Nima Hejazi

Nima Hejazi

PhD Candidate in Biostatistics

University of California, Berkeley

Nima Hejazi's GitHub Activity

Biography

I am a PhD candidate in Biostatistics, working jointly with Mark van der Laan and Alan Hubbard. I am a founding core developer of the tlverse project, the software ecosystem for Targeted Learning. At UC Berkeley, I am affiliated with the Center for Computational Biology and the NIH Biomedical Big Data initiative. I have also enjoyed serving in scientific/statistical collaborations with the Bill & Melinda Gates Foundation, the Kaiser Permanente Division of Research, and the Fred Hutchinson Cancer Research Center.

My research interests sit primarily at the intersection of causal inference and machine learning, with a particular concern towards developing efficient and robust statistical procedures for evaluating complex target estimands within observational studies and randomized trials. Broadly, my work draws on ideas from non/semi-parametric estimation in large, flexible statistical models; high-dimensional inference; targeted loss-based estimation; statistical computing; computational biology; and statistical epidemiology. Of late, my methodological work has touched on causal mediation analysis, stochastic treatment regimes, robust inference in two-phase designs, and efficient estimation with sieve-type methods. I am also quite keenly interested in designing open source statistical software to promote computational reproducibility in applied scientific practice.

Interests

  • Causal Inference and Censored Data Models
  • Nonparametric Estimation and Machine Learning
  • Semiparametric Theory and Robust Statistics
  • High-Dimensional and Computational Biology
  • Statistical Computing and Reproducible Research

Education

  • PhD in Biostatistics (designated emphasis in Computational and Genomic Biology), 2017-present

    University of California, Berkeley

  • MA in Biostatistics, 2017

    University of California, Berkeley

  • BA with a triple major in Molecular and Cell Biology (em. Neurobiology), Psychology, and Public Health, 2015

    University of California, Berkeley

Featured Publications

Jeremy Coyle, Nima Hejazi, Ivana Malenica, Rachael Phillips, Benjamin Arnold, Andrew Mertens, Jade Benjamin-Chung, Weixin Cai, Sonali Dayal, John Colford Jr., Alan Hubbard, Mark van der Laan
June 2020

Targeted Learning: robust statistics for reproducible research

Targeted Learning is a subfield of statistics that unifies advances in causal inference, machine learning and statistical theory to help answer scientifically impactful questions with statistical confidence. Targeted Learning is driven by complex problems in data science and has been implemented in a diversity of real-world scenarios: observational studies with missing treatments and outcomes, personalized interventions, longitudinal settings with time-varying treatment regimes, survival analysis, adaptive randomized trials, mediation analysis, and networks of connected subjects. In contrast to the (mis)application of restrictive modeling strategies that dominate the current practice of statistics, Targeted Learning establishes a principled standard for statistical estimation and inference (i.e., confidence intervals and p-values). This multiply robust approach is accompanied by a guiding roadmap and a burgeoning software ecosystem, both of which provide guidance on the construction of estimators optimized to best answer the motivating question. The roadmap of Targeted Learning emphasizes tailoring statistical procedures so as to minimize their assumptions, carefully grounding them only in the scientific knowledge available. The end result is a framework that honestly reflects the uncertainty in both the background knowledge and the available data in order to draw reliable conclusions from statistical analyses - ultimately enhancing the reproducibility and rigor of scientific findings.
Preprint Code
Nima Hejazi, Mark van der Laan, Holly Janes, Peter Gilbert, David Benkeser
April 2020

Efficient nonparametric inference on the effects of stochastic interventions under two-phase sampling, with applications to vaccine efficacy trials

The advent and subsequent widespread availability of preventive vaccines has altered the course of public health over the past century. Despite this success, effective vaccines to prevent many high-burden diseases, including HIV, have been slow to develop. Vaccine development can be aided by the identification of immune response markers that serve as effective surrogates for clinically significant infection or disease endpoints. However, measuring immune response is often costly, which has motivated the usage of two-phase sampling for immune response sampling in clinical trials of preventive vaccines. In such trials, measurement of immunological markers is performed on a subset of trial participants, where enrollment in this second phase is potentially contingent on the observed study outcome and other participant-level information. We propose nonparametric methodology for efficiently estimating a counterfactual parameter that quantifies the impact of a given immune response marker on the subsequent probability of infection. Along the way, we fill in a theoretical gap pertaining to the asymptotic behavior of nonparametric efficient estimators in the context of two-phase sampling, including a multiple robustness property enjoyed by our estimators. Techniques for constructing confidence intervals and hypothesis tests are presented, and an open source software implementation of the methodology, the txshift R package, is introduced. We illustrate the proposed techniques using data from a recent preventive HIV vaccine efficacy trial.
Preprint Code Project Slides
Iván Díaz, Nima Hejazi
February 2020 In Journal of the Royal Statistical Society, Series B (Statistical Methodology)

Causal mediation analysis for stochastic interventions

Mediation analysis in causal inference has traditionally focused on binary treatment regimes and deterministic interventions, as well as a decomposition of the average treatment effect in terms of direct and indirect effects. In this paper we present an analogous decomposition of the population intervention effect, defined through stochastic interventions. Population intervention effects provide a generalized framework in which a variety of interesting causal contrasts can be defined, including effects for continuous and categorical exposures. We show that identification of direct and indirect effects for the population intervention effect requires weaker assumptions than its average treatment effect counterpart. In particular, identification of direct effects is guaranteed in experiments that randomize the treatment and the mediator. We discuss various estimators of the direct and indirect effects, including substitution, re-weighted, and efficient estimators based on flexible regression techniques. Our efficient estimator is asymptotically linear under a condition requiring $n^{\frac{1}{4}}$-consistency of certain regression functions. We perform a simulation study in which we assess the finite-sample properties of our proposed estimators. We present the results of an illustrative study where we assess the effect of participation in a sports team on BMI among children, using mediators such as exercise habits, daily consumption of snacks, and overweight status.
Preprint PDF Code Project Project DOI

Recent Publications

(see CV for a full list)

Quickly discover relevant content by filtering publications.
Jeremy Coyle, Nima Hejazi, Ivana Malenica, Rachael Phillips, Benjamin Arnold, Andrew Mertens, Jade Benjamin-Chung, Weixin Cai, Sonali Dayal, John Colford Jr., Alan Hubbard, Mark van der Laan (2020). Targeted Learning: robust statistics for reproducible research.

Preprint Code

Ashkan Ertefaie, Nima Hejazi, Mark van der Laan (2020). Nonparametric inverse probability weighted estimators based on the highly adaptive lasso.

Preprint Project

Nima Hejazi, Mark van der Laan, Holly Janes, Peter Gilbert, David Benkeser (2020). Efficient nonparametric inference on the effects of stochastic interventions under two-phase sampling, with applications to vaccine efficacy trials.

Preprint Code Project Slides

Philippe Boileau, Nima Hejazi, Sandrine Dudoit (2020). Exploring high-dimensional biological data with sparse contrastive principal component analysis. In Bioinformatics.

Preprint PDF Code Project DOI

Philippe Boileau, Nima Hejazi, Sandrine Dudoit (2020). scPCA: A toolbox for sparse contrastive principal component analysis in R. In Journal of Open Source Software.

PDF Code Project Source Document DOI

See all publications

Recent & Upcoming Talks

Nonparametric Causal Mediation Analysis for Stochastic Interventions
Wed, Apr 29, 2020 1:30 PM Berkeley, California, United States
Generalized Variance Moderation for Locally Efficient Estimation in High-Dimensional Biology
Tue, Jun 25, 2019 11:00 AM New York, New York, United States
Robust Inference on the Causal Effects of Stochastic Interventions Under Two-Phase Sampling, with Applications in Vaccine Efficacy Trials
Thu, Mar 21, 2019 3:00 PM Berkeley, California, United States
Towards the Realistic, Robust, and Efficient Assessment of Causal Effects with Stochastic Shift Interventions
Fri, Sep 14, 2018 10:00 AM Berkeley, California, United States
Fair Inference Through Semiparametric-Efficient Estimation Over Constraint-Specific Paths
Thu, Aug 2, 2018 8:30 AM Vancouver, British Columbia, Canada
See all talks

Teaching

current courses

  • None for now. Check back later.

past courses

recent workshops

Carpentries workshops

I am an member of Software Carpentry and Data Carpentry, through which I work on curriculum development, maintenance of lesson materials, and workshop delivery.

Software

Collected collateral damage from doing statistics research, hopefully useful to others.

Targeted Learning and the tlverse

The tlverse is an ecosystem of R packages for Targeted Learning, of which I am a co-founder and core developer. A few of the tlverse packages to which I’ve made significant contributions include

Causal Inference with Machine Learning

A significant focus of my research program centers on the intersection of causal inference and statistical machine learning. I’ve (co-)developed R packages for a range of problems: causal mediation analysis, evaluating stochastic interventions under two-phase sampling, conditional density estimation, and survival analysis.

  • medshift: An R package for estimating the population intervention (in)direct effects based on stochastic interventions. Classical and efficient estimators are supported for the effects of incremental propensity score interventions and modified treatment policies. Joint work with Iván Díaz.
    [Docs] | [GitHub]

  • medoutcon: An R package for efficient estimation of interventional (in)direct effects subject to intermediate confounding, including one-step and targeted minimum loss estimators. Joint work with Iván Díaz and Kara Rudolph.
    [Docs] | [GitHub]

  • txshift: An R package for efficient estimation of and inference on causal effects of stochastic interventions on continuous-valued exposures. Robust estimation and efficient inference under two-phased sampling is supported. Joint work with David Benkeser.
    [Docs] | [GitHub]

  • haldensify: An R package for nonparametric conditional density estimation based on the highly adaptive lasso, designed for estimating the generalized propensity score. Joint work with David Benkeser and Mark van der Laan.
    [Docs] | [GitHub] | [CRAN]

  • survtmle: An R package for the construction of targeted maximum likelihood estimates of marginal cumulative incidence in right-censored survival settings with and without competing risks, including estimation procedures that respect bounds. Joint work with David Benkeser.
    [Docs] | [GitHub] | [CRAN]

Computational Biology and Bioconductor

A parallel thread of my research concerns the development of novel statistical methodologies for application in high-dimensional and computational biology settings. Consequently, I have (co-)developed several R packages extending the Bioconductor Project.

Miscellaneous

Projects

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All Causal Inference Biostatistics Targeted Learning Miscellany
The Highly Adaptive Lasso
Contrastive Covariance Methods
Causal Mediation Analysis
Causal Effects of Stochastic Interventions
Semiparametric Variance Moderation
Distractions
The PhD Years

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