Last data update: Jan 27, 2025. (Total: 48650 publications since 2009)
Records 1-14 (of 14 Records) |
Query Trace: Jones AM[original query] |
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Identifying possible inaccuracy in reported birth head circumference measurements among infants in the US Zika Pregnancy and Infant Registry
Roth NM , Woodworth KR , Godfred-Cato S , Delaney AM , Olson SM , Nahabedian JF3rd , Reynolds MR , Jones AM , Neelam V , Valencia-Prado M , Delgado-López C , Lee EH , Ellis EM , Lake-Burger H , Tonzel JL , Higgins CA , Chan RL , Tong VT , Gilboa SM , Cragan JD , Honein MA , Moore CA . Birth Defects Res 2022 114 (8) 314-318 BACKGROUND: The US Zika Pregnancy and Infant Registry (USZPIR) monitors infants born to mothers with confirmed or possible Zika virus infection during pregnancy. The surveillance case definition for Zika-associated birth defects includes microcephaly based on head circumference (HC). METHODS: We assessed birth and follow-up data from infants with birth HC measurements <3rd percentile and birthweight ≥10th percentile to determine possible misclassification of microcephaly. We developed a schema informed by literature review and expert opinion to identify possible HC measurement inaccuracy using HC growth velocity and longitudinal HC measurements between 2 and 12 months of age. Two or more HC measurements were required for assessment. Inaccuracy in birth HC measurement was suspected if growth velocity was >3 cm/month in the first 3 months or HC was consistently >25th percentile during follow-up. RESULTS: Of 6,799 liveborn infants in USZPIR, 351 (5.2%) had Zika-associated birth defects, of which 111 had birth HC measurements <3rd percentile and birthweight ≥10th percentile. Of 84/111 infants with sufficient follow-up, 38/84 (45%) were classified as having possible inaccuracy of birth HC measurement, 19/84 (23%) had HC ≥3rd percentile on follow-up without meeting criteria for possible inaccuracy, and 27/84 (32%) had continued HC <3rd percentile. After excluding possible inaccuracies, the proportion of infants with Zika-associated birth defects including microcephaly decreased from 5.2% to 4.6%. CONCLUSIONS: About one-third of infants in USZPIR with Zika-associated birth defects had only microcephaly, but indications of possible measurement inaccuracy were common. Implementation of this schema in longitudinal studies can reduce misclassification of microcephaly. |
Clinical phenotype in infants with negative Zika virus immunoglobulin M testing born to mothers with confirmed Zika virus infection during pregnancy
Godfred-Cato S , Newton S , Adams L , Valencia-Prado M , Lake-Burger H , Morrison A , Jones AM , Olson SM , Roth NM , Tong VT , Gilboa SM , Meaney Delman D , Honein MA , Staples JE , Moore CA . Birth Defects Res 2021 113 (17) 1267-1274 BACKGROUND: Recommended testing for both infants with Zika-associated birth defects (i.e., microcephaly and selected brain or eye anomalies) and infants without birth defects whose mothers had laboratory evidence of possible Zika virus (ZIKV) infection during pregnancy includes nucleic acid amplification testing (NAAT) and immunoglobulin M (IgM) testing within days after birth. Brain and eye defects highly specific for congenital ZIKV infection have been described; sporadic reports have documented negative ZIKV testing in such infants. METHODS: Infants from the U.S. Zika Pregnancy and Infant Registry and Zika Birth Defects Surveillance with Zika-associated birth defects and maternal and infant laboratory testing for ZIKV and two congenital infections (i.e., cytomegalovirus [CMV] and toxoplasmosis) were reviewed for phenotype and laboratory results. Infants with at least one defect considered highly specific for congenital ZIKV infection were designated as having congenital Zika syndrome (CZS) clinical phenotype for this study. RESULTS: Of 325 liveborn infants with Zika-associated birth defects and laboratory evidence of maternal ZIKV infection, 33 (10%) had CZS clinical phenotype; 171 (53%) had ZIKV IgM testing with negative or no ZIKV NAAT. ZIKV IgM was negative in the remaining 120 infants, and for 90%, testing for CMV and toxoplasmosis was missing/incomplete. Among 11 infants testing negative for ZIKV IgM, CMV, and toxoplasmosis, 2 infants had CZS clinical phenotype. CONCLUSIONS: These data add support to previous reports of negative ZIKV IgM testing in infants with clear maternal and phenotypic evidence of congenital ZIKV infection. Follow-up care consistent with the diagnosis is recommended regardless of infant ZIKV test results. |
Role of prenatal ultrasonography and amniocentesis in the diagnosis of congenital Zika syndrome: A systematic review
Viens LJ , Fleck-Derderian S , Baez-Santiago MA , Oduyebo T , Broussard CS , Khan S , Jones AM , Meaney-Delman D . Obstet Gynecol 2020 135 (5) 1185-1197 OBJECTIVE: To examine the relationship between prenatal diagnostics (ultrasound examination and amniotic fluid Zika virus testing) and postnatal congenital Zika syndrome abnormalities. DATA SOURCES: Systematic searches were performed in 27 databases, including ClinicalTrials.gov, from inception to July 1, 2019, for articles with the keywords "Zika," "prenatal," "ultrasound," and "amniocentesis." METHODS OF STUDY SELECTION: A total of 3,049 unique records were identified. Two reviewers independently assessed titles, abstracts, and full texts for relevance; 84 articles met the inclusion criteria. These articles describe 402 mother-fetus or mother-neonate dyads; 385 were included in the review of prenatal ultrasound examination, and 56 in the review of amniocentesis (39 in both). TABULATION, INTEGRATION, AND RESULTS: Among 195 fetuses with congenital Zika syndrome findings on prenatal ultrasound examination, postnatal congenital Zika syndrome abnormalities were reported for 153 (78%; 95% CI 7-84%). High proportions of microcephaly (76%; 95% CI 69-82%) and brain abnormalities (78%; 95% CI 69-86%) were confirmed postnatally. Among 190 fetuses without congenital Zika syndrome findings on prenatal ultrasound examination, 17% (95% CI 12-24%) had congenital Zika syndrome abnormalities identified postnatally. Structural congenital Zika syndrome abnormalities were identified postnatally in approximately equal proportions among dyads with and without Zika virus RNA detected in an amniotic fluid specimen (68% and 67%; 95% CI 52-82% and 95% CI 38-88%). In six pregnancies, Zika virus RNA was detected in amniotic fluid but not in a subsequent amniocentesis specimen. CONCLUSION: Prenatal ultrasound examination frequently detects structural findings associated with Zika virus infection; however, not all abnormalities are detected, and some may represent transient findings. As with other congenital infections, prenatal detection may vary with timing of infection, timing of ultrasound examination, technical expertise, and severity of abnormalities. The detection of Zika virus RNA in amniotic fluid in the included studies did not predict the risk for congenital Zika syndrome abnormalities in these cases, and clearance of Zika virus RNA from amniotic fluid appears possible after maternal infection. Diagnostic testing for Zika virus infection remains a shared decision between patients and clinicians, and more data are needed to define clinical predictors that will inform these decisions. SYSTEMATIC REVIEW REGISTRATION: PROSPERO, CRD42018080959. |
Population-based surveillance for birth defects potentially related to Zika virus infection - 22 states and territories, January 2016-June 2017
Smoots AN , Olson SM , Cragan J , Delaney A , Roth NM , Godfred-Cato S , Jones AM , Nahabedian JF 3rd , Fornoff J , Sandidge T , Yazdy MM , Higgins C , Olney RS , Eckert V , Forkner A , Fox DJ , Stolz A , Crawford K , Cho SJ , Knapp M , Ahmed MF , Lake-Burger H , Elmore AL , Langlois P , Breidenbach R , Nance A , Denson L , Caton L , Forestieri N , Bergman K , Humphries BK , Leedom VO , Tran T , Johnston J , Valencia-Prado M , Perez-Gonzalez S , Romitti PA , Fall C , Bryan JM , Barton J , Arias W , St John K , Mann S , Kimura J , Orantes L , Martin B , de Wilde L , Ellis EM , Song Z , Akosa A , Goodroe C , Ellington SR , Tong VT , Gilboa SM , Moore CA , Honein MA . MMWR Morb Mortal Wkly Rep 2020 69 (3) 67-71 Zika virus infection during pregnancy can cause congenital brain and eye abnormalities and is associated with neurodevelopmental abnormalities (1-3). In areas of the United States that experienced local Zika virus transmission, the prevalence of birth defects potentially related to Zika virus infection during pregnancy increased in the second half of 2016 compared with the first half (4). To update the previous report, CDC analyzed population-based surveillance data from 22 states and territories to estimate the prevalence of birth defects potentially related to Zika virus infection, regardless of laboratory evidence of or exposure to Zika virus, among pregnancies completed during January 1, 2016-June 30, 2017. Jurisdictions were categorized as those 1) with widespread local transmission of Zika virus; 2) with limited local transmission of Zika virus; and 3) without local transmission of Zika virus. Among 2,004,630 live births, 3,359 infants and fetuses with birth defects potentially related to Zika virus infection during pregnancy were identified (1.7 per 1,000 live births, 95% confidence interval [CI] = 1.6-1.7). In areas with widespread local Zika virus transmission, the prevalence of birth defects potentially related to Zika virus infection during pregnancy was significantly higher during the quarters comprising July 2016-March 2017 (July-September 2016 = 3.0; October-December 2016 = 4.0; and January-March 2017 = 5.6 per 1,000 live births) compared with the reference period (January-March 2016) (1.3 per 1,000). These findings suggest a fourfold increase (prevalence ratio [PR] = 4.1, 95% CI = 2.1-8.4) in birth defects potentially related to Zika virus in widespread local transmission areas during January-March 2017 compared with that during January-March 2016, with the highest prevalence (7.0 per 1,000 live births) in February 2017. Population-based birth defects surveillance is critical for identifying infants and fetuses with birth defects potentially related to Zika virus regardless of whether Zika virus testing was conducted, especially given the high prevalence of asymptomatic disease. These data can be used to inform follow-up care and services as well as strengthen surveillance. |
Trisomy 13 and 18-Prevalence and mortality-A multi-registry population based analysis.
Goel N , Morris JK , Tucker D , de Walle HEK , Bakker MK , Kancherla V , Marengo L , Canfield MA , Kallen K , Lelong N , Camelo JL , Stallings EB , Jones AM , Nance A , Huynh MP , Martinez-Fernandez ML , Sipek A , Pierini A , Nembhard WN , Goetz D , Rissmann A , Groisman B , Luna-Munoz L , Szabova E , Lapchenko S , Zarante I , Hurtado-Villa P , Martinez LE , Tagliabue G , Landau D , Gatt M , Dastgiri S , Morgan M . Am J Med Genet A 2019 179 (12) 2382-2392 ![]() The aim of the study is to determine the prevalence, outcomes, and survival (among live births [LB]), in pregnancies diagnosed with trisomy 13 (T13) and 18 (T18), by congenital anomaly register and region. Twenty-four population- and hospital-based birth defects surveillance registers from 18 countries, contributed data on T13 and T18 between 1974 and 2014 using a common data-reporting protocol. The mean total birth prevalence (i.e., LB, stillbirths, and elective termination of pregnancy for fetal anomalies [ETOPFA]) in the registers with ETOPFA (n = 15) for T13 was 1.68 (95% CI 1.3-2.06), and for T18 was 4.08 (95% CI 3.01-5.15), per 10,000 births. The prevalence varied among the various registers. The mean prevalence among LB in all registers for T13 was 0.55 (95%CI 0.38-0.72), and for T18 was 1.07 (95% CI 0.77-1.38), per 10,000 births. The median mortality in the first week of life was 48% for T13 and 42% for T18, across all registers, half of which occurred on the first day of life. Across 16 registers with complete 1-year follow-up, mortality in first year of life was 87% for T13 and 88% for T18. This study provides an international perspective on prevalence and mortality of T13 and T18. Overall outcomes and survival among LB were poor with about half of live born infants not surviving first week of life; nevertheless about 10% survived the first year of life. Prevalence and outcomes varied by country and termination policies. The study highlights the variation in screening, data collection, and reporting practices for these conditions. |
Updated baseline prevalence of birth defects potentially related to Zika virus infection
Olson SM , Delaney A , Jones AM , Carr CP , Liberman RF , Forestieri NE , Tong VT , Gilboa SM , Honein MA , Moore CA , Cragan JD . Birth Defects Res 2019 111 (13) 938-940 Zika virus (ZIKV) was first recognized as a human teratogen in 2016 (Rasmussen, Jamieson, Honein, & Petersen, 2016). During the ZIKV outbreak in the Americas, we launched rapid surveillance of pregnancies with laboratory evidence of ZIKV infection and targeted surveillance of birth defects. Because little was known about the birth defects associated with congenital ZIKV infection, a broad case definition was used for surveillance of birth defects potentially related to ZIKV based on early reports of congenital ZIKV infection in the literature and expert opinion. The initial case definition included microcephaly and/or brain abnormalities, neural tube defects (NTDs) and other early brain malformations (e.g., holoprosencephaly), eye abnormalities, and consequences of central nervous system (CNS) dysfunction such as arthrogryposis and hearing loss (Honein et al., 2017). The baseline prevalence of these defects in the United States prior to the ZIKV outbreak was estimated as 2.86 per 1,000 live births (95% CI: 2.65–3.07) using data from statewide birth defects surveillance programs in Massachusetts and North Carolina in 2013 and from three counties in metropolitan Atlanta, Georgia, during 2013–2014 (Cragan et al., 2017). |
Vital signs: Zika-associated birth defects and neurodevelopmental abnormalities possibly associated with congenital Zika virus infection - U.S. Territories and freely associated states, 2018
Rice ME , Galang RR , Roth NM , Ellington SR , Moore CA , Valencia-Prado M , Ellis EM , Tufa AJ , Taulung LA , Alfred JM , Perez-Padilla J , Delgado-Lopez CA , Zaki SR , Reagan-Steiner S , Bhatnagar J , Nahabedian JF 3rd , Reynolds MR , Yeargin-Allsopp M , Viens LJ , Olson SM , Jones AM , Baez-Santiago MA , Oppong-Twene P , VanMaldeghem K , Simon EL , Moore JT , Polen KD , Hillman B , Ropeti R , Nieves-Ferrer L , Marcano-Huertas M , Masao CA , Anzures EJ , Hansen RL Jr , Perez-Gonzalez SI , Espinet-Crespo CP , Luciano-Roman M , Shapiro-Mendoza CK , Gilboa SM , Honein MA . MMWR Morb Mortal Wkly Rep 2018 67 (31) 858-867 INTRODUCTION: Zika virus infection during pregnancy causes serious birth defects and might be associated with neurodevelopmental abnormalities in children. Early identification of and intervention for neurodevelopmental problems can improve cognitive, social, and behavioral functioning. METHODS: Pregnancies with laboratory evidence of confirmed or possible Zika virus infection and infants resulting from these pregnancies are included in the U.S. Zika Pregnancy and Infant Registry (USZPIR) and followed through active surveillance methods. This report includes data on children aged >/=1 year born in U.S. territories and freely associated states. Receipt of reported follow-up care was assessed, and data were reviewed to identify Zika-associated birth defects and neurodevelopmental abnormalities possibly associated with congenital Zika virus infection. RESULTS: Among 1,450 children of mothers with laboratory evidence of confirmed or possible Zika virus infection during pregnancy and with reported follow-up care, 76% had developmental screening or evaluation, 60% had postnatal neuroimaging, 48% had automated auditory brainstem response-based hearing screen or evaluation, and 36% had an ophthalmologic evaluation. Among evaluated children, 6% had at least one Zika-associated birth defect identified, 9% had at least one neurodevelopmental abnormality possibly associated with congenital Zika virus infection identified, and 1% had both. CONCLUSION: One in seven evaluated children had a Zika-associated birth defect, a neurodevelopmental abnormality possibly associated with congenital Zika virus infection, or both reported to the USZPIR. Given that most children did not have evidence of all recommended evaluations, additional anomalies might not have been identified. Careful monitoring and evaluation of children born to mothers with evidence of Zika virus infection during pregnancy is essential for ensuring early detection of possible disabilities and early referral to intervention services. |
Population genomics and the evolution of virulence in the fungal pathogen Cryptococcus neoformans.
Desjardins CA , Giamberardino C , Sykes SM , Yu CH , Tenor JL , Chen Y , Yang T , Jones AM , Sun S , Haverkamp MR , Heitman J , Litvintseva AP , Perfect JR , Cuomo CA . Genome Res 2017 27 (7) 1207-1219 ![]() Cryptococcus neoformans is an opportunistic fungal pathogen that causes approximately 625,000 deaths per year from nervous system infections. Here, we leveraged a unique, genetically diverse population of C. neoformans from sub-Saharan Africa, commonly isolated from mopane trees, to determine how selective pressures in the environment coincidentally adapted C. neoformans for human virulence. Genome sequencing and phylogenetic analysis of 387 isolates, representing the global VNI and African VNB lineages, highlighted a deep, nonrecombining split in VNB (herein, VNBI and VNBII). VNBII was enriched for clinical samples relative to VNBI, while phenotypic profiling of 183 isolates demonstrated that VNBI isolates were significantly more resistant to oxidative stress and more heavily melanized than VNBII isolates. Lack of melanization in both lineages was associated with loss-of-function mutations in the BZP4 transcription factor. A genome-wide association study across all VNB isolates revealed sequence differences between clinical and environmental isolates in virulence factors and stress response genes. Inositol transporters and catabolism genes, which process sugars present in plants and the human nervous system, were identified as targets of selection in all three lineages. Further phylogenetic and population genomic analyses revealed extensive loss of genetic diversity in VNBI, suggestive of a history of population bottlenecks, along with unique evolutionary trajectories for mating type loci. These data highlight the complex evolutionary interplay between adaptation to natural environments and opportunistic infections, and that selection on specific pathways may predispose isolates to human virulence. |
Pregnancy outcomes after maternal Zika virus infection during pregnancy - U.S. territories, January 1, 2016-April 25, 2017
Shapiro-Mendoza CK , Rice ME , Galang RR , Fulton AC , VanMaldeghem K , Prado MV , Ellis E , Anesi MS , Simeone RM , Petersen EE , Ellington SR , Jones AM , Williams T , Reagan-Steiner S , Perez-Padilla J , Deseda CC , Beron A , Tufa AJ , Rosinger A , Roth NM , Green C , Martin S , Lopez CD , deWilde L , Goodwin M , Pagano HP , Mai CT , Gould C , Zaki S , Ferrer LN , Davis MS , Lathrop E , Polen K , Cragan JD , Reynolds M , Newsome KB , Huertas MM , Bhatangar J , Quinones AM , Nahabedian JF , Adams L , Sharp TM , Hancock WT , Rasmussen SA , Moore CA , Jamieson DJ , Munoz-Jordan JL , Garstang H , Kambui A , Masao C , Honein MA , Meaney-Delman D . MMWR Morb Mortal Wkly Rep 2017 66 (23) 615-621 Pregnant women living in or traveling to areas with local mosquito-borne Zika virus transmission are at risk for Zika virus infection, which can lead to severe fetal and infant brain abnormalities and microcephaly (1). In February 2016, CDC recommended 1) routine testing for Zika virus infection of asymptomatic pregnant women living in areas with ongoing local Zika virus transmission at the first prenatal care visit, 2) retesting during the second trimester for women who initially test negative, and 3) testing of pregnant women with signs or symptoms consistent with Zika virus disease (e.g., fever, rash, arthralgia, or conjunctivitis) at any time during pregnancy (2). To collect information about pregnant women with laboratory evidence of recent possible Zika virus infection* and outcomes in their fetuses and infants, CDC established pregnancy and infant registries (3). During January 1, 2016-April 25, 2017, U.S. territoriesdagger with local transmission of Zika virus reported 2,549 completed pregnancies section sign (live births and pregnancy losses at any gestational age) with laboratory evidence of recent possible Zika virus infection; 5% of fetuses or infants resulting from these pregnancies had birth defects potentially associated with Zika virus infection paragraph sign (4,5). Among completed pregnancies with positive nucleic acid tests confirming Zika infection identified in the first, second, and third trimesters, the percentage of fetuses or infants with possible Zika-associated birth defects was 8%, 5%, and 4%, respectively. Among liveborn infants, 59% had Zika laboratory testing results reported to the pregnancy and infant registries. Identification and follow-up of infants born to women with laboratory evidence of recent possible Zika virus infection during pregnancy permits timely and appropriate clinical intervention services (6). |
Vital Signs: Update on Zika virus-associated birth defects and evaluation of all U.S. Infants with congenital Zika virus exposure - U.S. Zika Pregnancy Registry, 2016
Reynolds MR , Jones AM , Petersen EE , Lee EH , Rice ME , Bingham A , Ellington SR , Evert N , Reagan-Steiner S , Oduyebo T , Brown CM , Martin S , Ahmad N , Bhatnagar J , Macdonald J , Gould C , Fine AD , Polen KD , Lake-Burger H , Hillard CL , Hall N , Yazdy MM , Slaughter K , Sommer JN , Adamski A , Raycraft M , Fleck-Derderian S , Gupta J , Newsome K , Baez-Santiago M , Slavinski S , White JL , Moore CA , Shapiro-Mendoza CK , Petersen L , Boyle C , Jamieson DJ , Meaney-Delman D , Honein MA . MMWR Morb Mortal Wkly Rep 2017 66 (13) 366-373 BACKGROUND: In collaboration with state, tribal, local, and territorial health departments, CDC established the U.S. Zika Pregnancy Registry (USZPR) in early 2016 to monitor pregnant women with laboratory evidence of possible recent Zika virus infection and their infants. METHODS: This report includes an analysis of completed pregnancies (which include live births and pregnancy losses, regardless of gestational age) in the 50 U.S. states and the District of Columbia (DC) with laboratory evidence of possible recent Zika virus infection reported to the USZPR from January 15 to December 27, 2016. Birth defects potentially associated with Zika virus infection during pregnancy include brain abnormalities and/or microcephaly, eye abnormalities, other consequences of central nervous system dysfunction, and neural tube defects and other early brain malformations. RESULTS: During the analysis period, 1,297 pregnant women in 44 states were reported to the USZPR. Zika virus-associated birth defects were reported for 51 (5%) of the 972 fetuses/infants from completed pregnancies with laboratory evidence of possible recent Zika virus infection (95% confidence interval [CI] = 4%-7%); the proportion was higher when restricted to pregnancies with laboratory-confirmed Zika virus infection (24/250 completed pregnancies [10%, 95% CI = 7%-14%]). Birth defects were reported in 15% (95% CI = 8%-26%) of fetuses/infants of completed pregnancies with confirmed Zika virus infection in the first trimester. Among 895 liveborn infants from pregnancies with possible recent Zika virus infection, postnatal neuroimaging was reported for 221 (25%), and Zika virus testing of at least one infant specimen was reported for 585 (65%). CONCLUSIONS AND IMPLICATIONS FOR PUBLIC HEALTH PRACTICE: These findings highlight why pregnant women should avoid Zika virus exposure. Because the full clinical spectrum of congenital Zika virus infection is not yet known, all infants born to women with laboratory evidence of possible recent Zika virus infection during pregnancy should receive postnatal neuroimaging and Zika virus testing in addition to a comprehensive newborn physical exam and hearing screen. Identification and follow-up care of infants born to women with laboratory evidence of possible recent Zika virus infection during pregnancy and infants with possible congenital Zika virus infection can ensure that appropriate clinical services are available. |
Birth defects among fetuses and infants of US women with evidence of possible Zika virus infection during pregnancy
Honein MA , Dawson AL , Petersen EE , Jones AM , Lee EH , Yazdy MM , Ahmad N , Macdonald J , Evert N , Bingham A , Ellington SR , Shapiro-Mendoza CK , Oduyebo T , Fine AD , Brown CM , Sommer JN , Gupta J , Cavicchia P , Slavinski S , White JL , Owen SM , Petersen LR , Boyle C , Meaney-Delman D , Jamieson DJ . JAMA 2016 317 (1) 59-68 Importance: Understanding the risk of birth defects associated with Zika virus infection during pregnancy may help guide communication, prevention, and planning efforts. In the absence of Zika virus, microcephaly occurs in approximately 7 per 10000 live births. Objective: To estimate the preliminary proportion of fetuses or infants with birth defects after maternal Zika virus infection by trimester of infection and maternal symptoms. Design, Setting, and Participants: Completed pregnancies with maternal, fetal, or infant laboratory evidence of possible recent Zika virus infection and outcomes reported in the continental United States and Hawaii from January 15 to September 22, 2016, in the US Zika Pregnancy Registry, a collaboration between the CDC and state and local health departments. Exposures: Laboratory evidence of possible recent Zika virus infection in a maternal, placental, fetal, or infant sample. Main Outcomes and Measures: Birth defects potentially Zika associated: brain abnormalities with or without microcephaly, neural tube defects and other early brain malformations, eye abnormalities, and other central nervous system consequences. Results: Among 442 completed pregnancies in women (median age, 28 years; range, 15-50 years) with laboratory evidence of possible recent Zika virus infection, birth defects potentially related to Zika virus were identified in 26 (6%; 95% CI, 4%-8%) fetuses or infants. There were 21 infants with birth defects among 395 live births and 5 fetuses with birth defects among 47 pregnancy losses. Birth defects were reported for 16 of 271 (6%; 95% CI, 4%-9%) pregnant asymptomatic women and 10 of 167 (6%; 95% CI, 3%-11%) symptomatic pregnant women. Of the 26 affected fetuses or infants, 4 had microcephaly and no reported neuroimaging, 14 had microcephaly and brain abnormalities, and 4 had brain abnormalities without microcephaly; reported brain abnormalities included intracranial calcifications, corpus callosum abnormalities, abnormal cortical formation, cerebral atrophy, ventriculomegaly, hydrocephaly, and cerebellar abnormalities. Infants with microcephaly (18/442) represent 4% of completed pregnancies. Birth defects were reported in 9 of 85 (11%; 95% CI, 6%-19%) completed pregnancies with maternal symptoms or exposure exclusively in the first trimester (or first trimester and periconceptional period), with no reports of birth defects among fetuses or infants with prenatal exposure to Zika virus infection only in the second or third trimesters. Conclusions and Relevance: Among pregnant women in the United States with completed pregnancies and laboratory evidence of possible recent Zika infection, 6% of fetuses or infants had evidence of Zika-associated birth defects, primarily brain abnormalities and microcephaly, whereas among women with first-trimester Zika infection, 11% of fetuses or infants had evidence of Zika-associated birth defects. These findings support the importance of screening pregnant women for Zika virus exposure. |
HIV testing among internet-using MSM in the United States: Systematic review
Noble M , Jones AM , Bowles K , DiNenno EA , Tregear SJ . AIDS Behav 2016 21 (2) 561-575 Regular HIV testing enables early identification and treatment of HIV among at-risk men who have sex with men (MSM). Characterizing HIV testing needs for Internet-using MSM informs development of Internet-facilitated testing interventions. In this systematic review we analyze HIV testing patterns among Internet-using MSM in the United States who report, through participation in an online study or survey, their HIV status as negative or unknown and identify demographic or behavioral risk factors associated with testing. We systematically searched multiple electronic databases for relevant English-language articles published between January 1, 2005 and December 16, 2014. Using meta-analysis, we summarized the proportion of Internet-using MSM who had ever tested for HIV and the proportion who tested in the 12 months preceding participation in the online study or survey. We also identified factors predictive of these outcomes using meta-regression and narrative synthesis. Thirty-two studies that enrolled 83,186 MSM met our inclusion criteria. Among the studies reporting data for each outcome, 85 % (95 % CI 82-87 %) of participants had ever tested, and 58 % (95 % CI 53-63 %) had tested in the year preceding enrollment in the study, among those for whom those data were reported. Age over 30 years, at least a college education, use of drugs, and self-identification as being homosexual or gay were associated with ever having tested for HIV. A large majority of Internet-using MSM indicated they had been tested for HIV at some point in the past. A smaller proportion-but still a majority-reported they had been tested within the year preceding study or survey participation. MSM who self-identify as heterosexual or bisexual, are younger, or who use drugs (including non-injection drugs) may be less likely to have ever tested for HIV. The overall findings of our systematic review are encouraging; however, a subpopulation of MSM may benefit from targeted outreach. These findings indicate unmet needs for HIV testing among Internet-using MSM and identify subpopulations that might benefit from targeted outreach, such as provision of HIV self-testing kits. |
Increasing prevalence of gastroschisis - 14 States, 1995-2012
Jones AM , Isenburg J , Salemi JL , Arnold KE , Mai CT , Aggarwal D , Arias W , Carrino GE , Ferrell E , Folorunso O , Ibe B , Kirby RS , Krapfl HR , Marengo LK , Mosley BS , Nance AE , Romitti PA , Spadafino J , Stock J , Honein MA . MMWR Morb Mortal Wkly Rep 2016 65 (2) 23-6 Gastroschisis is a serious congenital defect in which the intestines protrude through an opening in the abdominal wall. Gastroschisis requires surgical repair soon after birth and is associated with an increased risk for medical complications and mortality during infancy. Reports from multiple surveillance systems worldwide have documented increasing prevalence of gastroschisis since the 1980s, particularly among younger mothers; however, since publication of a multistate U.S. report that included data through 2005 (1), it is not known whether prevalence has continued to increase. Data on gastroschisis from 14 population-based state surveillance programs were pooled and analyzed to assess the average annual percent change (AAPC) in prevalence and to compare the prevalence during 2006-2012 with that during 1995-2005, stratified by maternal age and race/ethnicity. The pooled data included approximately 29% of U.S. births for the period 1995-2012. During 1995-2012, gastroschisis prevalence increased in every category of maternal age and race/ethnicity, and the AAPC ranged from 3.1% in non-Hispanic white (white) mothers aged <20 years to 7.9% in non-Hispanic black (black) mothers aged <20 years. These corresponded to overall percentage increases during 1995-2012 that ranged from 68% in white mothers aged <20 years to 263% in black mothers aged <20 years. Gastroschisis prevalence increased 30% between the two periods, from 3.6 per 10,000 births during 1995-2005 to 4.9 per 10,000 births during 2006-2012 (prevalence ratio = 1.3, 95% confidence interval [CI]: 1.3-1.4), with the largest increase among black mothers aged <20 years (prevalence ratio = 2.0, 95% CI: 1.6-2.5). Public health research is urgently needed to identify factors contributing to this increase. |
Substantial regional differences in human herpesvirus 8 seroprevalence in sub-saharan Africa: insights on the origin of the "KS Belt"
Dollard SC , Butler LM , Graves Jones AM , Mermin JH , Chidzonga M , Chipato T , Shiboski CH , Brander C , Mosam A , Kiepiela P , Hladik W , Martin JN . Int J Cancer 2010 127 (10) 2395-401 Equatorial Africa has among the highest incidences of Kaposi's sarcoma (KS) in the world, thus earning the name "KS Belt." This was the case even prior to the HIV epidemic. To date, there is no clear evidence that HHV-8 seroprevalence is higher in this region, but interpretation of the available literature is tempered by differences in serologic assays used across studies. We examined representatively sampled ambulatory adults in Uganda, which is in the "KS Belt", and in Zimbabwe and South Africa which are outside the Belt, for HHV-8 antibodies. All serologic assays were uniformly performed in the same reference laboratory by the same personnel. In the base-case serologic algorithm, seropositivity was defined by reactivity in an immunofluorescence assay or in two enzyme immunoassays. A total of 2375 participants were examined. In Uganda, HHV-8 seroprevalence was high early in adulthood (35.5% by age 21) without significant change thereafter. In contrast, HHV-8 seroprevalence early in adulthood was lower in Zimbabwe and South Africa (13.7% and 10.8%, respectively), but increased with age. After age adjustment, Ugandans had 3.24-fold greater odds of being HHV-8-infected than South Africans (p<0.001) and 2.22-fold greater odds than Zimbabweans (p<0.001). Inferences were unchanged using all other serologic algorithms evaluated. In conclusion, HHV-8 infection is substantially more common in Uganda than in Zimbabwe and South Africa. These findings help explain the high KS incidence in the "KS Belt" and underscore the importance of a uniform approach to HHV-8 antibody testing. (c) 2010 UICC. |
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