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{{BioMicroCenter}}
{{BioMicroCenter}}
 
[[File:SingleCellOptions.png|thumb|right|400px]]
[[File:SingleCellOptions.png|thumb|right|400px]]
The BioMicro Center supports a broad range of methods for single cell sequencing. The choice of method depends heavily on the type of question being asked and the source material. The methods break down into those supporting individual cells characterized in single wells, methods that use droplet isolation and library preparation, and those that support rapid characterization of a modest number of transcripts using in situ sequencing (coming soon). These cell requirements for each method vary significantly so reviewing each method is valuable and we strongly encourage consultation with BMC staff prior to beginning the experiment.
The BioMicro Center supports a broad range of methods for single cell sequencing. The choice of method depends heavily on the type of question being asked and the source material. The methods break down into those supporting individual cells characterized in single wells and methods that use droplet isolation and library preparation. These cell requirements for each method vary significantly so reviewing each method is valuable and we strongly encourage consultation with BMC staff prior to beginning the experiment.
<BR><BR><BR><BR><BR><BR>.
<BR><BR><BR><BR><BR><BR>.
 
 
== 10x CHROMIUM X ==
== 10x CHROMIUM X ==
[[File:25_10xAssays.png|thumb|left|400px]]
[[File:25_10xAssays.png|thumb|left|400px]]
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  |style="width: 450px;"|
  |style="width: 450px;"|
=== scRNAseq / snRNAseq ===
=== scRNAseq / snRNAseq ===
<!-- A "setup" covers the chip, labor, and service contract. For Flex it also includes the GEMs. Samples per setup differ by assay - see Samples per setup row. -->
  {| class="wikitable" border=1
  {| class="wikitable" border=1
   !   
   !   
   ! 3'RNA/5'RNA <BR> (GEM-X)
   ! 3'RNA/5'RNA <BR> (GEM-X)
   ! 3'/5' OnChipMultiplexing <BR> (OCM)
   ! 3'/5' OnChipMultiplexing <BR> (OCM)
   ! Fixed RNA <BR> (Flex GEM-X)
   ! Fixed RNA <BR> (Flex v2 / Apex)
   |-
   |-
   !INPUT  
   !INPUT  
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[https://www.10xgenomics.com/support/universal-three-prime-gene-expression/documentation/steps/sample-prep Freshly counted cells/nuclei in suspension.]
[https://www.10xgenomics.com/support/universal-three-prime-gene-expression/documentation/steps/sample-prep Freshly counted cells/nuclei in suspension.]
   |
   |
[https://www.10xgenomics.com/support/flex-gene-expression/documentation/steps/sample-prep Fixed cells in suspension.]  
[https://www.10xgenomics.com/support/flex-gene-expression/documentation/steps/sample-prep Fixed cells in suspension.] Also supports fresh, frozen, FFPE, fixed whole blood, and flow-sorted cells.
   |-
   |-
   !Cell Concentration <BR><small> cells|nuclei/uL </small>
   !Cell Concentration <BR><small> cells|nuclei/uL </small>
   |100-2000
   |100-2000
   |100-2000
   |100-2000
   |2000+
   |100-2000
   |-
   |-
   ! Fraction Recovered <BR><small> est. percent of input cells captured </small>
   ! Fraction Recovered <BR><small> est. percent of input cells captured </small>
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   | 500-20,000/lane
   | 500-20,000/lane
   | 500-5,000/lane  
   | 500-5,000/lane  
   | 500-10,000/sample
   | up to 20,000/sample
   |-
   |-
   ! Expected doublet rate @ Max load
   ! Expected doublet rate @ Max load
   | 8%
   | 8%
   | 7.5%
   | 7.5%
   | 8% doublet @ 10k
   | 8% doublet @ 20k
   |-
   |-
   !Multiplexing
   ! Samples per setup <BR><small> A setup covers chip, labor, and service contract. Flex also includes GEMs. </small>
   | 1 sample
   | 1-8 samples <BR><small> 8 GEMs per chip </small>
   | 4 samples/library
   | 1-8 samples <BR><small> 4 lanes/batch → 2 GEMs per chip </small>
   | 4 samples/lane
   | up to ~48 samples <BR><small> 1 GEM; ~1M cells captured; ~20k cells/index </small>
   |-
   |-
   !ADD'L AMPLICONS
   !ADD'L AMPLICONS
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   ! KEY NOTES
   ! KEY NOTES
   |
   |
   |
   | Batches of 4 samples
   | Human/Mouse only
   | Human/Mouse only. <BR><small> Probe-based: exogenous sequences (GFP, reporters, etc.) not captured without custom probes. </small>
   |-
   |-
   !SUBMISSION FORMS
   !SUBMISSION FORMS
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   |colspan="3"| [http://mit.edu/manoli/ Prof. Manolis Kellis]
   |colspan="3"| [http://mit.edu/manoli/ Prof. Manolis Kellis]
  |}
  |}
 
=== CHROMATIN ===
=== CHROMATIN ===
  {| class="wikitable" border=1
  {| class="wikitable" border=1
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   |colspan="2"| FASTQ, BAM, 10X QC, loupe file
   |colspan="2"| FASTQ, BAM, 10X QC, loupe file
  |}
  |}
 
|
|
 
=== 10X Genomics ===
=== 10X Genomics ===
[[image:10xX.jpg|thumb|right|500px|10x Chromium X]]
[[image:10xX.jpg|thumb|right|500px|10x Chromium X]]
 
 
FAQs for Users <BR>
FAQs for Users <BR>
'''1) What buffers in the final suspension are compatible with 10X applications?'''  
'''1) What buffers in the final suspension are compatible with 10X applications?'''  
<br>
<br>
[https://kb.10xgenomics.com/hc/en-us/articles/115001937123-What-buffers-can-be-used-for-washing-and-cell-resuspension Buffers/media] for the submitted single cell/nuclei suspension should not contain excessive amounts of EDTA (>0.1 mM) or magnesium (>3 mM) and should be free of surfactants (i.e. Tween-20, SDS etc) and any RNases or DNases.
[https://kb.10xgenomics.com/s/article/115001937123-What-buffers-can-be-used-for-washing-and-cell-resuspension Buffers/media] for the submitted single cell/nuclei suspension should not contain excessive amounts of EDTA (>0.1 mM) or magnesium (>3 mM) and should be free of surfactants (i.e. Tween-20, SDS etc) and any RNases or DNases.
*1xPBS (calcium free and magnesium free) containing 0.04%  weight/volume BSA (400 µg/ml) is recommended for most general protocols and is considered the standard buffer
*1xPBS (calcium free and magnesium free) containing 0.04%  weight/volume BSA (400 µg/ml) is recommended for most general protocols and is considered the standard buffer
*Cell culture media with up to 1% BSA or up to 10% FBS if cells are not viable in standard buffer
*Cell culture media with up to 1% BSA or up to 10% FBS if cells are not viable in standard buffer
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*Nuclei also require addition of RNase Inhibitor along with 10X Genomics 1X nuclei buffer before chip loading, instructions for which are included in 10x user guides. If needed, users can collect buffer aliquots from the BMC after submitting a project. Please coordinate with BMC staff for pick-up. <br>
*Nuclei also require addition of RNase Inhibitor along with 10X Genomics 1X nuclei buffer before chip loading, instructions for which are included in 10x user guides. If needed, users can collect buffer aliquots from the BMC after submitting a project. Please coordinate with BMC staff for pick-up. <br>
'''2) How many cells are captured in the Assay?'''
'''2) How many cells are captured in the Assay?'''
<br>Up to 10,000 cells for NextGEM and 20,000 cells for GEM-X can be uniquely barcoded, but this highly depends on cell counts and viability. Dying cells will leak RNA, hence may not be captured efficiently leading to sample failures. We recommend to count cells at the BMC to avoid discrepancies, but can work with users' counts as well. <BR>
<br>Up to 20,000 cells per GEM can be uniquely barcoded with GEM-X, but this highly depends on cell counts and viability. Dying cells will leak RNA, hence may not be captured efficiently leading to sample failures. We recommend to count cells at the BMC to avoid discrepancies, but can work with users' counts as well. <BR>
'''3) What are the best practices for flow sorting cells? <br>  
'''3) What are the best practices for flow sorting cells?''' <br>  
10x provides guidance with their tested protocols about pre-sort buffer, collection buffer and FACS best practices [https://kb.10xgenomics.com/hc/en-us/articles/360048826911-What-are-the-best-practices-for-flow-sorting-cells-for-10x-Genomics-assays here.] <br>
10x provides guidance with their tested protocols about pre-sort buffer, collection buffer and FACS best practices [https://kb.10xgenomics.com/s/article/360048826911-What-are-the-best-practices-for-flow-sorting-cells-for-10x-Genomics-assays here.] <br>
'''4) What is the expected size distribution for cDNA?''' <br>
'''4) What is the expected size distribution for cDNA?''' <br>
cDNA for 3' and 5' libraries will span between 400 to 9000 base pairs, depending on sample type.
cDNA for 3' and 5' libraries will span between 400 to 9000 base pairs, depending on sample type.
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'''5) How much sequencing per sample is recommended?''' <br>
'''5) How much sequencing per sample is recommended?''' <br>
10x makes several recommendations in their [https://www.10xgenomics.com/support/epi-atac/documentation/steps/sequencing/sequencing-handbook sequencing handbook]. Recommendation numbers vary by sample type, expected CNPs per sample, assay type and general sample quality. The higher the CNPs, the higher the quality, the more likely increased read depth is required. <br>
10x makes several recommendations in their [https://www.10xgenomics.com/support/epi-atac/documentation/steps/sequencing/sequencing-handbook sequencing handbook]. Recommendation numbers vary by sample type, expected CNPs per sample, assay type and general sample quality. The higher the CNPs, the higher the quality, the more likely increased read depth is required. <br>
For more resources, please visit https://kb.10xgenomics.com/hc/en-us <br>
For more resources, please visit https://kb.10xgenomics.com/s/ <br>
|
|
|}
|}
 
== NAMOCELL SINGLE CELL SORTER ==
== NAMOCELL SINGLE CELL SORTER ==
 
{| align=left  
{| align=left  
  |- style="vertical-align: top;"
  |- style="vertical-align: top;"
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  |}
  |}
  |
  |
The [https://www.namocell.com/namo/ Namocell Single Cell Sorter] allows users to sort cells into plates. The sorter uses microfluidics to sort single cells in 1uL of sheath fluid into a well. The instrument uses disposable cartridges to minimize contamination. The instrument integrates well with the [[BioMicroCenter:Tecan_Freedom_Evo#TTP_LABTECH_MOSQUITO_HV|TTP Labtech Mosquito HV]] which handles small reaction volumes. <BR><BR>
[[image:Namo.jpg|thumb|right|Namo (Namocell) Bio-Techne]]
[[image:Namo.jpg|thumb|right|Namo (Namocell) Bio-Techne]]
|
The [https://www.bio-techne.com/brands/namocell Namocell Single Cell Sorter] allows users to sort cells into plates. The sorter uses microfluidics to sort single cells in 1uL of sheath fluid into a well. The instrument uses disposable cartridges to minimize contamination. The instrument integrates well with the [[BioMicroCenter:Tecan_Freedom_Evo#SPT_LABTECH_MOSQUITO_HV|SPT Labtech Mosquito HV]] which handles small reaction volumes. <BR><BR>
|}  
|}  
 
<BR><BR>.
 
 
<!-- AVITI24 high-output DISS (whole transcriptome single cell) section pending - not yet released -->
== AVITI24 IN SITU SEQUENCING ==
*** coming in early 2026 ***
 
The AVITI24 enables direct in situ sequencing of samples, allowing for very rapid characterization of single cells. Cells can be grown or placed on the AVITI24 flowcell and processed. Runs are predicted to produce a few thousand reads plus cytostaining and antibody labeling, all within a day. More information will be released soon.
 
 
<!-- commenting out Seq-Well  
<!-- commenting out Seq-Well  
== SEQ-WELL ==
== SEQ-WELL ==

Latest revision as of 20:29, 24 March 2026

HOME -- SEQUENCING -- LIBRARY PREP -- HIGH-THROUGHPUT -- COMPUTING -- OTHER TECHNOLOGY

The BioMicro Center supports a broad range of methods for single cell sequencing. The choice of method depends heavily on the type of question being asked and the source material. The methods break down into those supporting individual cells characterized in single wells and methods that use droplet isolation and library preparation. These cell requirements for each method vary significantly so reviewing each method is valuable and we strongly encourage consultation with BMC staff prior to beginning the experiment.





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10x CHROMIUM X

The BioMicro Center provides access to 10x Genomics library preparation as an assisted or a walk-up service. Added in 2023, The 10x Chromium X can handle a broad variety of methodologies now including 3', 5' and fixed RNA sequencing, ATAC and multiome Dropoff for assisted service is coordinated with Center staff with at least one week's lead time. Users should bring their single cell/nuclei suspension(s) in 1.5 mL microfuge tubes in the standard buffer at or around that time. Staff works with the user to intake the initial samples and proceed through the protocol with quality control checks at the appropriate steps.

Chromium X usage is also offered as a walkup service. Usage may be scheduled on the iLabs calendar after training by BMC staff. This still requires at least a week's lead time before usage. You will not have permission to schedule the equipment until you have been approved by BMC staff. Reagents are stocked in the BioMicro Center and we ask that you use our reagents. This allows us to get larger bulk discounts we can pass on to our users. Please note that we do include a fraction of the instrument usage cost in the cost of the chips and will charge this cost if you use your own chips.

The full 10x suite of software is installed on LURIA and is integrated into our analysis package.

scRNAseq / snRNAseq

3'RNA/5'RNA
(GEM-X) 		3'/5' OnChipMultiplexing
(OCM) 		Fixed RNA
(Flex v2 / Apex)
INPUT

Freshly counted cells/nuclei in suspension.

Fixed cells in suspension. Also supports fresh, frozen, FFPE, fixed whole blood, and flow-sorted cells.

nuclei/uL 100-2000 100-2000 100-2000
Fraction Recovered
est. percent of input cells captured 		~65% ~60% ~50%
Target recovery
multiply by recovery for input 		500-20,000/lane 500-5,000/lane up to 20,000/sample
Expected doublet rate @ Max load 8% 7.5% 8% doublet @ 20k
Samples per setup
A setup covers chip, labor, and service contract. Flex also includes GEMs. 		1-8 samples
8 GEMs per chip 		1-8 samples
4 lanes/batch → 2 GEMs per chip 		up to ~48 samples
1 GEM; ~1M cells captured; ~20k cells/index
ADD'L AMPLICONS

Custom priming for CITEseq, CRISPRs (perturb-seq), TCR (5'), BCR (5').
Please provide custom oligos and protocols to core.

Additional genes require new probes.

KEY NOTES Batches of 4 samples Human/Mouse only.
Probe-based: exogenous sequences (GFP, reporters, etc.) not captured without custom probes.
SUBMISSION FORMS ASSISTED - ilabs WALKUP - Calendar
DELIVERY FASTQ, SAM, BAM, 10X QC, loupe file
DONATED BY Prof. Manolis Kellis

CHROMATIN

snATACseq multiome
Input
  • 160-8,000 nuclei/uL
  • 50% estimated recovery
  • 7.5% doublets @ 10k cells recovered
  • 10uL minimum volume
Multiplexing Not available
SUBMISSION FORMS ASSISTED - ilabs WALKUP - Calendar
DELIVERY FASTQ, BAM, 10X QC, loupe file

10X Genomics

10x Chromium X


FAQs for Users
1) What buffers in the final suspension are compatible with 10X applications?
Buffers/media for the submitted single cell/nuclei suspension should not contain excessive amounts of EDTA (>0.1 mM) or magnesium (>3 mM) and should be free of surfactants (i.e. Tween-20, SDS etc) and any RNases or DNases.

  • 1xPBS (calcium free and magnesium free) containing 0.04% weight/volume BSA (400 µg/ml) is recommended for most general protocols and is considered the standard buffer
  • Cell culture media with up to 1% BSA or up to 10% FBS if cells are not viable in standard buffer
  • 1xPBS (calcium free and magnesium free) containing up to 10% FBS for CMO labelling
  • Nuclei also require addition of RNase Inhibitor along with 10X Genomics 1X nuclei buffer before chip loading, instructions for which are included in 10x user guides. If needed, users can collect buffer aliquots from the BMC after submitting a project. Please coordinate with BMC staff for pick-up.

2) How many cells are captured in the Assay?
Up to 20,000 cells per GEM can be uniquely barcoded with GEM-X, but this highly depends on cell counts and viability. Dying cells will leak RNA, hence may not be captured efficiently leading to sample failures. We recommend to count cells at the BMC to avoid discrepancies, but can work with users' counts as well.
3) What are the best practices for flow sorting cells?
10x provides guidance with their tested protocols about pre-sort buffer, collection buffer and FACS best practices here.
4) What is the expected size distribution for cDNA?
cDNA for 3' and 5' libraries will span between 400 to 9000 base pairs, depending on sample type.
5) How much sequencing per sample is recommended?
10x makes several recommendations in their sequencing handbook. Recommendation numbers vary by sample type, expected CNPs per sample, assay type and general sample quality. The higher the CNPs, the higher the quality, the more likely increased read depth is required.
For more resources, please visit https://kb.10xgenomics.com/s/

NAMOCELL SINGLE CELL SORTER

INSTRUMENT NAMOCELL SINGLE CELL SORTER
TYPE WALKUP - MIT only
FACS
UNIT Per Cartridge
LASER WAVELENGTH 488 nm
DETECTION CHANNELS
  • FL1 533 nm (FITC/GFP)
  • FL2 585 nm (PE/PI)
  • FL3 676 nm (PerCP)
DISPENSE VOLUME 1 ul
SAMPLE VOLUME 100-750 ul
CELL INPUT single cell mode: 100-10,000 cells
FORMAT 96w/384w
SIGNUP ILABS
NEW USERS New users should request training by emailing biomicro@mit.edu
DONATED BY Prof Linda Griffith
Namo (Namocell) Bio-Techne

The Namocell Single Cell Sorter allows users to sort cells into plates. The sorter uses microfluidics to sort single cells in 1uL of sheath fluid into a well. The instrument uses disposable cartridges to minimize contamination. The instrument integrates well with the SPT Labtech Mosquito HV which handles small reaction volumes.



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