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Invitrogen Qubit assays use target-selective dyes that emit fluorescence only when bound to their DNA, RNA, or protein target. They are more accurate than traditional UV absorbance, which can overestimate sample concentrations due to contaminants such as salts, solvents, detergents, proteins, and free nucleotides. Fluorescence measurements are also much more sensitive than UV absorbance, and Qubit Fluorometers can accurately measure dilute samples with significantly less noise.
Tip: For high-throughput quantification, consider using a microplate reader with fluorescence capabilities. . The Thermo Scientific Varioskan ALF and Varioskan LUX Multimode Microplate Readers are compatible with Quant-iT assays to quantify the same analytes as Qubit Fluorometers and assays. For a comparison, see our RNA/DNA Quantification page.
While Qubit assays differ in the analytes they measure, they share characteristics that make them selective, sensitive, and easy to use with the Qubit 4 or Flex Fluorometer.
Dyes bind selectively to DNA, RNA, or protein
More sensitive than UV absorbance and traditional Bradford protein assays
Dyes emit fluorescence only when bound to target
Minimizes effects of contaminants, including degraded DNA or RNA
Easy to perform
Simple mix-and-read format
Short incubation times
Only 2 minutes for DNA and RNA assays or 10–15 minutes for protein assays
Designed for Qubit Fluorometers
Optimized for use with the Qubit 4 and Qubit Flex Fluorometers
Qubit assays are available for double- and single-stranded DNA (dsDNA and ssDNA), RNA, microRNA, and protein. Qubit DNA and RNA assays are available with different quantification ranges. The HS (high sensitivity) assays quantitate the lowest levels of analyte, the BR (broad range) assays do so across a wider range, and the RNA XR (extended range) assay is ideal for abundant samples. These various detection ranges allow accurate measurement across a wide range of concentrations. As the graph shows, both Qubit HS and BR assays detect lower levels of analyte than UV absorbance.
Sample concentration ranges for Qubit assays and UV absorbance
Fluorescence-based quantification using the Qubit system is very sensitive, quantitating samples of low abundance, and measures only the intended target, even if the sample contains both DNA and RNA. Standard UV absorbance readings are not sensitive enough to detect low levels of analyte and do not distinguish between RNA vs DNA, quantitating all nucleic acid present in a sample.
In addition, fluorescence-based quantification using the Qubit system can distinguish between RNA and DNA in the same sample whereas UV absorbance readings typically cannot. With the total solution offered by Qubit platforms, you can be confident in your results because assays, consumables and instruments have been co-optimized for exceptional performance.
Qubit dsDNA assays are available in two quantification ranges (HS and BR) and two formats (standard and 1X), both important considerations for downstream applications and processing. An assay that quantifies ssDNA and oligonucleotides is also available.
Product |
Initial sample concentration |
Quantitation range |
No. of assays |
Cat. No. |
High Sensitivity dsDNA Assays |
||||
Qubit 1X dsDNA HS Assay Kit |
0.005–120 ng/µL |
0.1–120 ng |
100 |
|
500 |
||||
Qubit dsDNA HS Assay Kit |
0.005–120 ng/µL |
0.1–120 ng |
100 |
|
500 |
||||
Qubit 1X dsDNA HS Assay Lambda Standard |
— |
— |
500 |
|
Broad Range dsDNA Assays |
||||
Qubit 1X dsDNA BR Assay Kit |
0.2–4,000 ng/µL |
4–4,000 ng |
100 |
|
500 |
||||
Qubit dsDNA BR Assay Kit |
0.2–2,000 ng/µL |
4–2,000 ng |
100 |
|
500 |
||||
Qubit 1X dsDNA BR Assay Lambda Standard |
— |
— |
500 |
|
ssDNA Assay |
||||
Qubit ssDNA Assay Kit |
0.01–240 ng/µL |
0.2–240 ng |
100 |
Our Qubit dsDNA high-sensitivity (HS) and broad-range (BR) assays are highly selective for dsDNA over RNA and ssDNA. The high-sensitivity assay is designed for samples with low concentrations of dsDNA, which helps to conserve precious samples. Common contaminants such as salts, free nucleotides, RNA, solvents, detergents, or protein are well tolerated in the dsDNA HS and BR assays.
Qubit dsDNA HS assay results
On either the Qubit 4 (shown) or Qubit Flex Fluorometer, results can be displayed either numerically or graphically. These images show our high-sensitivity (HS) dsDNA assay designed for samples with low DNA concentrations.
In this test, accuracy and precision were assessed on the Qubit 4 and Flex Fluorometers, as well as a competitor’s instrument, using the Qubit dsDNA HS and BR assays. Percent deviation and CV were both lower for the Qubit 4 and Flex instruments than the competitor’s, demonstrating higher accuracy and precision.
Qubit 1X dsDNA assays are provided in a convenient pre-mixed format that eliminates the step of preparing the Qubit working solution. Simply add your sample or standard to the premixed solution, incubate, and read your results. This format offers a simplified, faster workflow while reducing the number of tubes in the kit (and therefore the amount of plastic used).
The Qubit 1X dsDNA HS assay provides the same dynamic range and limit of detection as the standard dsDNA HS assay, while the Qubit 1X dsDNA BR assay has a higher dynamic range than the standard dsDNA BR assay, achieving 4,000 ng/µL in the extended range.
In this test of the Qubit 1X dsDNA HS (left) and BR (right) assays over their core ranges, the measured amount of dsDNA deviated from the expected value by less than 10%, even in the presence of equal amounts of RNA.
A) Qubit 1X dsDNA HS Assay
B) Qubit 1X dsDNA BR Assay
Selectivity of Qubit 1X dsDNA HS (A) and BR (B) assays
Plots show the quantification results for samples seeded with known quantities of DNA and RNA vs expected values. Circles represent samples with 10 μL of DNA plus 190 μL of working solution, at varying concentrations. Squares represent samples with 10 μL of RNA and 10 μL of DNA plus 180 μL of working solution, at varying concentrations. The closeness of the circles and squares—in some instances almost indistinguishable—demonstrate that these two dsDNA assays are minimally affected by the presence of RNA.
The Qubit ssDNA Assay Kit is designed to quantify long ssDNA or oligonucleotides. Purify ssDNA before performing the assay, as it can also detect dsDNA and RNA. However, assay results will not be affected by common contaminants such as salts, short oligonucleotides (≤6 bases), free nucleotides, solvents, detergents, or protein.
There are three Qubit RNA assays to quantify different concentration ranges of large RNA, and one assay to quantify small RNA molecules (microRNA). For an additional assay that measures the integrity and quality of your RNA sample, see the next section on the RNA IQ assay.
Product |
Initial sample concentration |
Quantitation range |
No. of assays |
Cat. No. |
General RNA assays |
||||
Qubit RNA HS Assay Kit |
0.2–200 ng/µL |
4–200 ng |
100 |
|
500 |
||||
Qubit RNA BR Assay Kit |
0.5–1,200 ng/µL |
10–1,200 ng |
100 |
|
500 |
||||
Qubit RNA XR Assay Kit |
5–20,000 ng/µL |
100–20,000 ng |
100 |
|
500 |
||||
microRNA assay |
||||
Qubit microRNA Assay Kit |
0.025–150 ng/µL |
0.5–150 ng |
100 |
|
500 |
To quantify RNA, you can choose among three Qubit RNA Assay kits with overlapping ranges of initial sample concentrations, from as little as 250 pg/μL to 10,000 ng/μL. These kits are highly selective for RNA over double-stranded DNA (dsDNA). Unlike other RNA assays, they do not require DNase for an accurate measurement, even if DNA is present in the sample. Common contaminants such as salts, free nucleotides, solvents, detergents, or proteins are well tolerated in these assays.
In this sensitivity test, both the Qubit RNA and microRNA assays (red and blue bars) measured very close to the actual concentrations of their target RNAs (red and blue lines).
Qubit RNA and microRNA assay sensitivity
Ribosomal RNA (rRNA) at the concentrations listed on the x-axis was added to samples containing 2 μg/mL siRNA. The mixtures were then assayed using the Qubit microRNA assay, the Qubit RNA assay, and the NanoDrop A260 assay, which quantifies using UV absorbance. Results from eight replicates were averaged, with standard deviations shown. The NanoDrop instrument’s (purple bars) detection limit for total RNA concentration is 1.5 μg/mL, affecting its accuracy and precision at low concentration levels. The Qubit RNA assay (red bars) accurately quantified the rRNA concentration over a broad scale. The Qubit microRNA assay (blue bars) accurately quantified the 2 μg/mL siRNA concentration, while accuracy was mildly affected as rRNA increased from 2 to 5 times that amount. The blue and red trendlines indicate the actual concentrations of siRNA and rRNA in the samples, respectively.
The Invitrogen Qubit microRNA Assay Kit is designed for easy and accurate quantification of small RNA (17–25 nt or bp) such as microRNA, even in the presence of common contaminants such as salts, free nucleotides, solvents, detergents, and protein. The assay is highly selective for small RNA over rRNA or large messenger RNA (mRNA) (>1,000 bp).
Small RNA in pure samples has reproducibly been quantified at levels as low as 0.5 ng in the assay tube. The assay detects all types of small RNA, including microRNA and short interfering RNA (siRNA), both single- and double-stranded. Because it does not detect nucleotides, it can distinguish small mRNA particles from completely degraded RNA.
The Qubit RNA IQ Assay was developed to quickly assess the integrity and quality (IQ) of an RNA sample. It uses two dyes: one that binds to large, intact, and/or structured RNA, the other to small, degraded RNA. No special handling, tedious sample preparation, or waiting for results is required.
The Qubit Protein Assay Kits are designed to make protein quantification easy and accurate. Addressing overlapping concentration ranges, the two kits together are accurate for initial sample concentrations from 12.5 μg/mL to 20 mg/mL and exhibit low protein-to-protein variation. Qubit protein assays are easy to perform and require only 10–15 minutes of room temperature incubation, eliminating long incubation periods or exposure to elevated temperatures.
Qubit Endotoxin Detection Assay, designed for use with the Qubit Flex Fluorometer, offers an efficient, fluorescent endpoint assay to quantify endotoxin in various sample types such as protein, peptides, antibodies or nucleic acid samples. The assay can be run with variable sample volume, offering a dynamic range from 0.01-10.0 EU/mL using a streamlined workflow. Key features and benefits of the Qubit Endotoxin Detection Assay Kit include:
Product | Unit size | Cat. No. |
---|---|---|
Qubit Endotoxin Detection Assay Kit* |
80 assays |
Q32891 |
Qubit Flex Pyrogen-Free Tube Strips |
120 tube strips | Q32893 |
Qubit Flex Endotoxin Detection Starter Kit | 1 kit | Q32894 |
* Use Qubit Flex System Verification Assay Kit (Cat. No. Q33254) prior to first assay run on the Qubit Flex
Invitrogen Qubit System Verification Kits are fast, easy-to-use, reagent-based assays that test the performance of the Qubit 4 and Qubit Flex Fluorometers. The three components include a blank reagent solution, a green fluorescent reagent, and a far-red fluorescent reagent. The green fluorescent reagent is designed to test the blue excitation (470 nm LED; 430-495 nm excitation filter) and green fluorescence detection (510-580 nm emission filter) on the fluorometer, while the far-red fluorescent reagent is designed to test the red excitation (635 nm LED; 600-645 nm excitation filter) and far-red fluorescence detection (665-720 nm emission filter).
Product |
Initial sample concentration |
Quantitation range |
No. of assays |
Cat. No. |
Qubit 4 System Verification Assay Kit |
N/A |
N/A |
50 |
|
Qubit Flex System Verification Assay Kit |
N/A |
N/A |
25 |
Note: Each Qubit system verification assay can be used only with its specified Qubit Fluorometer and not with the other.
Custom MyQubit assays allow you to create additional assays for your Qubit Fluorometer in minutes. Reagent or assays that are spectrally compatible with the Qubit hardware can be adapted for use with the Invitrogen Qubit Fluorometer. Several preconfigured MyQubit assays are also available for download.
MyQubit assays bring customized fluorescence assays right to your benchtop, providing a reliable platform for many quantitation needs, from laboratory research and quality control to process monitoring and beyond. You can add new assays to your Qubit 3.0 and 4 Fluorometer via simple download and transfer of .qbt files using a USB drive.
MyQubit Assay Design Tool
The MyQubit Assay Design Tool helps you create custom MyQubit assay .qbt files that you can upload to your Qubit 3.0 and 4 Fluorometer.
As examples of the kinds of custom MyQubit assays you can create, we have developed new MyQubit assays for several commonly quantitated analytes using Amplex Red reagents. When you transfer the assay .qbt files to your Qubit Fluorometer via a USB drive, they will be available alongside the factory-loaded Qubit assays, extending the capabilities of your Qubit Fluorometer.
Assay |
Download for Qubit 3.0 and 4 |
Download for Qubit 2.0* |
PDF manual |
Amplex Red Cholesterol Assay |
|||
Amplex Red Galactose Assay |
|||
Amplex Glucose Assay |
|||
Amplex Red Glutamic Acid Assay |
|||
Amplex Red Peroxide Assay |
|||
Amplex Red Sucrose Assay |
* The Qubit 2.0 Fluorometer requires a USB flash drive of 2 GB or less, such as the one provided with the instrument, to transfer MyQubit files.
To download the .qbt file, click on the .qbt file link of interest in the table. It will automatically download to your computer. Make sure you click the correct link for your Qubit model. Consult the assay’s PDF manual for instructions on uploading the .qbt file to your Qubit Fluorometer.
In the Ion Torrent method of next-generation sequencing (NGS), multiple copies of each amplicon are created on an Ion Sphere Particle (ISP) during template preparation. Before sequencing DNA or RNA, it’s important to know the amount of template positive ISPs.
The Ion Sphere Quality Control Kit enables quick and easy assessment of enriched ISPs on your Qubit Fluorometer prior to performing an NGS run on the Ion Personal Genome Machine (PGM) or Ion GeneStudio System. ISPs bind a complimentary, green-fluorescent Invitrogen Alexa Fluor 488 dye–labeled oligonucleotide, whereas only those beads that are template-positive bind a complementary red-fluorescent Invitrogen Alexa Fluor 647 dye–labeled oligonucleotide.
Product |
No. of assays |
Cat. No. |
Ion Sphere Quality Control Kit (Qubit 4 only) |
20 |
The Qubit Fluorometer measures the fluorescence emission of each dye conjugate, and an Excel file template is used to calculate the percentage of template-positive ISPs from the ratio of the Alexa Fluor 647 dye signal to the Alexa Fluor 488 dye signal. This quality-control step using a Qubit fluorometer helps to determine the likelihood of a successful sequencing run, ultimately saving time and expense during subsequent sequencing.
Ion Sphere Particle assay principle
The B nucleic acid sequence is present in both the ISP primer and the template and is used to drive the amplification of the template onto the bead, while the A sequence is present only in the template. Using Invitrogen Alexa Fluor dyes, the ratio of fluorescence signals from nucleotides labeled with Alexa Fluor 647 (red) and Alexa Fluor 488 (green) dyes is used to determine the relative quantity of template-positive particles.
For Research Use Only. Not for use in diagnostic procedures.