Oligo Resuspension & Dilution Calculator
Professional calculator for oligonucleotide preparation. Calculate resuspension volumes, C₁V₁=C₂V₂ dilutions, and pool-specific concentrations with instant printable protocols.
When to Use Each Calculator
1Resuspension Calculator
Use for: Initial reconstitution of lyophilized oligos from vendor. Input received nmol, get buffer volume for target stock (typically 100 µM).
2Dilution Calculator
Use for: Preparing working solutions from stocks using C₁V₁=C₂V₂. Common: 100 µM stock → 10 µM working solution for PCR.
3Pool-Specific Calculator
Use for: CRISPR libraries and oligo pools requiring equimolar representation. Calculate per-oligo concentration (standard: 0.5-2 nM each).
Input Parameters
Results
No results yet
Enter values and click "Calculate Volume"
Understanding Dilution Calculations for Oligonucleotides
How to Use the Dilution Calculator
The Dilution Calculator is an essential tool for preparing oligonucleotide solutions at precise concentrations required for your experiments. Follow these step-by-step instructions to ensure accurate results:
- Select the Appropriate Tab: Choose between Resuspension Calculator (for initial reconstitution of lyophilized oligos), Dilution Calculator (for preparing working solutions from stocks), or Pool-Specific Calculator (for oligo pools where each oligo needs a specific concentration).
- Enter Received Amount: Input the amount of oligonucleotide you received from the vendor, typically stated on the tube or datasheet. Common units are nmol (nanomoles) or pmol (picomoles). For example, a standard primer might come as 50 nmol.
- Set Target Concentration: Specify your desired final concentration. Common values include 100 µM for primer stocks, 10 µM for working solutions, or 0.5-2 nM per oligo in pools. The calculator supports nM (nanomolar) and µM (micromolar) units.
- Optional Pool Size: If working with oligo pools (e.g., CRISPR libraries), enter the number of unique oligos. This enables calculation of per-oligo concentration, ensuring equimolar representation.
- Calculate and Review: Click"Calculate Volume" or press Ctrl+Enter (Cmd+Enter on Mac) to get instant results. The calculator displays the exact buffer volume needed, final concentration, and a printable step-by-step protocol.
- Follow the Protocol: Use the generated protocol to prepare your solution accurately. Always use calibrated pipettes and appropriate buffers (TE buffer for long-term storage, nuclease-free water for immediate use).
Calculation Examples
Example 1: Primer Resuspension
Scenario: You received a 50 nmol primer and need a 100 µM stock solution.
Input: Received Amount = 50 nmol, Target Concentration = 100 µM
Calculation: Volume (µL) = Amount (nmol) / Concentration (µM) = 50 nmol / 100 µM = 500 µL
Result: Add 500 µL of TE buffer to achieve 100 µM concentration. This stock can be stored at -20°C for 6-12 months. For daily use, prepare a 10 µM working solution by diluting 10 µL of stock into 90 µL buffer.
Example 2: Working Solution Dilution
Scenario: You have a 100 µM stock and need 50 µL of 10 µM working solution for PCR.
Input: Initial Concentration (C₁) = 100 µM, Final Concentration (C₂) = 10 µM, Final Volume (V₂) = 50 µL
Calculation: Using C₁V₁ = C₂V₂: V₁ = (C₂ × V₂) / C₁ = (10 µM × 50 µL) / 100 µM = 5 µL
Result: Pipette 5 µL of your 100 µM stock into 45 µL of buffer to make 50 µL of 10 µM working solution. This working solution should be stored at 4°C and used within 1-2 weeks.
Example 3: Oligo Pool Preparation
Scenario: You have a 1000-oligo CRISPR library (50 nmol total) and need each oligo at 1 nM concentration.
Input: Received Amount = 50 nmol, Pool Size = 1000, Target Per-Oligo Concentration = 1 nM
Calculation: Total pool concentration = 1 nM × 1000 = 1000 nM = 1 µM. Volume = 50 nmol / 1 µM = 50,000 µL = 50 mL
Result: Resuspend the entire pool in 50 mL of buffer to achieve 1 nM per oligo. This ensures equimolar representation, critical for uniform amplification in downstream applications. Aliquot into smaller volumes to avoid repeated freeze-thaw cycles.
Understanding Your Results
The Dilution Calculator provides several key outputs to guide your experimental preparation:
- Buffer Volume Required: The exact volume of buffer (typically TE buffer or nuclease-free water) needed to achieve your target concentration. This is the primary output you'll use in the lab. Always add buffer to the oligo tube, not the reverse, to ensure complete dissolution.
- Final Concentration: The resulting concentration of your solution after resuspension or dilution. Verify this matches your experimental requirements. For PCR primers, 10 µM working solutions are standard; for qPCR, 5-10 µM is typical.
- Per-Oligo Concentration: When working with pools, this shows the concentration of each individual oligo. For CRISPR libraries and NGS applications, maintaining equimolar representation (typically 0.5-2 nM per oligo) is critical for uniform coverage.
- Storage Recommendations: The calculator provides temperature and duration guidelines based on concentration and application. Stock solutions (100 µM) can be stored at -20°C for 6-12 months, while working solutions (10 µM) are stable at 4°C for 1-2 weeks.
Important Notes: Always verify concentrations using spectrophotometry (A₂₆₀ readings) when possible. The 260/280 ratio should be ~1.8-2.0 for pure DNA. For oligo pools, consider using our Uniformity Estimator to assess representation quality. If you encounter dissolution issues, check for secondary structures using our Secondary Structure Predictor.
Vendor-Specific Resuspension Protocols
All major oligonucleotide vendors provide synthesis on similar scales, but resuspension recommendations vary. This calculator is compatible with all vendors using standard nmol-to-µM conversions.
⚠️ Important: Vendor specifications below are typical as of November 2025 but subject to change. Always verify current synthesis scales and QC methods from your vendor's datasheet. This information is for educational reference only.
| Vendor | Typical Scale (nmol) | Stock Conc. | Recommended Buffer | Special Notes |
|---|---|---|---|---|
| IDT | 25 (desalted) 250 (HPLC) | 100 µM | IDTE (pH 8.0) | Often ships with buffer |
| Twist | 50-100 (pools) 10-25 (singles) | 10 nM/oligo (pools) 100 µM (singles) | TE buffer | Heat pools to 65°C |
| GenScript | 50 (standard) 100+ (modified) | 100 µM 50 µM (modified) | TE or NFW | DMSO for hydrophobic mods |
| Sigma-Aldrich | 40-50 | 100 µM | TE or NFW | Check for pre-added water |
IDT (Integrated DNA Technologies)
- Standard scale: 25 nmol desalted, 250 nmol HPLC/PAGE purified
- Recommended stock: 100 µM in TE buffer (pH 8.0)
- Volume calculation: For 25 nmol → 100 µM: Add 250 µL buffer
- QC provided: OD260, exact nmol yield on tube label
- Tip: IDT ships with IDTE buffer (10 mM Tris, 0.1 mM EDTA, pH 8.0) - use this for best stability
Twist Bioscience
- Standard scale: Oligo pools 50-100 nmol total, individual oligos 10-25 nmol
- Recommended stock: Pools at 10 nM per oligo, singles at 100 µM
- Volume calculation: For 50 nmol pool (1000 oligos) → 10 nM/oligo: Add 5 mL buffer
- QC provided: NGS-based uniformity analysis, exact nmol on datasheet
- Tip: Twist pools benefit from heating to 65°C for 5 min during resuspension due to high complexity
GenScript
- Standard scale: 50 nmol for primers, 100+ nmol for modified oligos
- Recommended stock: 100 µM standard, 50 µM for hydrophobic modifications
- Volume calculation: For 50 nmol → 100 µM: Add 500 µL buffer
- QC provided: MALDI-TOF mass spec for modified oligos
- Tip: GenScript modifications may need 10-20% DMSO in buffer for complete dissolution
Sigma-Aldrich / Millipore
- Standard scale: 40-50 nmol standard synthesis
- Recommended stock: 100 µM in nuclease-free water or TE
- Volume calculation: For 40 nmol → 100 µM: Add 400 µL buffer
- QC provided: OD260, purity by RP-HPLC
- Tip: Sigma often ships in tubes with pre-measured water - check tube label before adding buffer
Universal Protocol: Regardless of vendor, always (1) spin down tube to collect lyophilized material, (2) add buffer slowly to avoid splash, (3) vortex 30 seconds, (4) centrifuge briefly, (5) let sit 5-10 min for complete dissolution. For oligos >80 nt or GC% > 65%, heat to 65°C for 5 min then cool slowly.
Accuracy & Best Practices
Typical laboratory observations and general industry practices. Individual results may vary based on equipment, technique, and specific experimental conditions:
Typical Dilution Errors
Based on common laboratory experience with manual pipetting. Electronic pipettes may achieve better precision.
- 10x dilution accuracy: ±2-5% typical range (calibrated pipettes, experienced users)
- 100x dilution accuracy: ±5-10% typical (recommend 2-step: 10x → 10x for better accuracy)
- Pipetting dead volume: ~0.5-1 µL (P10), ~2-5 µL (P200) - add 10% extra for critical applications
- Freeze-thaw effects: Estimated 5-10% activity loss per cycle (limit to 3-5 cycles maximum)
Note: Actual precision depends on pipette calibration, user technique, and liquid properties. Verify with standards when precision is critical.
Standard Concentrations by Application
Current industry practices as of November 2025. These are common starting points; optimize for your specific protocols.
| Application | Stock Conc. | Working Conc. | Final Reaction Conc. |
|---|---|---|---|
| PCR Primers | 100 µM | 10 µM | 0.2-0.5 µM (200-500 nM) |
| qPCR Primers | 100 µM | 10 µM | 0.3-0.9 µM (300-900 nM) |
| qPCR Probes (TaqMan) | 100 µM | 5-10 µM | 0.1-0.25 µM (100-250 nM) |
| Sequencing Primers | 100 µM | 3.2 µM | 1.6-3.2 µM (Sanger) |
| CRISPR sgRNA (IVT) | N/A (use template) | 2-10 µM (post-IVT) | 200 nM (in RNP complex) |
| Oligo Pools (NGS) | 10-20 nM/oligo | 1-2 nM/oligo | 0.5-1 nM/oligo (library prep) |
| CRISPR Libraries | 10 nM/sgRNA | 1-2 nM/sgRNA | 0.5-1 nM/sgRNA (cloning) |
| Molecular Beacons | 100 µM | 5 µM | 50-250 nM |
| Hybridization Probes | 100 µM | 10 µM | 1-10 nM (varies by method) |
Note: Final concentrations vary by polymerase, kit manufacturer, and specific protocol. Always consult your kit's manual.
Storage Stability Guidelines
General recommendations based on common laboratory practices. Actual stability depends on sequence, modifications, buffer composition, and contamination levels:
- -80°C: Typically > 95% activity for 5+ years (preferred for archival storage)
- -20°C: Generally > 90% activity for 12 months (100 µM stocks) or 6 months (10 µM working)
- 4°C: 7-14 days typical for working stocks; not recommended for long-term storage
- Room temperature: < 24 hours - minimize exposure during handling
- TE buffer benefit: Approximately 2-3x better stability than water (pH buffering + EDTA chelation)
Best practice: Aliquot stocks immediately upon resuspension to minimize freeze-thaw cycles. Monitor for precipitation or discoloration as signs of degradation.
Troubleshooting Guide: Common Problems & Solutions
⚠️Problem: Oligo Won't Dissolve Completely
Symptoms: Visible particles, cloudy solution after vortexing
Diagnosis tree:
- Check GC content: If > 65%, heat to 65°C for 5 min then cool slowly (breaks secondary structures)
- Check length: If > 80 nt, may need overnight dissolution at 4°C after initial vortex
- Check modifications: Hydrophobic mods (biotin, fluorophores) need 10-20% DMSO in buffer
- Check pH: Ensure pH 7-8; acidic solutions (< pH 6) reduce solubility
- Still cloudy? Filter through 0.22 µm syringe filter - remaining particles are likely contaminants, not oligo
Prevention: Use our Secondary Structure Predictor during design to avoid high-GC hairpins.
⚠️Problem: PCR Not Working with Freshly Diluted Primers
Symptoms: No amplification or weak bands after primer dilution
Diagnosis tree:
- Verify dilution math: Use Dilution Calculator to confirm C₁V₁=C₂V₂ calculation
- Check stock concentration: Measure OD260 (1 OD260 ≈ 33 µg/mL for ssDNA) - vendor nmol may be overestimated by 10-20%
- Check final primer concentration: Most Taq polymerases need 0.2-0.5 µM final (200-500 nM). Too low (< 0.1 µM) = no product, too high (> 1 µM) = primer dimers
- Buffer compatibility: If using DEPC-treated water, switch to regular nuclease-free water (DEPC inactivates enzymes)
- Template quality: Not a dilution issue - check with our Tm Calculator to verify annealing temperature
⚠️Problem: Oligo Pool Shows Poor Uniformity After Resuspension
Symptoms: NGS shows > 3-fold variation between oligos (expected: < 1.5-fold)
Diagnosis tree:
- Incomplete dissolution: Heat to 65°C for 10 min, vortex vigorously, let sit overnight at 4°C
- Synthesis bias (not fixable): If specific sequences consistently low, this is vendor synthesis bias. Use our Uniformity Estimator to predict dropout risk before ordering
- Aggregation: Some oligos form higher-order structures. Add 0.01% Tween-20 to prevent aggregation
- Verify target concentration: For CRISPR libraries, aim for 1-2 nM per oligo. Too high concentration (> 10 nM) can cause aggregation
Quality control: Always run NGS QC on 1-5% of resuspended pool before large-scale experiments. See Oligo Pool QC workflow.
Calculation Formulas & Theoretical Background
The dilution calculations used in this calculator are based on fundamental principles of solution chemistry, validated through decades of molecular biology research and updated with 2025 best practices:
C₁V₁ = C₂V₂ Dilution Formula
Solve for V₁:
V₁ = (C₂ × V₂) / C₁
Example: (10 µM × 100 µL) / 100 µM = 10 µL stock + 90 µL buffer
Essential Unit Conversions
| Quantity | Unit | Relationship | Example |
|---|---|---|---|
| Amount | 1 mol | = 1,000 mmol = 1,000,000 µmol | - |
| 1 mmol | = 1,000 µmol = 1,000,000 nmol | Rare for oligos | |
| 1 nmol | = 1,000 pmol | Standard oligo scale | |
| Concentration | 1 M | = 1,000 mM = 1,000,000 µM | Too concentrated |
| 1 µM | = 1,000 nM = 1 nmol/µL | Stock concentration | |
| 1 nM | = 1,000 pM = 1 pmol/µL | Pool per-oligo conc. | |
| 1 pM | = 0.001 nM | Very dilute | |
| Key Conversion | 1 µM = 1 nmol/µL = 1 nmol/mL | Most important! | |
| 100 µM in 500 µL = 50 nmol total | Typical stock | ||
Memory aid: µM and nmol/µL are equivalent. If you have 25 nmol and want 100 µM, add 250 µL (25/100 = 0.25 mL = 250 µL).
This resuspension formula derives from the definition of molarity: M = n/V, where M is molarity (mol/L), n is moles, and V is volume. For oligonucleotides, we work with nanomoles (nmol) and micromolar (µM) concentrations. The key insight: 1 µM = 1 nmol/µL, which simplifies all calculations.
- Resuspension Calculations: When resuspending lyophilized oligos, the amount (in nmol) is fixed by the vendor. The volume you add determines the final concentration. This calculator uses the standard conversion: 1 µM = 1 nmol/µL, ensuring compatibility with all major vendors (IDT, Twist Bioscience, GenScript, Dynegene).
- Dilution Formula (C₁V₁ = C₂V₂): This fundamental equation ensures mass conservation during dilution. The product of initial concentration and volume equals the product of final concentration and volume. This calculator solves for V₁ (volume of stock needed) when you know C₁, C₂, and V₂.
- Pool-Specific Calculations: For oligo pools, the total pool concentration equals the per-oligo concentration multiplied by pool size. Example: 1000-oligo pool at 1 nM per oligo = 1000 nM = 1 µM total pool concentration. This ensures equimolar representation, critical for CRISPR libraries, NGS target enrichment, and multiplexed screening. Industry recommendations as of 2025: maintain 0.5-2 nM per oligo for most applications. For CRISPR genome-wide screens, 1-2 nM per sgRNA is standard to ensure sufficient coverage while minimizing off-target effects.
- 2025 Updates: Recent guidelines emphasize the importance of accurate pipetting and calibrated equipment. The calculator accounts for practical considerations like dead volume and pipetting error. For critical applications, always add 10% extra volume to account for these factors.
For comprehensive protocols and best practices, refer to our User Guide or explore Oligo Pool QC workflows.
Frequently Asked Questions
Use TE buffer (10mM Tris-HCl pH 8.0, 0.1mM EDTA) for long-term storage or nuclease-free water for immediate use. TE buffer provides better stability by chelating metal ions and maintaining pH. Avoid DEPC-treated water as it can react with primary amines.
Learn more about buffer selection and storage in our User Guide.
Need more help? Visit our complete FAQ for additional questions, or check out User Guide for detailed protocols on oligo resuspension and dilution.
Related Tools & Common Workflows
Common Workflows: Tool Combinations
🧬PCR Primer Workflow
- Dilution Calculator: Resuspend lyophilized primer to 100 µM stock
- Molecular Weight Calculator: Verify concentration from OD260 reading
- Tm Calculator: Calculate optimal annealing temperature
- Secondary Structure Predictor: Check for primer dimers & hairpins
- Result: PCR-ready primers with verified quality
🧠CRISPR Library Workflow
- Uniformity Estimator: Predict synthesis dropout risk before ordering
- Dilution Calculator (Pool-Specific): Resuspend to equimolar concentration (1-2 nM/oligo)
- Batch Sequence QC: Validate pool uniformity via NGS
- GC Content Analyzer: Identify problematic sequences
- Result: High-quality CRISPR library ready for screening
⚙️qPCR Probe Workflow
- Dilution Calculator: Make 10 µM working stock from 100 µM stock
- Tm Calculator: Verify probe Tm is 8-10°C higher than primers
- Secondary Structure Predictor: Ensure no probe self-structure
- Result: Optimized qPCR assay with minimal background
📊Quality Control Workflow
- Dilution Calculator: Prepare test dilutions
- Molecular Weight Calculator: Calculate expected MW for mass spec verification
- GC Content Analyzer: Predict solubility issues
- Batch Sequence QC: Comprehensive pool analysis
- Result: Validated oligo stocks with documented QC
All Related Tools
Molecular Weight Calculator
Calculate MW and concentration from OD260 readings
Tm Calculator
Calculate melting temperature for primer design
GC Content Analyzer
Analyze sequence composition and GC percentage
Secondary Structure Predictor
Detect hairpins and dimers in your oligos
Uniformity Estimator
Estimate pool uniformity and dropout rates
Batch Sequence QC
Quality control for large oligo pools