Patient genomes are interpretable only in the context of other genomes. However, privacy concerns over genetic data oftentimes deter individuals from contributing their genomes to scientific studies and prevent researchers from sharing their data with the scientific community. In this talk, I will describe how we can leverage secure multiparty computation techniques from modern cryptography to perform useful scientific computations on genomic data while protecting the privacy of the participants\u27 genomes. In multiple real scenarios, our methods successfully identified the disease-causing genes and even discovered previously unrecognized disease genes, all while keeping nearly all of the participants\u27 most sensitive genomic information private. We believe that our techniques will help make currently restricted data more readily available to the scientific community and enable individuals to contribute their genomes to a study without compromising their personal privacy.
The material from this talk is based on joint works with Gill Bejerano, Bonnie Berger, Johannes A. Birgmeier, Dan Boneh, Hyunghoon Cho, and Karthik A. Jagadeesh

Wu, David

International Journal for Population Data Science

English

ScholarlyCommons@Penn

University of PennsylvaniaScholarlyCommons2018 ADRF Network Research ConferencePresentations ADRF Network Research Conference Presentations11-2018Protecting Patient Privacy in Genomic AnalysisDavid WuStanford UniversityFollow this and additional works at: https://repository.upenn.edu/admindata_conferences_presentations_2018DOI https://doi.org/10.23889/ijpds.v3i5.1046This paper is posted at ScholarlyCommons. https://repository.upenn.edu/admindata_conferences_presentations_2018/28For more information, please contact repository@pobox.upenn.edu.Wu, David, "Protecting Patient Privacy in Genomic Analysis" (2018). 2018 ADRF Network Research Conference Presentations. 28.https://repository.upenn.edu/admindata_conferences_presentations_2018/28Protecting Patient Privacy in Genomic AnalysisAbstractPatient genomes are interpretable only in the context of other genomes. However, privacy concerns overgenetic data oftentimes deter individuals from contributing their genomes to scientific studies and preventresearchers from sharing their data with the scientific community. In this talk, I will describe how we canleverage secure multiparty computation techniques from modern cryptography to perform useful scientificcomputations on genomic data while protecting the privacy of the participants' genomes. In multiple realscenarios, our methods successfully identified the disease-causing genes and even discovered previouslyunrecognized disease genes, all while keeping nearly all of the participants' most sensitive genomicinformation private. We believe that our techniques will help make currently restricted data more readilyavailable to the scientific community and enable individuals to contribute their genomes to a study withoutcompromising their personal privacy.The material from this talk is based on joint works with Gill Bejerano, Bonnie Berger, Johannes A. Birgmeier,Dan Boneh, Hyunghoon Cho, and Karthik A. Jagadeesh.CommentsDOI https://doi.org/10.23889/ijpds.v3i5.1046This presentation is available at ScholarlyCommons: https://repository.upenn.edu/admindata_conferences_presentations_2018/28Protecting Patient Privacy inGenomic AnalysisDavid Wubased on joint works with:Gill Bejerano, Bonnie Berger, Johannes A. Birgmeier,Dan Boneh, Hyunghoon Cho, and Karthik A. JagadeeshThe Era of “Big Data”analytics, recommendationsData Collection and Data BreachesDatabase breaches have become the norm rather than the exception…[Data taken from Vigilante.pw]Genomics in the Era of Big DataSource: Nature, 2014Genome sequencing around $1000!Genomics in the Era of Big DataPrivacy-Preserving GenomicsFinding a tradeoff between functionality and privacyRare Disease DiagnosisPatients with Kabuki SyndromeEach patient has a list of 200-400rare variants over ≈20,000 genesWhat gene causes a specific (rare) disease?Jagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]Rare Disease DiagnosisPatients with Kabuki SyndromeEach patient has a list of 200-400rare variants over ≈20,000 genes01⋮011⋮001⋮100⋮001⋮0A1BGZZZ3Each patient has a vector "where "# = 1 if patient has a rare variant in gene &GeneGoal: Identify gene with most variants across all patientsJagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]Rare Disease DiagnosisPatients with Kabuki SyndromeEach patient has a list of 200-400rare variants over ≈20,000 genes01⋮011⋮001⋮100⋮001⋮0A1BGZZZ3GeneWorks well for Mendelian (monogenic) diseases (estimated to affect ≈10% of individuals)Each patient has a vector "where "# = 1 if patient has a rare variant in gene &Goal: Identify gene with most variants across all patientsJagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]Patients often ingeographically-diverse locationsRare Disease DiagnosisJagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]Trusted PartyQuestion: Can we perform this computation without seeing complete patient genomes?Rare Disease DiagnosisPatients with Kabuki SyndromeEach patient has a list of 200-400rare variants over ≈20,000 genesPatients “secret share” their data with twonon-colluding hospitals! " − !Jagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]Rare Disease DiagnosisPatients with Kabuki SyndromeEach patient has a list of 200-400rare variants over ≈20,000 genesMPC ProtocolPatients “secret share” their data with twonon-colluding hospitalsHospitals run a multiparty computation (MPC) protocol on pooled inputsJagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]Rare Disease DiagnosisPatients with Kabuki SyndromeEach patient has a list of 200-400rare variants over ≈20,000 genesMPC ProtocolTop variants (sorted):KMT2D, COL6A1, FLNBKnown cause of diseaseJagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]Rare Disease DiagnosisPatients with Kabuki SyndromeEach patient has a list of 200-400rare variants over ≈20,000 genesMPC ProtocolTop variants (sorted):KMT2D, COL6A1, FLNBOther variants that the patients possess are kept hiddenJagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]End-to-End Time CommunicationNumber of Patients10 100509.6 s13.7 s15.8 s41.0 MB62.2 MB72.7 MBRare Disease DiagnosisJagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]Experimental benchmarks for identifying causal gene in small disease cohort• Simulated two non-colluding entities with 1 server on East Coast and 1 on West CoastSecure Genome ComputationMPC ProtocolModern cryptographic tools enable useful computations while protecting the privacy of individual genomesSecure Genome ComputationMPC ProtocolModern cryptographic tools enable useful computations while protecting the privacy of individual genomesTechniques apply to generalcomputations over private dataConclusionsProject Website:https://crypto.stanford.edu/~dwu4/genomepriv-project.htmlThank you!• Privacy and functionality are notinherently incompatible• Modern cryptographic tools enable computation on private data• Question: What privacy challenges are there in your area, and what kind of cryptographic tools can we use to address them?

Protecting Patient Privacy in Genomic Analysis

Kosmopolis

University of Pennsylvania
ScholarlyCommons
2018 ADRF Network Research Conference
Presentations ADRF Network Research Conference Presentations
11-2018
Protecting Patient Privacy in Genomic Analysis
David Wu
Stanford University
Follow this and additional works at: https://repository.upenn.edu/
admindata_conferences_presentations_2018
DOI https://doi.org/10.23889/ijpds.v3i5.1046
This paper is posted at ScholarlyCommons. https://repository.upenn.edu/admindata_conferences_presentations_2018/28
For more information, please contact repository@pobox.upenn.edu.
Wu, David, "Protecting Patient Privacy in Genomic Analysis" (2018). 2018 ADRF Network Research Conference Presentations. 28.
https://repository.upenn.edu/admindata_conferences_presentations_2018/28
Protecting Patient Privacy in Genomic Analysis
Abstract
Patient genomes are interpretable only in the context of other genomes. However, privacy concerns over
genetic data oftentimes deter individuals from contributing their genomes to scientific studies and prevent
researchers from sharing their data with the scientific community. In this talk, I will describe how we can
leverage secure multiparty computation techniques from modern cryptography to perform useful scientific
computations on genomic data while protecting the privacy of the participants' genomes. In multiple real
scenarios, our methods successfully identified the disease-causing genes and even discovered previously
unrecognized disease genes, all while keeping nearly all of the participants' most sensitive genomic
information private. We believe that our techniques will help make currently restricted data more readily
available to the scientific community and enable individuals to contribute their genomes to a study without
compromising their personal privacy.
The material from this talk is based on joint works with Gill Bejerano, Bonnie Berger, Johannes A. Birgmeier,
Dan Boneh, Hyunghoon Cho, and Karthik A. Jagadeesh.
Comments
DOI https://doi.org/10.23889/ijpds.v3i5.1046
This presentation is available at ScholarlyCommons: https://repository.upenn.edu/admindata_conferences_presentations_2018/28
Protecting Patient Privacy in
Genomic Analysis
David Wu
based on joint works with:
Gill Bejerano, Bonnie Berger, Johannes A. Birgmeier,
Dan Boneh, Hyunghoon Cho, and Karthik A. Jagadeesh
The Era of “Big Data”
analytics, 
recommendations
Data Collection and Data Breaches
Database breaches have 
become the norm rather 
than the exception…
[Data taken from Vigilante.pw]
Genomics in the Era of Big Data
Source: Nature, 2014
Genome sequencing 
around $1000!
Genomics in the Era of Big Data
Privacy-Preserving Genomics
Finding a tradeoff between functionality and privacy
Rare Disease Diagnosis
Patients with Kabuki Syndrome
Each patient has a list of 200-400
rare variants over ≈20,000 genes
What gene causes a specific (rare) disease?
Jagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]
Rare Disease Diagnosis
Patients with Kabuki Syndrome
Each patient has a list of 200-400
rare variants over ≈20,000 genes
0
1
⋮
0
1
1
⋮
0
0
1
⋮
1
0
0
⋮
0
0
1
⋮
0
A1BG
ZZZ3
Each patient has a vector "
where "# = 1 if patient has 
a rare variant in gene &G
en
e
Goal: Identify gene with 
most variants across all 
patients
Jagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]
Rare Disease Diagnosis
Patients with Kabuki Syndrome
Each patient has a list of 200-400
rare variants over ≈20,000 genes
0
1
⋮
0
1
1
⋮
0
0
1
⋮
1
0
0
⋮
0
0
1
⋮
0
A1BG
ZZZ3
Ge
ne
Works well for Mendelian 
(monogenic) diseases (estimated 
to affect ≈10% of individuals)
Each patient has a vector "
where "# = 1 if patient has 
a rare variant in gene &
Goal: Identify gene with 
most variants across all 
patients
Jagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]
Patients often in
geographically-diverse locations
Rare Disease Diagnosis
Jagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]
Trusted 
Party
Question: Can we perform this 
computation without seeing 
complete patient genomes?
Rare Disease Diagnosis
Patients with Kabuki Syndrome
Each patient has a list of 200-400
rare variants over ≈20,000 genes
Patients “secret share” 
their data with two
non-colluding hospitals
! " − !
Jagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]
Rare Disease Diagnosis
Patients with Kabuki Syndrome
Each patient has a list of 200-400
rare variants over ≈20,000 genes
MPC Protocol
Patients “secret share” 
their data with two
non-colluding hospitals
Hospitals run a multiparty 
computation (MPC) 
protocol on pooled inputs
Jagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]
Rare Disease Diagnosis
Patients with Kabuki Syndrome
Each patient has a list of 200-400
rare variants over ≈20,000 genes
MPC Protocol
Top variants (sorted):
KMT2D, COL6A1, FLNB
Known cause of disease
Jagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]
Rare Disease Diagnosis
Patients with Kabuki Syndrome
Each patient has a list of 200-400
rare variants over ≈20,000 genes
MPC Protocol
Top variants (sorted):
KMT2D, COL6A1, FLNB
Other variants that the 
patients possess are kept 
hidden
Jagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]
End-to-End Time Communication
Number of Patients
10 10050
9.6 s
13.7 s
15.8 s
41.0 MB
62.2 MB
72.7 MB
Rare Disease Diagnosis
Jagadeesh-W-Birgmeier-Boneh-Bejerano [Science 2017]
Experimental benchmarks for identifying causal gene in small disease cohort
• Simulated two non-colluding entities with 1 server on East Coast and 1 on West Coast
Secure Genome Computation
MPC Protocol
Modern cryptographic tools enable useful computations while 
protecting the privacy of individual genomes
Secure Genome Computation
MPC Protocol
Modern cryptographic tools enable useful computations while 
protecting the privacy of individual genomes
Techniques apply to general
computations over private data
Conclusions
Project Website:
https://crypto.stanford.edu/~dwu4/genomepriv-project.html
Thank you!
• Privacy and functionality are not
inherently incompatible
• Modern cryptographic tools enable 
computation on private data
• Question: What privacy challenges 
are there in your area, and what 
kind of cryptographic tools can we 
use to address them?


Patient genomes are interpretable only in the context of other genomes. However, privacy concerns over genetic data oftentimes deter individuals from contributing their genomes to scientific studies and prevent researchers from sharing their data with the scientific community. In this talk, I will describe how we can leverage secure multiparty computation techniques from modern cryptography to perform useful scientific computations on genomic data while protecting the privacy of the participants' genomes. In multiple real scenarios, our methods successfully identified the disease-causing genes and even discovered previously unrecognized disease genes, all while keeping nearly all of the participants' most sensitive genomic information private. We believe that our techniques will help make currently restricted data more readily available to the scientific community and enable individuals to contribute their genomes to a study without compromising their personal privacy.



The material from this talk is based on joint works with Gill Bejerano, Bonnie Berger, Johannes A. Birgmeier, Dan Boneh, Hyunghoon Cho, and Karthik A. Jagadeesh

David Wu

Directory of Open Access Journals

International Journal of Population Data Science (2018) 3:5:05International Journal ofPopulation Data ScienceJournal Website: www.ijpds.orgProtecting Patient Privacy in Genomic AnalysisWu , D1*1Stanford UniversityPatient genomes are interpretable only in the context ofother genomes. However, privacy concerns over genetic dataoftentimes deter individuals from contributing their genomesto scientific studies and prevent researchers from sharing theirdata with the scientific community. In this talk, I will describehow we can leverage secure multiparty computation techniquesfrom modern cryptography to perform useful scientific com-putations on genomic data while protecting the privacy of theparticipants’ genomes. In multiple real scenarios, our methodssuccessfully identified the disease-causing genes and even dis-covered previously unrecognized disease genes, all while keep-ing nearly all of the participants’ most sensitive genomic infor-mation private. We believe that our techniques will help makecurrently restricted data more readily available to the scientificcommunity and enable individuals to contribute their genomesto a study without compromising their personal privacy.The material from this talk is based on joint works with GillBejerano, Bonnie Berger, Johannes A. Birgmeier, Dan Boneh,Hyunghoon Cho, and Karthik A. Jagadeesh.∗Corresponding Author:Email Address: dwu4@cs.stanford.edu (D Wu)http://dx.doi.org/10.23889/ijpds.v3i5.1046November 2018 c© The Authors. Open Access under CC BY-NC-ND 4.0 (https://creativecommons.org/licenses/by-nc-nd/4.0/deed.en)

https://repository.upenn.edu/cgi/viewcontent.cgi?article=1026&amp;context=admindata_conferences_presentations_2018

Protecting Patient Privacy in Genomic Analysis

Abstract

Similar works

Full text

Available Versions

ScholarlyCommons@Penn

Kosmopolis

Directory of Open Access Journals