health; Daniel Drociuk, South Carolina Department of Health and Environmental Control; Vinita Leedom, MPH, South Carolina Department of Health and Environmental Control; Brian Witrick, MPH, South Carolina Department of Health and Environmental Control; Jan Bollock, South Dakota Department of Health; Lon Kightlinger, PhD, South Dakota Department of Health; Marie Bottomley Hartel, MPH, Tennessee Department of Health; Loraine Swanson Lucinski, MPH, Tennessee Department of Health; Morgan McDonald, MD, Tennessee Department of Health; Angela M. Miller, PhD, Tennessee Department of Health; Tori Armand Ponson, MPH, Tennessee Department of Health; Laura Price, Tennessee Department of Health; Kelly Broussard, MPH, Texas Department of State Health Services; Amy E. Nance, MPH, Utah Birth Defect Network, Utah Department of Health; Dallin Peterson, MPH, Utah Department of Health; Brennan Martin, MPH, Vermont Department of Health; Shea Browne, MS, Virginia Department of Health; LaToya A. Griffin-Thomas, PhD, Virginia Division of Consolidated Laboratory Services; Jennifer O. Macdonald, MPH, Virginia Department of Health; Jillian Neary, MPH, Washington State Department of Health; Hanna Oltean, MPH, Washington State Department of Health; Alys Adamski, PhD, CDC; Madelyn Baez-Santiago, PhD, CDC; Brigid C. Bollweg, MPH, CDC; Janet D. Cragan, MD, CDC; Yokabed Ermias, MPH, CDC; Lindsey B. C. Estetter, MS, CDC; Shannon Fleck-Derderian, MPH, CDC, ORISE; Cynthia S. Goldsmith, MGS, CDC; Matthew R. Groenewold, PhD, CDC; Heather Hayes, CDC; Irogue Igbinosa, MD, CDC; Tiffany Gayle Jenkinson, CDC; Abbey M. Jones, MPH, CDC; Amanda Lewis, CDC; Cynthia A. Moore, MD, PhD, CDC; Kimberly B. Newsome, MPH, CDC; Vaunita Parihar, CDC; Mitesh M. Patel, CDC; Anna Paulino, CDC; Sonja A. Rasmussen, MD, CDC; Meghan Raycraft, MPH, CDC; Megan R Reynolds, MPH, CDC; Dominique C. Rollin, MD, CDC; Jeanine H. Sanders, CDC; Carrie Shapiro-Mendoza, PhD, CDC; Luciana Silva-Flannery, PhD, CDC; Pamela Spivey, CDC; Alphonse K. Tshiwala, MPA, CDC; Tonya R. Williams, PhD, CDC.
Zika Virus Response Epidemiology and Surveillance Task Force Pathology Team
William A. Bower, MD, CDC; Elizabeth Davlantes, MD, CDC, Epidemic Intelligence Service (EIS); Terra R. Forward, DO, CDC; Rena Fukunaga, PhD, CDC, EIS; Jonas Hines, MD, CDC; Shaohua Sean Hu, MD, DrPH, CDC; Jessica Leung, MPH, CDC; Lillianne Lewis, MD, CDC; Stacey Martin, MSc, CDC; Lucy McNamara, PhD, CDC; John D. Omura, MD, CDC; Candice L. Robinson, MD, CDC; Kristine Schmit, MD, CDC; Julie L. Self, PhD, CDC, EIS; Minesh Shah, MD, CDC; Anne Straily, DVM, CDC, EIS; Elizabeth A. Van Dyne, MD, CDC; Milan Vu, CDC; Charnetta Williams, MD, CDC, EIS.
Conflict of Interest
Kirsten St. George reports grants from Akonni Biosystems Inc., nonfinancial support from ThermoFisher, and a royalty generating collaborative agreement with Zeptometrix outside the submitted work. No other conflicts of interest were reported.
Corresponding author: Sarah Reagan-Steiner, [email protected], 404-639-2811.
1Division of High-Consequence Pathogens and Pathology, National Center for Emerging and Zoonotic Infectious Diseases, CDC; 2Division of Congenital and Developmental Disorders, National Center on Birth Defects and Developmental Disabilities, CDC; 3Division of Reproductive Health, National Center for Chronic Disease Prevention and Health Promotion, CDC; 4Division of Emergency Operations, Office of Public Health Preparedness and Response, CDC; 5New York City Department of Health & Mental Hygiene; 6Massachusetts Department of Public Health; 7Florida Department of Health, 8New York State Department of Health; 9Epidemic Intelligence Service, CDC; 10Division of HIV/AIDS Prevention, National Center for HIV/AIDS, Viral Hepatitis, STD, and TB Prevention, CDC; 11Division of Environmental Hazards and Health Effects, National Center for Environmental Health, CDC; 12Oak Ridge Institute for Science and Education; 13Division of Vector-Borne Infectious Diseases, National Center for Emerging and Zoonotic Infectious Diseases, CDC; 14Office of the Director, National Center for Emerging and Zoonotic Infectious Diseases, CDC.
* Possible exposure to Zika virus includes: 1) travel to or residence in an area at risk for Zika virus transmission and with a CDC travel notice, or 2) condomless sexual exposure to a partner who traveled to or lived in an area with risk of Zika virus transmission and a CDC travel notice during pregnancy or the periconceptional period (https://www.cdc.gov/zika/geo/index.html).
† Infant laboratory evidence categories apply to results of testing on infant or fetal clinical specimens (e.g., serum, cord blood, urine, cerebrospinal fluid, amniotic fluid), however if infant PRNT titers were not available, maternal serum PRNT titers were used. Categories include the following: confirmed congenital Zika virus infection = positive by Zika virus RT-PCR, Zika virus IgM positive and Zika virus PRNT titer ≥10; probable congenital Zika virus infection = Zika virus IgM-positive, no PRNT titers reported, or Zika and dengue virus PRNT titers ≥10; negative infant Zika virus test results = neither Zika virus RT-PCR nor Zika virus IgM positive results; no infant specimen test results reported = testing could be not performed, not reported, or pending. Only includes results of Zika virus clinical laboratory testing conducted in the United States and U.S. territories (https://wwwn.cdc.gov/nndss/conditions/zika/case-definition/2016/06/).
§ Trimester of infection or possible exposure is based on symptom onset date for symptomatic pregnant women or trimester(s) of suspected vectorborne or sexual exposure for asymptomatic pregnant women. Periconceptional exposure only is defined as infection or possible exposure during the 8 weeks before conception (6 weeks before and 2 weeks after the first day of the last menstrual period).
¶ U.S. Zika Pregnancy Registry inclusion criteria = pregnant women with laboratory evidence of Zika virus infection (positive or equivocal test results, regardless of whether they have had symptoms) and periconceptionally, prenatally, or perinatally exposed infants born to these women, and infants with laboratory evidence of congenital Zika virus infection (positive or equivocal test results, regardless of whether they have symptoms) and their mothers (https://www.cdc.gov/zika/reporting/registry.html).
** Birth defects include those that met the USZPR surveillance case definition for birth defects potentially associated with Zika virus infection during pregnancy as of May 18, 2017. These birth defects include brain abnormalities and/or microcephaly; intracranial calcifications; ventriculomegaly; neural tube defects and other early brain malformations; eye abnormalities; or other consequences of central nervous system dysfunction including arthrogryposis (joint contractures), clubfoot, congenital hip dysplasia, and congenital deafness (https://www.cdc.gov/zika/geo/pregnancy-outcomes.html).
†† Recommendations for specimen collection and submission are available at https://www.cdc.gov/zika/laboratories/test-specimens-tissues.html.
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TABLE 1. Categories for laboratory evidence of maternal Zika virus infection from testing of nontissue clinical samples (e.g., serum, urine)
Category | Definition |
---|---|
Confirmed recent Zika virus infection | Positive Zika virus RT-PCR, or Zika or dengue virus IgM positive or equivocal* with Zika virus PRNT titer ≥10 and dengue virus PRNT titer <10 |
Recent unspecified flavivirus infection | Zika virus RT-PCR negative or not performed, with Zika or dengue virus IgM positive, or equivocal with Zika virus and dengue virus PRNT titers ≥10 |
Maternal samples negative by Zika virus IgM, all or part of possible exposure occurred >12 weeks before serum collection | Zika virus RT-PCR negative or not performed, with Zika virus IgM negative, where all or part of possible maternal exposure occurred >12 weeks before serum collection date |
Pending/Unknown | Test results unknown or pending |
No evidence of Zika virus infection | Zika or dengue IgM positive or equivocal with Zika virus PRNT titer <10 regardless of dengue PRNT titer, or Zika virus IgM negative where all possible exposure occurred within 2–12 weeks of serum collection date |
No maternal clinical samples tested | No maternal serum, urine, or other clinical specimens tested |
TABLE 2. Zika virus RT-PCR results from fixed placental and fetal tissue samples from completed pregnancies for which specimens* were submitted to CDC’s Infectious Diseases Pathology Branch, by pregnancy outcome — 50 U.S. states and District of Columbia (n = 627), including 449 reported to the U.S. Zika Pregnancy Registry, January–December 2016
All completed pregnancies from which tissue specimens were submitted (n = 627) | ||||
---|---|---|---|---|
Characteristic | Live births (n = 546) | Pregnancy losses (n = 81) | ||
Live births with tissue specimens tested, no. | Tissue RT-PCR positive,† no. (%) | Pregnancy losses with tissue specimens tested, no. | Tissue RT-PCR positive, no. (%) | |
Total | 546 | 60 (11) | 81 | 18 (22) |
Maternal clinical Zika virus test results§ | ||||
Confirmed recent Zika virus infection | 47 | 13 (28) | 19 | 11 (58) |
Recent unspecified flavivirus infection | 363 | 38 (10) | 13 | 4 (31) |
Maternal samples negative by Zika virus IgM, all or part of possible exposure occurred >12 weeks before serum collected¶ | 86 | 9 (10) | 18 | 2 (11) |
No maternal clinical samples tested** | 34 | — | 16 | 1 (6) |
Pending/Unknown | 2 | — | 1 | — |
No evidence of possible Zika virus infection | 14 | — | 14 | — |
Infant clinical Zika virus test results†† | ||||
Confirmed congenital Zika virus infection | 3 | — | NA | NA |
Probable congenital Zika virus infection | 46 | 9 (20) | NA | NA |
Negative Zika virus testing | 358 | 39 (11) | NA | NA |
No results reported | 139 | 12 (9) | NA | NA |
Trimester of infection or possible exposure§§ | ||||
First trimester only | 90 | 9 (10) | 41 | 12 (29) |
Multiple trimesters, including first | 291 | 32 (11) | 24 | 4 (17) |
Second and/or third trimester only | 149 | 18 (12) | 4 | — |
Periconceptional only | 11 | 1 (9) | 10 | 2 (20) |
Unknown/Missing | 5 | — | 2 | — |
Maternal symptom status | ||||
Asymptomatic | 366 | 37 (10) | 56 | 7 (13) |
Symptomatic | 176 | 23 (13) | 25 | 11 (44) |
Unknown | 4 | — | — | — |
Trimester of pregnancy loss | ||||
Pregnancy loss, first trimester | NA | NA | 28 | 10 (36) |
Pregnancy loss, second trimester | NA | NA | 35 | 3 (9) |
Pregnancy loss, third trimester | NA | NA | 17 | 5 (29) |
Missing | NA | NA | 1 | — |
Completed pregnancies reported to the U.S. Zika Pregnancy Registry¶¶ (n = 449) | ||||
Characteristic | Live births (n = 414) | Pregnancy losses (n = 35) | ||
Total | 414 | 60 (14) | 35 | 18 (51) |
Possible Zika virus–associated birth defects*** | ||||
Birth defects reported | 30 | 16 (53) | 4 | 2 (50) |
No birth defects reported | 384 | 44 (11) | 31 | 16 (52) |
FIGURE. Zika virus placental tissue RT-PCR results, among live births with neither clinical laboratory evidence of confirmed recent Zika virus infection on maternal testing nor confirmed congenital Zika virus infection on infant testing (n = 482),*,†,§ by maternal clinical Zika virus test results categories¶,** — 50 U.S. states and the District of Columbia, January–December, 2016
Abbreviations: IgM = immunoglobulin M; PRNT= plaque-reduction neutralization test; RT-PCR = reverse transcription–polymerase chain reaction.
* Excludes live births with confirmed recent maternal Zika virus infection (positive Zika virus RT-PCR, or Zika or dengue virus IgM-positive or equivocal with Zika virus PRNT titer ≥10 and dengue virus PRNT titer <10) or no evidence of Zika virus infection (Zika or dengue virus IgM positive or equivocal with Zika virus PRNT titer <10 regardless of dengue PRNT titer, or Zika virus IgM negative where all possible exposure occurred within 2–12 weeks of serum collection date), or confirmed congenital Zika virus infection based on infant testing (positive Zika virus RT-PCR or Zika virus IgM positive and Zika virus PRNT titer ≥10 with dengue virus PRNT titer <10).
† Includes 41 live births where infants had laboratory evidence of probable congenital Zika virus infection; 9/41 (22%) with placental tissue RT-PCR positive; and 441 live births where infants had negative Zika virus testing or no Zika virus testing reported; 38/441 (9%) with placental tissue RT-PCR positive. Positive placental tissue RT-PCR results provide evidence of confirmed recent maternal Zika virus infection.
§ Placental tissue RT-PCR positive = at least one placental tissue specimen was positive by Zika virus RT-PCR.
¶ Recent unspecified flavivirus infection = negative or no Zika virus RT-PCR performed, with Zika or dengue virus IgM positive, or equivocal with Zika and dengue virus PRNT titers ≥10.
** Maternal samples negative by Zika virus IgM, all or part of possible exposure occurred >12 weeks before serum collection date with negative or no Zika virus RT-PCR performed, maternal Zika virus testing not performed, or results pending or unknown.
The figure above is a bar graph showing Zika virus placental tissue RT-PCR results, among live births with neither clinical laboratory evidence of confirmed recent Zika virus infection on maternal testing nor confirmed congenital Zika virus infection on infant testing, by maternal clinical Zika virus test results categories in 50 U.S. states and the District of Columbia during January–December, 2016.
Suggested citation for this article: Reagan-Steiner S, Simeone R, Simon E, et al. Evaluation of Placental and Fetal Tissue Specimens for Zika Virus Infection — 50 States and District of Columbia, January–December, 2016. MMWR Morb Mortal Wkly Rep 2017;66:636–643. DOI: http://dx.doi.org/10.15585/mmwr.mm6624a3.
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