Technical articles

Application Comparison and Selection Strategies for Common Coprecipitants in Nucleic Acid Precipitation Experiments

In the precipitation of low-concentration, low-copy, or highly diluted nucleic acid samples, precipitation efficiency is determined not only by ethanol, isopropanol, and salt systems, but also by whether the system contains a coprecipitant capable of improving nucleation efficiency, stabilizing precipitated particles, and reducing loss during supernatant removal. Different coprecipitants differ markedly in recovery limits, exogenous background, pellet visibility, and downstream compatibility. Their selection should therefore be based systematically on sample abundance, nucleic acid type, and downstream analytical goals.
 
Keywords: nucleic acid precipitation; coprecipitant; glycogen; linear polyacrylamide; carrier RNA; salmon sperm DNA; poly(A); poly(C); low-abundance nucleic acids; downstream compatibility
 
1 Fundamental roles of coprecipitants in nucleic acid precipitation
1.1 Main reasons why trace nucleic acids are difficult to precipitate
(1) Insufficient nucleation efficiency
When the total amount of nucleic acid is low, the number of molecules available to form a stable aggregation nucleus is limited. Even if ethanol or isopropanol concentrations meet standard precipitation conditions, precipitation may remain incomplete because of insufficient nucleation, ultimately presenting as extremely small pellets or target nucleic acid remaining in the supernatant.
(2) Precipitated particles are too small for efficient centrifugal recovery
Even when low-abundance nucleic acids have entered the precipitated phase, the pellet is often invisible to the naked eye, extremely fine, or attached to the edge of the tube wall. Such pellets are highly susceptible to mechanical loss during centrifugation, decanting, and resuspension.
(3) Complex sample matrices reduce precipitation efficiency
Proteins, surfactants, guanidinium salts, residual phenol, carbohydrates, and high ionic strength can all affect nucleic acid aggregation behavior. For extraction products of only moderate purity, the role of a coprecipitant is often not merely to improve yield, but to ensure that the sample can be recovered reproducibly.
 
1.2 Coprecipitants do not act in the same way
(1) Providing a non-nucleic acid aggregation scaffold
Some coprecipitants are not nucleic acids themselves, but rather polysaccharides or synthetic polymers. Their role is to provide an attachment and aggregation interface for the target nucleic acid, thereby making the precipitated particles more stable and easier to recover by centrifugation.
(2) Enhancing recovery through co-precipitation of related molecules
Another class of coprecipitants consists of RNA, DNA, or artificial polynucleotides. Because they themselves enter the precipitated phase along with the target nucleic acid, they often provide stronger precipitation support under extremely low-input conditions.
(3) Improving practical recoverability during experimental handling
The experimental value of a coprecipitant lies not only in theoretical yield enhancement, but also in making the pellet easier to locate, less likely to be lost during decanting, and more reproducible after resuspension. Evaluation of a coprecipitant should therefore not be limited to chemical precipitation capacity alone, but should also include operational tolerance.
 
1.3 Key dimensions to consider when comparing coprecipitants
(1) Recovery limit
The lowest nucleic acid input level at which the coprecipitant still significantly improves precipitation yield.
(2) Exogenous background
Whether the coprecipitant introduces additional signals that can be detected in quantification, amplification, reverse transcription, sequencing, or hybridization workflows.
(3) Downstream compatibility
Whether residual coprecipitant affects PCR, RT-qPCR, reverse transcription, ligation, library preparation, or hybridization analyses.
(4) Suitable nucleic acid type
Different coprecipitants are not equally suitable for long-fragment DNA, short RNA, small RNA, cfDNA/cfRNA, or total RNA.
Table 1. Basic classification of commonly used nucleic acid coprecipitants
 
Coprecipitant Category
Representative Type
Molecular Nature
Main Advantage
Main Limitation
Non-nucleic acid coprecipitants
Glycogen, linear polyacrylamide (LPA)
Polysaccharide or synthetic polymer
Low exogenous nucleic acid background; suitable for quantification and cleanup before library preparation
May not always be strongest under extreme low-input conditions; residual material may affect resuspension or certain enzyme reactions
Nucleic acid coprecipitants
Yeast tRNA, carrier RNA, salmon sperm DNA
Natural nucleic acid
Strong coprecipitation support under extremely low-input conditions
Introduces exogenous nucleic acid background; interferes with quantification, amplification, and sequencing
Artificial polynucleotides
poly(A), poly(C), etc.
Synthetic nucleic acid polymer
More defined composition and better controllability
Still an exogenous nucleic acid and may still interfere with downstream analysis
Visual coprecipitants
Dyed glycogen, etc.
Modified non-nucleic acid products
Improves pellet localization and handling visibility
Dye residue must be evaluated for compatibility with the detection system
 
2 Application characteristics of non-nucleic acid coprecipitants
2.1 Glycogen
(1) Mechanism of action
Glycogen is a highly branched polysaccharide that can form more stable precipitated particles together with nucleic acids in the presence of high salt and alcohol. Its core function is not sequence-level interaction with nucleic acids, but rather provision of an additional macromolecular aggregation interface.
(2) Application advantages
Glycogen is widely used in low-input RNA precipitation after TRIzol extraction or phenol/chloroform extraction, and is also suitable for trace DNA recovery. Because it is not itself a nucleic acid, it does not directly introduce amplification-template background as nucleic acid-type coprecipitants do. It generally offers favorable background control in RT-qPCR, PCR, and some cleanup steps before low-input library preparation.
(3) Scope of application
Suitable for total RNA, small amounts of RNA, low-input DNA, reprecipitation after column purification, nucleic acid recovery after phenol extraction, and workflows requiring a balance between recovery and background cleanliness.
(4) Limitations
Glycogen does not always provide the highest precipitation support in all extreme recovery scenarios. For samples near the detection limit, nucleic acid-type coprecipitants may sometimes provide stronger support through co-precipitation. In addition, if ethanol washing is insufficient, residual polysaccharide may affect resuspension uniformity or the reproducibility of certain enzymatic reactions.
 
2.2 Linear polyacrylamide (LPA)
(1) Mechanism of action
LPA is a synthetic polymer that contains no nucleic acid components. Its coprecipitation mechanism is similar to that of glycogen, mainly improving precipitation efficiency of low-abundance nucleic acids by forming an aggregation scaffold.
(2) Application advantages
LPA is often regarded as one of the non-nucleic acid coprecipitants with lower background and better batch stability. Because it is not a biologically derived polysaccharide, more consistent control of exogenous nucleic acid, nuclease background, and impurities can usually be achieved, giving it substantial value in highly sensitive workflows.
(3) Scope of application
Suitable for low-input RNA, low-input DNA, cfDNA/cfRNA, small RNA pretreatment, and cleanup steps before library preparation when background cleanliness is especially important.
(4) Limitations
LPA is not visible by itself and offers limited help in pellet localization. In manual experiments that rely more strongly on visual localization of the pellet, the operating experience is often less favorable than with visual coprecipitants. In addition, some laboratories have less accumulated process experience with LPA than with glycogen, so method transfer often requires reoptimization of dosage and wash conditions.
 
2.3 Visual non-nucleic acid coprecipitants
(1) Design purpose
These products are usually glycogen-based materials containing an inert dye component, enabling easier localization of low-abundance nucleic acid pellets after centrifugation.
(2) Application value
For single-tube samples, heavily manual workflows, or extremely small pellets, visual coprecipitants can reduce mechanical loss during supernatant removal and improve experimental reproducibility.
(3) Limitations
If downstream detection is sensitive to color background, fluorescence background, or visible residual impurities, compatibility should be evaluated separately.
 
3 Application characteristics of nucleic acid-type coprecipitants
3.1 Yeast tRNA and carrier RNA
(1) Mechanism of action
Carrier RNA is itself a nucleic acid, and therefore co-precipitates with target RNA or DNA in the presence of salt and alcohol. When the sample is at trace levels, it can markedly increase the probability of pellet formation.
(2) Application advantages
In extremely low-input RNA recovery, carrier RNA often has strong coprecipitation capacity and is especially suitable for sample-handling scenarios in which recovery is the highest priority.
(3) Main limitations
It directly introduces exogenous RNA background. If downstream workflows involve RT-qPCR, transcriptome library preparation, small RNA analysis, or trace RNA quantification, carrier RNA can significantly complicate interpretation and may even contribute a substantial fraction of sequencing reads.
(4) Appropriate use boundary
It is more suitable for experiments concerned mainly with whether the sample can be recovered at all, for rough presence/absence verification, or for workflows that still include an additional purification step. It is not suitable as the default choice for high-sensitivity transcriptomics or low-input library construction.
 
3.2 Salmon sperm DNA and other carrier DNAs
(1) Mechanism of action
Carrier DNAs such as salmon sperm DNA can provide co-precipitation support by contributing molecules of the same general type, thereby improving aggregation efficiency for trace DNA.
(2) Application advantages
In certain trace DNA samples, traditional hybridization experiments, or sample-rescue scenarios, carrier DNA still has substantial coprecipitation value.
(3) Main limitations
It directly increases DNA background and interferes with PCR, digital PCR, low-input library preparation, and quantitative analysis. For any modern sequencing workflow dependent on template cleanliness and low background, carrier DNA should be used with caution.
 
3.3 Artificial polynucleotides such as poly(A) and poly(C)
(1) Mechanism of action
Artificial polynucleotides are nucleic acid coprecipitants with a more defined composition. Compared with natural tRNA or mixed DNA preparations, their background composition is more predictable.
(2) Application advantages
In extremely low-input RNA or DNA recovery, artificial polynucleotides can provide relatively strong coprecipitation while maintaining more controllable background characteristics.
(3) Main limitations
They remain exogenous nucleic acids in essence and may still enter reverse transcription, amplification, and library-construction workflows. “More controllable background” does not mean “no downstream interference.”
Table 2. Comparison of commonly used coprecipitants
 
Coprecipitant
Type
Recovery Limit
Exogenous Nucleic Acid Background
More Suitable Sample Types
Main Limitation
Glycogen
Non-nucleic acid
Strong
Low
Total RNA, trace DNA, routine low-input samples
Not always strongest under extreme low-input conditions
LPA
Non-nucleic acid
Strong to very strong
Extremely low
cfDNA/cfRNA, small RNA, cleanup before low-input library preparation
Invisible pellet, requires greater methodological experience
Dyed glycogen
Non-nucleic acid
Strong
Low
Manual precipitation of extremely low-abundance samples
Dye residue compatibility must be evaluated
Yeast tRNA / carrier RNA
Nucleic acid
Very strong
High
Trace RNA rescue, rough presence verification
Interferes with RT-qPCR and sequencing
Salmon sperm DNA
Nucleic acid
Very strong
High
Trace DNA recovery, some traditional hybridization systems
Interferes with PCR and library construction
poly(A), poly(C)
Nucleic acid
Strong to very strong
Medium to high
Specific low-input systems requiring a more controlled background
Still introduces exogenous nucleic acid
 
4 Coupling between coprecipitants and precipitation systems
4.1 Relationship with ethanol precipitation systems
(1) Ethanol systems depend more on salt and time
Ethanol precipitation is relatively mild and performs well for recovery of long-fragment nucleic acids. However, in extremely low-input samples, addition of a coprecipitant often markedly improves nucleation and particle stability.
(2) Glycogen and LPA perform relatively evenly in ethanol systems
These non-nucleic acid coprecipitants are especially suitable for standard ethanol precipitation because they improve recovery without substantially increasing nucleic acid background.
 
4.2 Relationship with isopropanol precipitation systems
(1) Isopropanol more readily forms precipitates
Isopropanol has stronger nucleic acid precipitation capacity and requires less volume, making it suitable for high-salt and low-volume samples.
(2) Higher risk of impurity co-precipitation
In isopropanol systems, coprecipitants may further improve recovery but may also more readily bring salts, phenol, or other impurities into the pellet. Washing becomes correspondingly more important.
 
4.3 Relationship with salt systems
(1) Sodium acetate systems
These are the most common general-purpose precipitation salt systems and are usually highly compatible with glycogen and LPA.
(2) Ammonium acetate systems
These can help reduce co-precipitation of certain salts and therefore offer some advantages in RNA precipitation.
(3) Lithium chloride systems
These are more selective for RNA precipitation. Performance of different coprecipitants in this system should be evaluated in relation to RNA length, sample complexity, and downstream goals.
 
5 Differences in selection across nucleic acid types
5.1 Total RNA precipitation
(1) Routine low-input total RNA
Glycogen or LPA should generally be prioritized. If downstream workflows include RT-qPCR, RNA-seq, or small RNA analysis, non-nucleic acid coprecipitants are usually safer.
(2) Extremely low-input RNA samples
If the goal is maximum RNA recovery and downstream analysis is limited to rough detection or still includes an additional purification step, carrier RNA or poly(A) may be considered as nucleic acid-type coprecipitants.
 
5.2 DNA precipitation
(1) Routine DNA precipitation
In many cases, a coprecipitant is not strictly necessary. If the sample amount is low or the pellet is extremely small, glycogen or LPA should generally be preferred.
(2) Trace DNA recovery
If downstream workflows include PCR, digital PCR, or library construction, carrier DNA should be avoided whenever possible. Salmon sperm DNA-type solutions should be considered only for rescue recovery scenarios in which an additional purification step is still planned later.
 
5.3 cfDNA/cfRNA and small RNA
(1) These sample types are least compatible with introduction of exogenous nucleic acid background
Because the targets themselves are low-abundance and short-fragment, downstream workflows depend heavily on accurate quantification and library interpretation.
(2) LPA usually has higher priority
Its extremely low exogenous background makes it more suitable for low-input and high-sensitivity workflows.
 
6 Differences in downstream experimental compatibility
6.1 Effects on absorbance- and fluorescence-based quantification
(1) Non-nucleic acid coprecipitants
These generally do not directly elevate nucleic acid measurements as carrier nucleic acids do, but if purification is insufficient they may still affect solution uniformity and measurement reproducibility.
(2) Nucleic acid-type coprecipitants
These directly contribute to the quantitative signal. In trace samples, the exogenous coprecipitant itself may become a major component of the detected readout.
 
6.2 Effects on PCR and RT-qPCR
(1) Glycogen and LPA are more suitable for cleanup before PCR
Provided ethanol washing is sufficient and salt carryover is controlled, their compatibility is generally good.
(2) Carrier RNA and carrier DNA carry higher risk
They may produce background from non-target templates, background during reverse transcription, or confusion in amplification interpretation, especially in low-copy detection systems.
 
6.3 Effects on NGS library preparation and sequencing
(1) Non-nucleic acid coprecipitants are more suitable for cleanup before library preparation
This is especially true in small RNA, cfRNA, low-input RNA-seq, and trace DNA library workflows, where avoidance of exogenous nucleic acid is a prerequisite.
(2) Nucleic acid-type coprecipitants may occupy valuable sequencing reads
In extremely low-input samples, exogenous nucleic acid can readily enter the library and reduce the proportion of informative target reads.
Table 3. Compatibility of coprecipitants with different downstream experiments
 
Downstream Experiment
Glycogen
LPA
Nucleic Acid-Type Coprecipitants
Selection Recommendation
Routine RT-qPCR after RNA recovery
Relatively suitable
More suitable
Use cautiously
Prioritize non-nucleic acid coprecipitants
Low-input RNA-seq
Suitable
More suitable
High risk
Prioritize LPA, followed by glycogen
Small RNA library preparation
Relatively suitable
More suitable
Generally not recommended
Avoid exogenous nucleic acid background
Routine PCR after DNA recovery
Relatively suitable
Suitable
Use cautiously
Prioritize non-nucleic acid coprecipitants
cfDNA/cfRNA pretreatment
Usable
Higher priority
Generally not recommended
Prioritize LPA
Rough presence/absence verification
Usable
Usable
Usable
Determine according to whether recovery is the top priority
 
7 Selection strategies for coprecipitants
7.1 When glycogen should be prioritized
(1) The target nucleic acid amount is low, but downstream analysis emphasizes background cleanliness;
(2) Downstream workflows include RT-qPCR, PCR, or routine library preparation;
(3) A balance between operational convenience and sample cleanliness is desired;
(4) The laboratory already has a stable glycogen-based workflow with sufficient accumulated experience.
 
7.2 When LPA should be prioritized
(1) The sample input is extremely low and downstream workflows are highly sensitive to exogenous nucleic acid;
(2) The workflow involves cfDNA/cfRNA, small RNA, or low-input library preparation;
(3) Minimization of biologically derived impurities and nuclease background is a priority;
(4) Greater emphasis is placed on consistency between recovery limits and methodological cleanliness.
 
7.3 When nucleic acid-type coprecipitants should be considered
(1) The goal is maximal recovery of trace nucleic acids;
(2) Downstream analysis is not high-precision quantification or highly sensitive sequencing;
(3) An additional purification step will still follow later;
(4) The primary objective is to avoid complete loss of the target, rather than to move directly into high-precision analysis.
Table 4. Selection logic for coprecipitants in common experimental scenarios
 
Experimental Scenario
More Suitable Coprecipitant
Main Reason
Routine low-input total RNA precipitation
Glycogen or LPA
Good balance between recovery and background control
Trace RNA rescue
Carrier RNA or poly(A), with LPA also worth prioritizing for trial
Maximum recovery is the priority
Small RNA pretreatment
LPA
Control of exogenous nucleic acid background is more important
Low-input DNA precipitation
Glycogen or LPA
Avoid interference from carrier DNA
cfDNA/cfRNA recovery
LPA
Better suited to highly sensitive low-background workflows
Presence-only rough screening
Carrier RNA, carrier DNA, or artificial polynucleotides
Maximal recovery may be prioritized
 
8 Products related to nucleic acid precipitation experiments
Table 5. Master table of specific catalog products for nucleic acid precipitation experiments
 
Catalog No.
Name
Grade and Purity
Product Category
Suitable Research Use/Application
Carrier RNA (Poly A)
BioReagent, sterile, for DNA and RNA applications, PCR Reagent, ≥99%
Coprecipitant
Suitable for co-precipitation recovery of extremely low-input DNA/RNA samples, especially in low-input workflows prioritizing recovery
Glycogen (for nucleic acid precipitation, 5 mg/mL)
BioReagent, DNase, RNase free, Suitable for molecular biology, for DNA and RNA applications, 5.0 mg/mL
Coprecipitant
Suitable for precipitation of low-input RNA or DNA, balancing recovery with downstream RT-qPCR and PCR compatibility
Glycogen (for nucleic acid precipitation, 20 mg/mL)
BioReagent, DNase, RNase free, Suitable for molecular biology, for DNA and RNA applications, 20 mg/mL
Coprecipitant
Suitable for establishing higher-concentration glycogen coprecipitation systems for extremely low-input samples or highly diluted systems
Denatured Salmon Sperm DNA
BioReagent, 10 mg/mL
Coprecipitant
Suitable for rescue co-precipitation of trace DNA and some RNA samples; should be used cautiously before downstream amplification and library construction
Polydeoxynucleotide/Long-chain Salmon Sperm DNA Sodium (PN)
Cosmetic grade, sterile, ≥96%(HPLC), from Salmon sperm; Average Molecular Weight ≥1000 kDa/1650 bp
Coprecipitant
Suitable for development of long-chain nucleic acid-based coprecipitation systems, especially where aggregation scaffolding and extremely low-input recovery are emphasized
100bp DNA Ladder
Result validation product
Suitable for basic electrophoretic verification of DNA fragment size and recovery after nucleic acid precipitation
DNA Ladder
0.2-12kb, 12 bands, with Red
Result validation product
Suitable for evaluating fragment distribution and recovery integrity after routine DNA precipitation
DNA Ladder (100-15000bp)
BioReagent, ready-to-use, suitable for electrophoresis, Suitable for molecular biology, for NA electrophoresis, 100-15000bp, 11 bands, Blue, 100bp/ 250bp/ 500bp/ 750bp/ 1000bp/ 1500bp/ 2000bp/ 3000bp/ 5000bp/ 8000bp/ 15000bp
Result validation product
Suitable for verifying integrity of precipitated DNA samples across a broad fragment-size range
DNA Ladder (100-2000bp)
BioReagent, ready-to-use, suitable for electrophoresis, Suitable for molecular biology, for NA electrophoresis, 100-2000bp, 6 bands, Blue, 100bp/ 250bp/ 500bp/ 750bp/ 1000bp/ 2000bp
Result validation product
Suitable for evaluation of recovery of short- to medium-length DNA fragments
DNA Ladder (50-500bp)
BioReagent, ready-to-use, suitable for electrophoresis, Suitable for molecular biology, for NA electrophoresis, 50-500bp, 9 bands, Blue,  50bp/ 100bp/ 150bp/ 200bp/ 250bp/ 300bp/ 350bp/ 400bp/ 500bp
Result validation product
Suitable for electrophoretic comparison of short-fragment DNA or low-molecular-weight recovery experiments
Gelred-prestained DNA Ladder (100-1500bp)
BioReagent, ready-to-use, suitable for electrophoresis, Suitable for molecular biology, for NA electrophoresis, 100-1500bp, 11 bands, 100bp/ 200bp/ 300bp/ 400bp/ 500bp/ 600bp/ 700bp/ 800bp/ 900bp/ 1000bp/ 1500bp
Result validation product
Suitable for rapid prestained electrophoretic verification of DNA samples after recovery
Gelred-prestained DNA Ladder (100-5000bp)
BioReagent, ready-to-use, suitable for electrophoresis, Suitable for molecular biology, for NA electrophoresis, 100-5000bp, 9 bands, 100bp/ 250bp/ 500bp/ 750bp/ 1000bp/ 1500bp/ 2000bp/ 3000bp/ 5000bp
Result validation product
Suitable for rapid comparison of recovery of medium- to long-fragment DNA
Gelred-prestained DNA Ladder (250-10000bp)
BioReagent, ready-to-use, suitable for electrophoresis, Suitable for molecular biology, for NA electrophoresis, 250-10000bp, 9 bands, 250bp/ 500bp/ 750bp/ 1000bp/ 1500bp/ 2000bp/ 3000bp/ 5000bp/ 10000bp
Result validation product
Suitable for evaluation of recovery and integrity of longer DNA fragments
Gelred-prestained DNA Ladder (100-2000bp)
BioReagent, ready-to-use, suitable for electrophoresis, Suitable for molecular biology, for NA electrophoresis, 100-2000bp, 6 bands, 100bp/ 250bp/ 500bp/ 750bp/ 1000bp/ 2000bp
Result validation product
Suitable for rapid verification of precipitation results for medium-length DNA
Gelred-prestained DNA Ladder (250-12000bp)
BioReagent, ready-to-use, suitable for electrophoresis, Suitable for molecular biology, for NA electrophoresis, 250-12000bp, 13 bands, 250bp/ 500bp/ 750bp/ 1000bp/ 1500bp/ 2000bp/ 2500bp/ 3000bp/ 4000bp/ 5000bp/ 6000bp/ 8000bp/ 12000bp
Result validation product
Suitable for integrity assessment of DNA precipitation samples across a broad size range
Gelred-prestained DNA Ladder (50-500bp)
BioReagent, ready-to-use, suitable for electrophoresis, Suitable for molecular biology, for NA electrophoresis, 50-500 bp, 9 bands, 50bp/ 100bp/ 150bp/ 200bp/ 250bp/ 300bp/ 350bp/ 400bp/ 500 bp
Result validation product
Suitable for verification of short-fragment DNA and low-molecular-weight precipitation products
Small RNA Ladder
BioReagent, suitable for electrophoresis, Suitable for molecular biology, sterile, 10-50nt, 9 bands
Result validation product
Suitable for evaluating recovery efficiency and band distribution of small RNA or low-molecular-weight RNA precipitates
DuFinder nucleic acid dye
10000X in DMSO
Result validation product
Suitable for electrophoretic detection and band visualization after nucleic acid precipitation
DuGreen nucleic acid dye
10000× in DMSO
Result validation product
Suitable for gel imaging validation of DNA/RNA precipitation results
Gelstein red TM nucleic acid dye
10,000× in water
Result validation product
Suitable for observing recovery quality of precipitated nucleic acids after electrophoresis
Goldview Nucleic Acid Dyes
10000× in DMSO
Result validation product
Suitable for electrophoretic visualization of precipitated nucleic acid samples
HydraGreen™ Nucleic acid dyes
20000×
Result validation product
Suitable for highly sensitive nucleic acid staining and comparison of precipitation outcomes
HydraGreen™ Nucleic acid dyes
10000×
Result validation product
Suitable for routine gel detection after nucleic acid precipitation
RTGreen nucleic acid dye
20× in water
Result validation product
Suitable for rapid staining verification of precipitated nucleic acid samples
SafeGreen nucleic acid gel stain
10000x in DMSO
Result validation product
Suitable for routine electrophoretic detection and comparison of precipitation results
SafeGreen nucleic acid gel stain
10000x in H2O
Result validation product
Suitable for electrophoretic visualization of precipitated nucleic acid samples
SafeRed nucleic acid gel stain
10000x in H2O
Result validation product
Suitable for gel detection of DNA/RNA precipitation results
Super GelBlueTM Nucleic acid dyes
10,000× in water
Result validation product
Suitable for high-sensitivity observation of nucleic acid bands after recovery
Super page gelsteinred nucleic acid dye, 10000 × In water
Result validation product
Suitable for testing recovery performance of precipitated nucleic acids in PAGE systems
Super Safe nucleic acid dyes
10000× in DMSO
Result validation product
Suitable for routine electrophoretic verification after nucleic acid precipitation
Safe Red DNA Stain 2.0
10000×
Result validation product
Suitable for safe gel-staining observation of nucleic acid precipitation results
Ready-to-use SYTOGreen 9 Live Cell Nucleic Acid Stain (5 mM)
BioReagent, ready-to-use, Biological Stain, for fluorescence analysis, for microscopy, sterile, 5 mM
Result validation product
More suitable for nucleic acid visualization and staining; can be used in selected post-precipitation nucleic acid detection scenarios
SYTM Green
Result validation product
Suitable for visualization of DNA/RNA samples after electrophoresis of precipitated products
 
Selection of a coprecipitant in nucleic acid precipitation experiments is fundamentally a balance among recovery, background cleanliness, and downstream compatibility. Glycogen emphasizes improved recovery stability under relatively low-background conditions, LPA is more suitable for trace nucleic acid workflows requiring high sensitivity and low background, and nucleic acid-type coprecipitants are more appropriate for rescue recovery under extreme low-input conditions. A more rational experimental strategy is not to determine which coprecipitant is simply “stronger,” but to choose the one best matched to sample abundance, nucleic acid type, and downstream analytical goals.
 
For more related articles, please see below:
Categories: Technical articles

Da — when not otherwise indicated, molecular weight units are daltons.   Mw — weight-average molecular weight.   Mn — number-average molecular weight.

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Cite this article

Aladdin Scientific. "Application Comparison and Selection Strategies for Common Coprecipitants in Nucleic Acid Precipitation Experiments" Aladdin Knowledge Base, updated Apr 22, 2026. https://www.aladdinsci.com/us_en/faqs/application-comparison-and-selection-strategies-for-common-en.html

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