How to sequence your own DNA at home

A comprehensive, step-by-step guide and personal account of sequencing a personal genome at home using the Oxford Nanopore MinION sequencer.
I have now sequenced my own genome 5 times with an Oxford Nanopore Technologies MinION. This means collecting them from a swab, prepping them for sequencing, running them through a sequencer, then doing analysis over them.
Cheek cells are easily accessible and replenish pretty quickly. They are not used for cancer diagnosis, inflammation, or what genes are being activated in other parts of the body (like if you have hives on your chest and want to test what genes are being expressed in the cells that are inflamed), since you would want to collect the cells having problems and compare them against other normal versions of those cells.
To sequence the cells, I bought lab materials and consumables to sequence my own genome at home. It took me about two months to get everything together to do a full end to end high quality run. Likewise, the costs are still out of reach for the average person but they are decreasing (exponentially!) and we will eventually have affordable technology, like a cell phone or AI, telling us about our DNA + RNA expression real-time.
What can I even do with my own genome?
Before we actually spend all this time and money on sequencing, what can we actually do with our genome?
The genome is not magic by itself- it is the reference layer. Once I have a VCF, I can run it through tools like VEP, ClinVar, gnomAD, PharmGKB (highly recommend), Gene Inspector, or Claude, and start asking:
- Which variants do I have?
- Which genes and pathways are affected?
- Which medicines might I metabolize differently?
- What rare variants should I take seriously?
- Where does the model know nothing yet?
This last part matters- the information produced is not yet diagnosis-level, and it is definitely not “edit yourself with CRISPR because an AI said so.” The near-term value is turning a static genome into something queryable, but the “edit yourself with CRISPR” will most likely follow. DNA is the stable reference, RNA is the current state, and we will eventually integrate all biosensor data into one ‘model’ of yourself.
Here are a list of links and Twitter posts to help:
- Genetic variants from first principles:
- TLDR these genes, and the combinations of them, compound into real physical diseases. We will probably map these in the next decade
- Pass your genome + RNA to any of these models: https://www.biotender.online/bio-model-install-guide/
- Give your genome to Claude Code- message me if you want me to set this up for you
- Take it to a doctor if you metabolize particular drugs differently
- Patrick Collison post on using agents to talk to his genome
Protocol Steps
This is intended to be read by AI- please just copy and paste the URL of this and have ChatGPT walk you through it. If you have AR glasses, even better, since the AI can walk you through the whole protocol.
Hardware
- Oxford Nanopore Technologies MinION ($7.5k)
- Laptop/workstation for MinKNOW (any PC should be fine)
- 100GB+ storage for outputs
- GPU for Dorado basecalling
- Vortex ($50)
- Heat block ($250)
- Centrifuge ($400 used on eBay)
Consumables
- SQK-LSK114 Ligation Sequencing Kit V14 for DNA
- EXP-WSH004 Flow Cell Wash Kit
- EXP-CTL001 Control material
- PBS 1x
- Isohelix Buccal swabs
Reagents
- DNA extraction kit
- NEB Monarch HMW DNA Extraction Kit for Cells & Blood ($87 for 5 runs)
- Nuclei Prep Buffer
- Nuclei Lysis Buffer
- RNase A
- Proteinase K
- Precipitation Enhancer
- DNA Capture Beads
- gDNA Wash Buffer
- Elution Buffer II
- Bead retainers / Monarch collection parts from kit
- DNA library-prep reagents
- NEBNext Companion Module v2 / repair-end prep reagents ($760 for 24 reactions)
- FFPE DNA Repair Buffer
- FFPE DNA Repair Mix
- Ultra II End-prep Reaction Buffer
- Ultra II End-prep Enzyme Mix
- NEBNext Quick T4 DNA Ligase
- Oxford Nanopore SQK-LSK114 ($720 for 6 reactions)
- Long Fragment Buffer / LFB
- Elution Buffer / EB
- Ligation Adapter / LA
- Ligation Buffer / LNB
- Sequencing Buffer / SB
- Library Beads / LIB
- Flow cell priming reagents
- Flow Cell Flush / FCF
- Flow Cell Tether / FCT
- BSA
- AMPure XP beads
- 80% ethanol
- Nuclease-free water ($32 for 25mL)
- DNA quantity measurement
- Qubit fluorometer
- Qubit dsDNA BR or HS Assay Kit
Bench equipment
- Microcentrifuge
- Vortex mixer
- Heat block / dry bath
- Magnetic rack for 1.5/2 mL tubes
- Tube racks
- Ice bucket / cold block
- Freezer at -20°C
- Fridge at 4°C
- Pipettes
Plastics / Lab Pro-style consumables
- Sterile flocked cheek swabs
- 1.5 mL microcentrifuge tubes
- 2.0 mL microcentrifuge tubes
- DNA LoBind 1.5 mL tubes
- RNA LoBind tubes
- 0.2 mL PCR tubes
- Qubit assay tubes
- Pipette sterile filtered tips
- Wide-bore P200 tips
- Tube labels / lab marker
- Gloves
Software stack
- MinKNOW
- Dorado
- minimap2
- samtools
- mosdepth
- NanoPlot or pycoQC
- Clair3
- DeepVariant, optional
- Ensembl VEP
- ClinVar
- gnomAD
- PharmGKB
- dbSNP, optional
- Python/R
- SQLite/Postgres for query layer later
End-to-end DNA sequencing protocol
The goal is to go from 2 cheek-swab samples → MinION sequencing
0. Setup
- Gloves on.
- Clean bench.
- Label tubes:
Cheek sample
Extracted DNA
End-prep
Ligation
Final library
Priming mix
Loading mix
-
Bring AMPure XP beads to room temperature.
-
Keep enzyme mixes cold.
-
Set heat block to 56°C.
-
Keep Nuclei Prep Buffer cold.
-
Confirm gDNA Wash Buffer already has ethanol added.
-
Confirm you have isopropanol for DNA binding.
-
Confirm you have fresh 80% ethanol for AMPure cleanup.
-
Confirm you have the corrected ONT reagents:
-
FFPE DNA Repair Buffer v2
-
FFPE DNA Repair Mix
-
N-Prep Enzyme Mix
-
Salt-T4 DNA Ligase
-
LNB
-
LA
-
LFB
-
EB
-
SB
-
LIB
-
FCF
-
FCT
1. Collect cheek cells
Goal: get as much cheek-cell material as possible into PBS.
- Rinse mouth with water.
- Wait 10 minutes.
- Do not brush teeth.
- Do not use mouthwash.
- Scrape inside cheek firmly for 60 seconds.
- Add 1 mL cold PBS to labeled tube.
- Put swab head into PBS.
- Vortex 10 seconds.
- Press swab against tube wall to squeeze liquid out.
- Remove and discard swab.
What good looks like:
PBS may look slightly cloudy.
2. Pellet cheek cells
Goal: concentrate cells and remove excess PBS.
- Spin at 2,000 × g for 30 seconds.
- Look for a small white/off-white pellet or smear.
- Remove most PBS with P1000.
- Remove more PBS carefully with P200.
- Leave 50–100 µL above the pellet.
- Flick gently to resuspend the pellet.
Do not aspirate the pellet.
3. Prepare Monarch lysis solutions for one sample
Nuclei Prep Solution
165 µL Nuclei Prep Buffer
5.5 µL RNase A
Mix gently. Keep cold.
You will use 150 µL.
Nuclei Lysis Solution
165 µL Nuclei Lysis Buffer
11 µL Proteinase K
Mix gently. Keep at room temperature.
You will use 150 µL.
The extra volume is intentional so pipetting error does not leave you short.
4. Lyse cells
Goal: break open cells and digest proteins while preserving long genomic DNA.
- Add 150 µL Nuclei Prep Solution to the resuspended cheek-cell pellet.
- Pipette up/down gently 10 times.
- Incubate 2 minutes at room temperature.
- Add 150 µL Nuclei Lysis Solution.
- Invert tube gently 10 times.
- Do not vortex.
- Incubate at 56°C for 10 minutes.
What good looks like:
The liquid may become more viscous.
Do not vortex after lysis. At this point, the priority is preserving high molecular weight DNA.
5. Bind DNA to Monarch capture beads
Goal: precipitate genomic DNA onto the large Monarch capture beads.
- Add 75 µL Precipitation Enhancer.
- Invert gently 8–10 times.
- Add 2 DNA Capture Beads.
- Add 275 µL isopropanol.
- Invert slowly 30 times.
- Do not vortex.
Important:
The beads now carry the DNA.
Do not lose the beads.
Do not use ethanol here.
6. Wash DNA-bound beads
Goal: wash contaminants away while keeping DNA bound to the capture beads.
- Let beads settle briefly.
- Remove liquid carefully without removing beads.
- Add 500 µL gDNA Wa
Source: Hacker News
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