Magnetically Functionalized Hydrogels for High-Throughput Genomic Applications

Evan Lammertse; Siran Li; Jude Kendall; Catherine Kim; Patrick Morris; Nissim Ranade; Dan Levy; Michael Wigler; Eric Brouzes

doi:10.1002/admt.202301155

Magnetically Functionalized Hydrogels for High-Throughput Genomic Applications

Evan Lammertse
, Siran Li
, Jude Kendall
, Catherine Kim
, Patrick Morris
, Nissim Ranade
, Dan Levy
, Michael Wigler
, Eric Brouzes

Biomedical Engineering

Stony Brook University
Cold Spring Harbor Laboratory

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Single-cell genomics has revolutionized tissue analysis by revealing the genetic program of individual cells. The key aspect of the technology is the use of barcoded beads to unambiguously tag sequences originating from a single cell. The generation of unique barcodes on beads is mainly achieved by split–pooling methods, which are labor-intensive due to repeated washing steps. Toward the automation of the split–pooling method, a simple method to magnetize hydrogel beads is developed. The results show that these hydrogel beads provide increased yields and washing efficiencies for purification procedures. They are also fully compatible with single-cell sequencing using the BAG-seq workflow. The work opens the automation of the split–pooling technique, which will improve single-cell genomic workflows.

Original language	English
Article number	2301155
Journal	Advanced Materials Technologies
Volume	9
Issue number	2
DOIs	https://doi.org/10.1002/admt.202301155
State	Published - Jan 22 2024

Keywords

BAG-seq
automation
droplet microfluidics
magnetic separation
single-cell genomics
split–pooling

Access to Document

10.1002/admt.202301155

Cite this

@article{d9b14107acc24b6babc967f06f272f2a,

title = "Magnetically Functionalized Hydrogels for High-Throughput Genomic Applications",

abstract = "Single-cell genomics has revolutionized tissue analysis by revealing the genetic program of individual cells. The key aspect of the technology is the use of barcoded beads to unambiguously tag sequences originating from a single cell. The generation of unique barcodes on beads is mainly achieved by split–pooling methods, which are labor-intensive due to repeated washing steps. Toward the automation of the split–pooling method, a simple method to magnetize hydrogel beads is developed. The results show that these hydrogel beads provide increased yields and washing efficiencies for purification procedures. They are also fully compatible with single-cell sequencing using the BAG-seq workflow. The work opens the automation of the split–pooling technique, which will improve single-cell genomic workflows.",

keywords = "BAG-seq, automation, droplet microfluidics, magnetic separation, single-cell genomics, split–pooling",

author = "Evan Lammertse and Siran Li and Jude Kendall and Catherine Kim and Patrick Morris and Nissim Ranade and Dan Levy and Michael Wigler and Eric Brouzes",

note = "Publisher Copyright: {\textcopyright} 2023 Wiley-VCH GmbH.",

year = "2024",

month = jan,

day = "22",

doi = "10.1002/admt.202301155",

language = "English",

volume = "9",

journal = "Advanced Materials Technologies",

issn = "2365-709X",

number = "2",

}

TY - JOUR

T1 - Magnetically Functionalized Hydrogels for High-Throughput Genomic Applications

AU - Lammertse, Evan

AU - Li, Siran

AU - Kendall, Jude

AU - Kim, Catherine

AU - Morris, Patrick

AU - Ranade, Nissim

AU - Levy, Dan

AU - Wigler, Michael

AU - Brouzes, Eric

PY - 2024/1/22

Y1 - 2024/1/22

N2 - Single-cell genomics has revolutionized tissue analysis by revealing the genetic program of individual cells. The key aspect of the technology is the use of barcoded beads to unambiguously tag sequences originating from a single cell. The generation of unique barcodes on beads is mainly achieved by split–pooling methods, which are labor-intensive due to repeated washing steps. Toward the automation of the split–pooling method, a simple method to magnetize hydrogel beads is developed. The results show that these hydrogel beads provide increased yields and washing efficiencies for purification procedures. They are also fully compatible with single-cell sequencing using the BAG-seq workflow. The work opens the automation of the split–pooling technique, which will improve single-cell genomic workflows.

AB - Single-cell genomics has revolutionized tissue analysis by revealing the genetic program of individual cells. The key aspect of the technology is the use of barcoded beads to unambiguously tag sequences originating from a single cell. The generation of unique barcodes on beads is mainly achieved by split–pooling methods, which are labor-intensive due to repeated washing steps. Toward the automation of the split–pooling method, a simple method to magnetize hydrogel beads is developed. The results show that these hydrogel beads provide increased yields and washing efficiencies for purification procedures. They are also fully compatible with single-cell sequencing using the BAG-seq workflow. The work opens the automation of the split–pooling technique, which will improve single-cell genomic workflows.

KW - BAG-seq

KW - automation

KW - droplet microfluidics

KW - magnetic separation

KW - single-cell genomics

KW - split–pooling

UR - https://www.scopus.com/pages/publications/85179678302

U2 - 10.1002/admt.202301155

DO - 10.1002/admt.202301155

M3 - Article

AN - SCOPUS:85179678302

SN - 2365-709X

VL - 9

JO - Advanced Materials Technologies

JF - Advanced Materials Technologies

IS - 2

M1 - 2301155

ER -

Magnetically Functionalized Hydrogels for High-Throughput Genomic Applications

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this