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This tool converts the mass of ssDNA to moles of ssDNA and moles of ssDNA to the mass of ssDNA.
Mass to Moles Converter
moles of ssDNA [mol] = ssDNA mass [g] / DNA molecular weight [g/mol]
moles of ssDNA ends [mol] = moles of ssDNA [mol]
DNA copy number [molecules] = moles of ssDNA [mol] x 6.022e23 [molecules/mol]
DNA molecular weight [g/mol] = (DNA length [nt] x 308.97 [g/mol//nt]) + 18.02 [g/mol]
Note: 308.97 [g/mol] per nt is average where sequence not given or if sequence is given sum of A: 313.23 [g/mol]; T: 304.21 [g/mol]; C: 289.20 [g/mol];G: 329.23 [g/mol]
Moles to Mass Converter
ssDNA mass [g] = ssDNA moles [mol] x DNA molecular weight [g/mol]
DNA molecular weight [g/mol] = (DNA length [nt] x 308.97 [g/mol//nt]) + 18.02 [g/mol]
Note: 308.97 [g/mol] per nt is average where sequence not given or if sequence is given sum of A: 313.23 [g/mol] ; T: 304.21 [g/mol]; C: 289.20 [g/mol]; G: 329.23 [g/mol]
The ssDNA Mass Moles Converter is commonly used in molecular biology applications that involve quantifying single-stranded DNA (ssDNA) samples based on their mass and converting it to moles. This conversion is essential for various experimental procedures, such as oligonucleotide synthesis, ssDNA quantification and labeling reactions.
Learn more about these specific applications where the ssDNA Mass Moles Converter might be used:
1. Oligonucleotide synthesis: Oligonucleotides are short sequences of ssDNA that are synthesized for PCR primers, gene synthesis or molecular probes. The converter aids researchers in determining the amount of synthesized ssDNA in moles based on its mass, ensuring accurate calculations for the subsequent experimental steps.
2. ssDNA quantification: Similar to dsDNA quantification, the converter assists in identifying the concentration of ssDNA samples. This is essential for many applications, including hybridization experiments, ligations and molecular biology assays that require precise knowledge of the amount of ssDNA present.
3. Labeling reactions: Many labeling reactions, such as fluorescent labeling or radioisotope labeling, require accurately determining the amount of ssDNA used as a starting material. The converter helps in converting the mass of ssDNA into moles, enabling researchers to calculate the appropriate amount of labeling reagents needed for efficient labeling reactions.
4. Nucleic acid hybridization: Hybridization experiments, such as Southern blotting or in situ hybridization, often require quantification of ssDNA probes. The converter assists in converting the mass of ssDNA into moles, allowing accurate determination of probe concentrations for optimal hybridization conditions.
In summary, the ssDNA Mass Moles Converter is a valuable tool for converting ssDNA mass measurements to moles, facilitating accurate quantification and precise experimental design in various applications involving single-stranded DNA. Looking for enzymes to integrate into your workflows and experiments? Check out our broad spectrum portfolio.
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