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eDNA Water Filtration for Biodiversity Surveys

Physical filtration of water samples through membrane filters to capture environmental DNA (cellular, extracellular, and free DNA) from target organisms. Foundational sample-collection technique for eDNA metabarcoding, invasive-species surveillance, threatened-species monitoring, and any environmental biodiversity survey. Uses a vacuum manifold or syringe-based filtration. Works with any filter membrane; 0.45 µm cellulose nitrate or GF/F glass-fibre standard. Written for a novice audience.

sample_prep
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Version History
Version 0.1.1 Latest
Effective: 2026-04-20

Catalog fix (vacuum pump t#43, filter apparatus t#44) bundled. All `procedure N` references converted to Markdown hyperlinks pointing at https://librebiotech.org/?action=show&id=N — enables in-app click-through to referenced sibling procedures. Text content otherwise preserved.

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Version 0.1.0 Viewing
Effective: 2026-04-20

Initial release. Physical filtration technique; procedural facts are field-standard and uncopyrightable. Supports future eDNA content arc (Season 2). Fresh original prose. Catalog gap: vacuum pump + filter apparatus equipment types not yet in LibreBiotech catalog; to be added.
Procedure Details
Safety & Hazards
  • Contamination prevention is paramount. eDNA can be picked up on boots, gloves, equipment — a single contaminated sample can skew an entire biodiversity dataset. Dedicated eDNA-only equipment; bleach decontamination between sites; field negative controls (sterile water filtered identically).
  • Water handling. Treat source water as potentially hazardous (environmental pathogens possible). Gloves; eye protection at minimum; consult local field-safety protocols for unfamiliar water bodies.
  • Vacuum pump electrical safety. Keep water and electrical outlets separated; use ground-fault protection.
  • Filter handling. Filters with captured material should be treated as biologically active material — avoid skin contact; store/dispose per biohazard protocols.
  • Field safety beyond lab scope. Swiftly moving water, boats, wildlife hazards, weather — defer to local field practice.
Preparation Notes

Pre-trip prep:

  • Sterile sample bottles. 1 L HDPE plastic bottles, autoclaved. Label before field departure.
  • Filter assortment. Membrane filters in sterile pouches:
    • 0.45 µm cellulose nitrate (standard for general eDNA)
    • 0.22 µm cellulose nitrate (retains smaller particles; slower filtration)
    • GF/F glass-fibre (good for large-particle water; faster filtration)
  • Filter apparatus. Either: (a) disposable syringe-filter units (Sterivex-GP or similar), or (b) reusable vacuum manifold + funnel + membrane sandwich.
  • Vacuum pump. Hand-operated diaphragm pump for field use; electric pump for lab filtration. Hand pumps work surprisingly well for 1 L samples in 10–15 minutes.
  • Preservation buffer. Longmire buffer (100 mM Tris-HCl pH 8.0 + 100 mM EDTA + 10 mM NaCl + 0.5% SDS). Pre-fill 1.5 mL tubes with 800 µL Longmire; filters go directly in on collection.
  • Ice bucket / dry ice / thermos. For in-transit cold storage of filters until freezer access.
  • Field documentation. GPS unit, notebook, pen; record every sample's location, time, weather, water temperature, turbidity.

Mental model. Water at your field site contains eDNA from every organism that's recently been in/near the water: fish mucus cells, amphibian skin cells, bacterial cells, algal spores, and free DNA from cell lysis. Filtering captures this material on the membrane; subsequent DNA extraction (procedure 80) and PCR amplification (procedure 72) produces taxonomic calls.

Sample volumes:

  • 1 L per sample is standard for most biodiversity surveys.
  • 2 L for oligotrophic / low-biomass water (clear ocean, alpine lakes).
  • 250 mL for turbid / high-biomass water (eutrophic ponds, wastewater).
Timing
  • Per sample on-site (~15 min): collect water, filter, transfer filter to preservation buffer.
  • Batch efficient: 8–10 samples in an afternoon field trip per collector.
  • Storage transit: filters in Longmire stable on ice for 24 h; at −20°C indefinitely.
Equipment (Catalog) 3
  • Micropipette Liquid handling
    Specs: P1000, P200 for preservation-buffer aliquots
    Used lab-side for preservation-buffer prep, not field
  • Biosafety cabinet Safety
    Specs: Class II Type A2 or equivalent
    Lab-side only — for preservation-buffer preparation and filter unpacking
  • Freezer (−20 °C) Storage
    Specs: Standard lab freezer
    For long-term preservation of filters
Materials (Catalog) 1
  • Buffer Reagent
    Qty: 800 µL per filter tube
    100 mM Tris-HCl pH 8.0 + 100 mM EDTA + 10 mM NaCl + 0.5% SDS; stable room temp for months
Protocol Parameters Captured per-assay on each run; exported as ISA-Tab Parameter Value columns
Name Type Required Default Unit Description
sample_volume_mL number 1000 milliliter (UO:0000098) Water volume per sample. 1 L standard; 2 L for low-biomass water; 250 mL for high-biomass / turbid water.
filter_pore_size_um number 0.45 Filter membrane pore size. 0.45 µm standard; 0.22 µm for smaller organisms (bacteria); GF/F (~0.7 µm) for turbid water.
filter_material text cellulose_nitrate Filter material. 'cellulose_nitrate' (general eDNA); 'GF/F' (glass fibre, for high-particle water); 'polycarbonate' (flat surface, image-friendly).
longmire_volume_ul number 800 microliter (UO:0000101) Longmire preservation buffer per filter tube. 800 µL for 1.5 mL tube; 5 mL for 15 mL conical (Sterivex filters).
field_negative_ratio number 1 Number of field negatives per site per day. 1 minimum; 2 recommended for high-contamination-risk sites.
Procedure Steps (Version 0.1.0)

Pre-label sample bottles with: site ID, date, time slot, collector initials. Label one bottle per sample plus one field negative.

At the field site, collect a water sample. Standard: ~20 cm below surface, away from banks, facing upstream if flowing water. Fill bottle to ~1 L (mark the fill line to verify in the field).

For the field negative: pour 1 L of sterile lab water (brought from the lab) into a labelled sample bottle at the same site. Handle identically to the real samples.

Immediately set up the filtration apparatus. For syringe-filter format: draw sample water into a 60 mL syringe; screw on a Sterivex-GP (or equivalent) sterile filter cartridge. For vacuum-manifold format: mount a sterile membrane filter between two halves of the funnel/base; connect to vacuum pump.

Filter the entire 1 L sample through the filter. For syringe: refill and push repeatedly until the whole sample has passed through. For vacuum: apply suction, allowing water to pass through; refill funnel as needed.

Note the filtration time and any filter resistance. If filtration stops before 1 L has passed, record the actual volume filtered. Clogged filters often indicate high biomass samples — note this.

For syringe-filter format: unscrew the Sterivex cartridge. Dry the outer surface with a clean wipe. Use a blunt-tipped tool to transfer the Sterivex directly into a 15 mL conical tube pre-filled with 5 mL Longmire buffer.

For vacuum-manifold format: using sterile forceps, carefully lift the filter from the base, keeping it oriented with captured-material side up. Fold the filter in half, then in half again (material inside). Transfer directly into a 1.5 mL tube pre-filled with 800 µL Longmire buffer.

Cap the tube. Invert gently 3 times to ensure the filter is submerged in preservation buffer. Do NOT vortex — shears DNA prematurely.

Label the preservation tube with the sample identifier. Store on ice during the remainder of the field day; transfer to −20°C within 24 hours.

Decontaminate all non-disposable equipment between samples: bleach-wipe the filtration apparatus; change gloves; rinse sample bottles with sterile water before reuse (or use single-use bottles for critical projects).

Record the collection event in LibreBiotech when back at the lab: Process record for the collection trip; one Sample record per filter, with annotations for GPS coordinates, filter pore size, filtration time, observed turbidity, water temperature, and cross-reference to the field negative collected at the same site.

Completion Notes

Expected outcome. Filter membranes preserved in Longmire buffer, ready for DNA extraction (procedure 80). Each filter represents ~1 L of filtered water from a specific site/time.

Field negative controls (critical).

  • Field negative: 1 L of sterile laboratory water filtered identically at the same site. Catches contamination during field handling.
  • Bottle blank: 1 L of sterile water poured into a sample bottle, carried through the trip, and filtered in the lab. Catches bottle-contamination sources.
  • Minimum one field negative per site, per day.

QC gate. Every downstream eDNA workflow run should verify field negatives don't amplify target sequences. Positive amplification in a field negative invalidates that site's sample set.

Downstream. DNA extraction via procedure 80; qPCR or metabarcoding via procedure 72 + target-specific primers; species call via procedure 76.

Troubleshooting.

Symptom Likely cause Fix
Filtration becomes very slow / stops Filter clogged by sediment / biomass Pre-filter through coarser (1.0 µm) membrane first; reduce sample volume
Contamination in field negatives Cross-contamination during collection Use gloves changed between sites; bleach-wipe bottle exteriors; dedicated eDNA-only equipment
Weak signal in downstream PCR Low biomass; inhibitors in preservation Increase sample volume to 2 L; use different filter membrane (switch cellulose ↔ GF/F)
Filters curl / damage in preservation Too-stiff filter handling with forceps Use smooth-tipped forceps; handle filter by edge only
Preservation buffer frozen before filtration Dry ice transit too cold Store on wet ice only during transport until filtration; freeze after filter added
References
  1. Ficetola GF, Miaud C, Pompanon F, Taberlet P (2008). Species detection using environmental DNA from water samples. Biol Lett 4(4):423–5. (Foundational eDNA from water). DOI paper
  2. Deiner K, Walser JC, Mächler E, Altermatt F (2015). Choice of capture and extraction methods affect detection of freshwater biodiversity from environmental DNA. Biol Conserv 183:53–63. (Filtration method comparison). DOI paper
  3. Thomsen PF, Willerslev E (2015). Environmental DNA — an emerging tool in conservation for monitoring past and present biodiversity. Biol Conserv 183:4–18. (Review). DOI paper
  4. LibreBiotech procedure 80 — eDNA Extraction from Filter Membranes (downstream). Link protocol