Near real-time monitoring of HIV transmission hotspots from routine HIV genotyping: an implementation case study

Poon, Art F. Y.; Gustafson, Réka; Daly, Patricia; Zerr, Laura; Demlow, S. Ellen; Wong, Jason; Woods, Conan K.; Hogg, Robert S.; Krajden, Mel; Moore, David; Kendall, Perry; Montaner, Julio S. G.; Harrigan, P. Richard

doi:10.1016/s2352-3018(16)00046-1

Cited by 167 publications

(158 citation statements)

References 30 publications

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“…Unfortunately, the time delay between HIV diagnosis/interview and genotype acquisition by the DOHMH (i.e., 6 months in our study, though this delay has shrunk since 2012) represents an impediment to prompt network-based intervention. Point-of-diagnosis-genotyping coupled with real-time genetic network analysis to identify potential transmission partners could help interdict ongoing transmission and target prevention, linkage to care, and treatment more effectively (as recent suggested in [18]).…”

Section: Discussionmentioning

confidence: 99%

Social and Genetic Networks of HIV-1 Transmission in New York City

et al. 2017

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BackgroundSexually transmitted infections spread across contact networks. Partner elicitation and notification are commonly used public health tools to identify, notify, and offer testing to persons linked in these contact networks. For HIV-1, a rapidly evolving pathogen with low per-contact transmission rates, viral genetic sequences are an additional source of data that can be used to infer or refine transmission networks.Methods and FindingsThe New York City Department of Health and Mental Hygiene interviews individuals newly diagnosed with HIV and elicits names of sexual and injection drug using partners. By law, the Department of Health also receives HIV sequences when these individuals enter healthcare and their physicians order resistance testing. Our study used both HIV sequence and partner naming data from 1342 HIV-infected persons in New York City between 2006 and 2012 to infer and compare sexual/drug-use named partner and genetic transmission networks. Using these networks, we determined a range of genetic distance thresholds suitable for identifying potential transmission partners. In 48% of cases, named partners were infected with genetically closely related viruses, compatible with but not necessarily representing or implying, direct transmission. Partner pairs linked through the genetic similarity of their HIV sequences were also linked by naming in 53% of cases. Persons who reported high-risk heterosexual contact were more likely to name at least one partner with a genetically similar virus than those reporting their risk as injection drug use or men who have sex with men.ConclusionsWe analyzed an unprecedentedly large and detailed partner tracing and HIV sequence dataset and determined an empirically justified range of genetic distance thresholds for identifying potential transmission partners. We conclude that genetic linkage provides more reliable evidence for identifying potential transmission partners than partner naming, highlighting the importance and complementarity of both epidemiological and molecular genetic surveillance for characterizing regional HIV-1 epidemics.

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Section: Discussionmentioning

confidence: 99%

Social and Genetic Networks of HIV-1 Transmission in New York City

et al. 2017

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“…Nearly all uses of genetic clustering to infectious diseases have occurred in the context of retrospective studies, in which clusters are identified at a fixed point in time and seldom revisited in subsequent studies. In settings where there is widespread access to routine HIV genotyping, however, it is possible to prospectively track the appearance of new infections in clusters in real time (Little et al 2014; Poon et al 2016). Regardless of the inherent biases of genetic clustering methods, observing a rapid succession of new infections in a predefined cluster may represent an important source of evidence of a localized outbreak.…”

Section: Discussionmentioning

confidence: 99%

“…A sequence was classified as clustered if its shortest patristic distance to another sequence was below the cutoff in 80% or more of the bootstrap trees. This is the same clustering method being used for near real-time monitoring of HIV hotspots in British Columbia, Canada (Poon et al 2016). …”

Section: Evaluation Of Clustering Methodsmentioning

confidence: 99%

“…More recently, there has been a surge of interest in the use of genetic clustering to identify and characterize localized outbreaks of an infectious disease. By detecting subpopulations exposed to high rates of transmission, clustering may potentially facilitate a more impactful and cost-effective deployment of public health resources (Little et al 2014; Novitsky et al 2015; Poon et al 2016), such as point-of-care testing or pre-exposure prophylaxis (Pillay et al 2015). There are now many different genetic clustering methods that have been developed for this purpose, predominantly in the field of HIV (e.g.…”

Section: Introductionmentioning

confidence: 99%

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Impacts and shortcomings of genetic clustering methods for infectious disease outbreaks

Poon

2016

Virus Evol

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For infectious diseases, a genetic cluster is a group of closely related infections that is usually interpreted as representing a recent outbreak of transmission. Genetic clustering methods are becoming increasingly popular for molecular epidemiology, especially in the context of HIV where there is now considerable interest in applying these methods to prioritize groups for public health resources such as pre-exposure prophylaxis. To date, genetic clustering has generally been performed with ad hoc algorithms, only some of which have since been encoded and distributed as free software. These algorithms have seldom been validated on simulated data where clusters are known, and their interpretation and similarities are not transparent to users outside of the field. Here, I provide a brief overview on the development and inter-relationships of genetic clustering methods, and an evaluation of six methods on data simulated under an epidemic model in a risk-structured population. The simulation analysis demonstrates that the majority of clustering methods are systematically biased to detect variation in sampling rates among subpopulations, not variation in transmission rates. I discuss these results in the context of previous work and the implications for public health applications of genetic clustering.

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“…Phylogenetic methods can be used to study HIV transmission networks and hotspots within communities and populations 8–10 and to assess the genetic linkage of specific transmission events. 4,11 In this study, we used phylogenetic and statistical methods to identify genetically-linked partner infections in the HPTN 052 trial, which were the basis of the primary endpoint analysis for this landmark study.…”

Section: Discussionmentioning

confidence: 99%

Treatment as Prevention: Characterization of Partner Infections in the HIV Prevention Trials Network 052 Trial

Eshleman

Hudelson

Redd

et al. 2017

JAIDS Journal of Acquired Immune Deficiency Syndromes

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HIV Prevention Trials Network (HPTN) 052 demonstrated that antiretroviral therapy (ART) prevents HIV transmission in serodiscordant couples. HIV from index-partner pairs was analyzed to determine the genetic linkage status of partner infections. Forty-six infections were classified as linked, indicating that the index was the likely source of the partner’s infection. Lack of viral suppression and higher index viral load were associated with linked infection. Eight linked infections were diagnosed after the index started ART: four near the time of ART initiation and four after ART failure. Linked infections were not observed when the index participant was stably suppressed on ART.

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Near real-time monitoring of HIV transmission hotspots from routine HIV genotyping: an implementation case study

Cited by 167 publications

References 30 publications

Social and Genetic Networks of HIV-1 Transmission in New York City

Social and Genetic Networks of HIV-1 Transmission in New York City

Impacts and shortcomings of genetic clustering methods for infectious disease outbreaks

Treatment as Prevention: Characterization of Partner Infections in the HIV Prevention Trials Network 052 Trial

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