Calculate dilutions for DNA, RNA, and primer solutions. Supports mass/volume, molar concentration, serial dilution, and PCR master mix calculations.
The DNA Dilution Calculator helps molecular biology researchers prepare precise dilutions of DNA, RNA, primers, and other nucleic acid solutions. It handles mass concentration (ng/µL) to volume calculations, molar conversions using fragment length, serial dilution series, and PCR master mix volumes.
The fundamental dilution equation is C₁V₁ = C₂V₂: Stock concentration × Stock volume = Final concentration × Final volume. For nucleic acids, additional conversions are needed: ng/µL to nM requires the molecular weight, which depends on the number of base pairs (MW ≈ 660 g/mol × bp for dsDNA, 330 g/mol × nt for ssDNA/RNA).
Enter your stock concentration, desired final concentration, and final volume to calculate how much stock solution and diluent to add. Use the serial dilution mode for standard curves and the PCR mode for reaction setup. It is a quick check before you pipette anything. That can prevent wasting samples or making a dilute mix by mistake.
Use this calculator when you need a dilution plan that is precise enough for PCR, cloning, sequencing, or standards preparation. It is especially useful for converting between mass concentration and molarity, avoiding sub-microliter pipetting, and laying out serial dilutions cleanly. That keeps the setup practical as well as exact. It also makes the pipetting steps easier to follow at the bench.
Dilution: C₁V₁ = C₂V₂ → V₁ = C₂ × V₂ / C₁. Diluent = V₂ - V₁. ng/µL to nM: nM = (ng/µL × 10⁶) / (MW × 1000). dsDNA MW = 660 × bp. ssDNA MW = 330 × nt. Serial Dilution: Cₙ = C₀ / (DF)ⁿ. Copy Number: copies/µL = (ng/µL × 6.022×10²³) / (MW × 10⁹).
Result: Add 2.5 µL stock + 47.5 µL diluent = 50 µL at 10 ng/µL
V₁ = (10 × 50) / 200 = 2.5 µL of stock solution. Diluent = 50 - 2.5 = 47.5 µL TE buffer or water. This yields 50 µL of 10 ng/µL DNA. For 5000bp dsDNA: 10 ng/µL = 3.03 nM = 1.82 × 10⁹ copies/µL.
Mass concentration (ng/µL) describes how much DNA is present by weight. Molar concentration (nM) describes the number of molecules. Converting between them requires knowing the molecular weight, which depends on fragment size. A 100bp fragment at 1 ng/µL is at much higher molar concentration than a 10,000bp fragment at 1 ng/µL — there are 100× more molecules of the shorter fragment.
For primer design: primers are typically 20-25 nt ssDNA oligos. At 10 µM working concentration with MW ≈ 7,500 g/mol, that's about 75 ng/µL.
A standard curve for qPCR typically uses 5-7 points spanning the expected dynamic range. Protocol: prepare a concentrated stock (e.g., 10⁸ copies/µL), then serially dilute 1:10 five times. Each tube gets 10 µL of the previous dilution + 90 µL diluent. Always prepare standards fresh or use validated frozen aliquots.
The standard curve slope should be -3.1 to -3.6 (corresponding to 90-110% PCR efficiency). An R² ≥ 0.98 indicates good linearity.
For PCR, calculate the total volume needed: (number of reactions + 1 extra for pipetting loss) × per-reaction volume. A typical 25 µL reaction contains: 12.5 µL 2× master mix, 1 µL forward primer (10 µM → 0.4 µM final), 1 µL reverse primer, 1 µL template (1-100 ng for genomic, 1 pg-10 ng for plasmid), and 9.5 µL water. Scale up for the number of reactions, then aliquot.
For long-term storage: TE buffer (10mM Tris, 1mM EDTA, pH 8.0) — EDTA chelates Mg²⁺ and inhibits DNase. For immediate use/PCR: nuclease-free water or low-TE (10mM Tris, 0.1mM EDTA). For primers: nuclease-free water. Never use DEPC-treated water for PCR (inhibitory).
nM = (ng/µL × 10⁶) / (660 × bp × 1000). For a 500bp PCR amplicon at 10 ng/µL: nM = (10×10⁶)/(660×500×1000) = 30.3 nM. For copy number: copies/µL = (nM × 6.022×10²³) / 10⁹ = 1.82×10¹⁰ copies/µL for this example.
A serial dilution is a stepwise dilution where each step uses the previous dilution as the stock. A 1:10 serial dilution (DF=10) with 5 steps from 100 ng/µL gives: 100, 10, 1, 0.1, 0.01 ng/µL. This is used for standard curves in qPCR — each step is 1 log unit apart.
Accuracy and precision decrease dramatically below 1 µL. P2 pipettes (0.2-2 µL range) typically have ±5-12% error below 0.5 µL. For small stock volumes, dilute the stock first to avoid pipetting <1 µL. Reverse pipetting improves accuracy for viscous or small-volume samples.
Centrifuge the tube briefly to collect the pellet. Add nuclease-free water or low-TE to make a 100 µM stock (nmol on the tube = µL of water for 1 µM; for 100 µM, divide by 100). For a 25 nmol primer: add 250 µL for 100 µM stock. Then make 10 µM working stocks (1:10 dilution).
Ten-fold serial dilutions create evenly log-spaced standards. On a semi-log plot (Ct vs log concentration), a perfect standard curve is a straight line with slope = -3.32 (100% efficiency). Five 10-fold dilutions span 5 orders of magnitude (e.g., 10⁸ to 10³ copies), covering the typical dynamic range of qPCR.