Calculate DNA concentration from absorbance (A260), nanodrop data, molar conversions, and purity ratios. Covers dsDNA, ssDNA, RNA, and oligonucleotides.
Accurate DNA concentration measurement is fundamental to nearly every molecular biology workflow — PCR, cloning, sequencing, transfection, and library preparation all require precise input quantities. The standard method uses UV spectrophotometry at 260 nm (A260), leveraging the fact that nucleic acid bases absorb strongly at this wavelength.
The Beer-Lambert law relates absorbance to concentration: A = εlc, where ε is the extinction coefficient, l is the path length, and c is the concentration. For nucleic acids, simplified conversion factors are widely used: an A260 of 1.0 (in a 1 cm path length cell) corresponds to 50 µg/mL for double-stranded DNA, 33 µg/mL for single-stranded DNA, 40 µg/mL for RNA, and 20-33 µg/mL for oligonucleotides (sequence-dependent). Modern instruments like the NanoDrop use micro-volume measurements with short path lengths and automatically apply these factors.
Beyond raw concentration, purity assessment is critical. The A260/A280 ratio indicates protein contamination (pure DNA ≈ 1.8, pure RNA ≈ 2.0). The A260/A230 ratio indicates organic solvent or salt contamination (ideal: 2.0-2.2). This calculator computes concentration from absorbance, converts between mass and molar units, evaluates purity ratios, and provides the dilution calculations needed for downstream applications.
Precise nucleic acid quantification is required before virtually every molecular biology experiment. This calculator eliminates unit conversion errors between ng/µL, µg/mL, nM, and copies/µL — errors that can ruin expensive downstream reactions like sequencing library prep or transfection experiments. This dna concentration calculator helps you compare outcomes quickly and reduce avoidable mistakes when making day-to-day care decisions. Use the estimate as a planning baseline and confirm final decisions with a qualified professional when risk is high.
Concentration (µg/mL) = A260 × Dilution Factor × Conversion Factor / Path Length (cm). Conversion factors: dsDNA = 50, ssDNA = 33, RNA = 40, oligo ≈ 33. Molar concentration (nM) = [ng/µL] × 10⁶ / (MW in g/mol). Average MW per bp: dsDNA = 660 Da/bp, ssDNA = 330 Da/nt, RNA = 340 Da/nt.
Result: 25 µg/mL = 25 ng/µL = 7.58 nM
Concentration = 0.5 × 50 / 1 = 25 µg/mL. A260/280 = 1.79 (acceptable). MW of 5000 bp dsDNA = 5000 × 660 = 3,300,000 g/mol. Molar: 25 ng/µL × 10⁶ / 3,300,000 = 7.58 nM.
UV spectrophotometry (NanoDrop, cuvette) measures total nucleic acid absorption at 260 nm. This includes dsDNA, ssDNA, RNA, free nucleotides, and primers — everything that absorbs UV. It's fast, non-destructive, and doesn't consume reagents. **Fluorometry** (Qubit, PicoGreen, RiboGreen) uses dyes that selectively bind specific nucleic acid types. PicoGreen and Qubit dsDNA reagents bind only dsDNA, ignoring ssDNA contaminants, primers, and free nucleotides. This selectivity makes fluorometry the gold standard for NGS library quantification where adapter dimer contamination inflates NanoDrop readings by 2-10×.
**PCR**: 1-50 ng genomic DNA template (50 µL rxn). **qPCR**: 1-100 ng total, 10⁷ copies recommended. **Sanger sequencing**: 150-300 ng for plasmids, 20-50 ng for PCR products. **Illumina library prep**: 100-1000 ng input (kit-dependent). **Oxford Nanopore**: 400-1000 ng for ligation kits, 100-200 ng for rapid kits. **Transfection**: 0.5-5 µg per well (24-well plate). **Restriction digest**: 0.5-2 µg per reaction. **Ligation**: 50-100 ng vector + 3:1 molar insert:vector ratio.
Molecular weight of nucleic acids depends on type and length. **dsDNA**: MW = N × 660 Da where N = base pairs. A 1 kb fragment: 660,000 Da = 660 kDa. **ssDNA/oligos**: MW = N × 330 Da where N = nucleotides, minus water per condensation. More precisely, calculate from sequence: MW = (nA × 331.2) + (nC × 307.2) + (nG × 347.2) + (nT × 322.2) - 61.96. **RNA**: MW = N × 340 Da, or sequence-specific: MW = (nA × 347.2) + (nC × 323.2) + (nG × 363.2) + (nU × 324.2) + 159.0. For copy number: copies = (concentration in g/µL) × 6.022 × 10²³ / MW.
A260/A280 ratio of ~1.8 indicates pure DNA with minimal protein contamination. Ratios significantly lower than 1.8 suggest protein, phenol, or other UV-absorbing contaminant. RNA has a higher ideal ratio of ~2.0 due to its base composition. Note: 260/280 is pH-dependent — measure in slightly alkaline buffer (TE, pH 8.0) for accurate results.
Low 260/230 ratios (<1.8) indicate contamination with organic compounds that absorb at 230 nm: guanidinium salts (from column purification kits), phenol, EDTA, carbohydrates, or TRIzol carryover. These contaminants can inhibit downstream enzymatic reactions. Clean up with ethanol precipitation or a column-based purification kit.
Spectrophotometric methods (NanoDrop, standard cuvette UV) measure all nucleic acid in solution, including degraded DNA, primers, and free nucleotides. For applications requiring accurate dsDNA-specific quantification (e.g., NGS library prep), fluorometric methods (Qubit, PicoGreen) are more accurate because dyes selectively bind intact dsDNA.
Typical PCR template: 1-10 ng of genomic DNA or 0.1-1 ng of plasmid in 25-50 µL reactions. For qPCR: 1-100 ng total. For sequencing: varies by platform — Sanger: 100-200 ng, Illumina library prep: 100-1000 ng depending on kit.
nM = (ng/µL × 10⁶) / (MW in g/mol). For dsDNA: MW = length(bp) × 660 Da/bp. For a 300 bp PCR product: MW = 198,000 g/mol. So 10 ng/µL = 10 × 10⁶ / 198,000 = 50.5 nM. Sequencing core facilities often request libraries at 2-4 nM.
NanoDrop instruments use two path lengths simultaneously: 1 mm (0.1 cm) for high-concentration samples and 0.2 mm (0.02 cm) calculated from the 1 mm measurement. The 1 mm path is used for the reported concentration. Some older units also use 0.05 cm. Always check your instrument's documentation.