Qubit™ RNA High Sensitivity (HS), Broad Range (BR), and Extended Range (XR) Assay Kits
Qubit™ RNA High Sensitivity (HS), Broad Range (BR), and Extended Range (XR) Assay Kits
実際の製品は異なる場合があります
Qubit™ RNA High Sensitivity (HS), Broad Range (BR), and Extended Range (XR) Assay Kits
Qubit™ RNA High Sensitivity (HS), Broad Range (BR), and Extended Range (XR) Assay Kits
Qubit™ RNA High Sensitivity (HS), Broad Range (BR), and Extended Range (XR) Assay Kits
Qubit™ RNA High Sensitivity (HS), Broad Range (BR), and Extended Range (XR) Assay Kits
Citations & References (12)
Invitrogen™

Qubit™ RNA High Sensitivity (HS), Broad Range (BR), and Extended Range (XR) Assay Kits

キットを使用すると、低存在量および高存在量のRNAを迅速かつ高感度に検出でき、RNAとDNA、タンパク質、および遊離ヌクレオチドを識別できます。
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製品番号(カタログ番号)数量アッセイ
Q10210100 assaysRNA Quantification, broad range
Q10211500 assaysRNA Quantification, broad range
Q33223100 assaysRNA Quantification, extended range
Q33224500 assaysRNA Quantification, extended range
Q32852100 assaysRNA Quantification, high sensitivity
Q32855500 assaysRNA Quantification, high sensitivity
製品番号(カタログ番号) Q10210
価格(JPY)
17,200
Each
お問い合わせください ›
数量:
100 assays
アッセイ:
RNA Quantification, broad range
Qubit RNA HS、BR、およびXR Assay Kitを使用すると、RNAを正確かつ精密に定量できます。これらのRNA定量キットを使用すると、低存在量および高存在量のRNAサンプルを迅速かつ選択的に検出でき、RNAとDNA、タンパク質、および遊離ヌクレオチドを識別できます。塩、溶媒、界面活性剤などの汚染物質に対し、十分に耐性があります。
Qubit RNA HS、BR、およびXR Assay Kitは、Qubit Fluorometer用に設計されており、DNA、タンパク質、および遊離ヌクレオチドよりもRNAに高い選択性を有しています。各キットとも、濃縮アッセイ試薬、希釈バッファー、および希釈済みRNA標準液が含まれています。付属のバッファーで試薬を希釈し、サンプル(1 μL~20 μLの任意の容量)を加え、Qubit Fluorometerで濃度を読み取るだけです。

Qubit RNA HS Assay Kit
Qubit RNA HS(高感度)Assay Kitは、Qubit Fluorometerと併用することにより、存在量の少ないRNAサンプルの正確かつ選択的な定量が可能となります。サンプル量に応じて、このアッセイキットはRNAサンプルの初期濃度が0.2~200 ng/μLで、4~200 ngの検出範囲を提供するように正確に設計されています。

Qubit RNA BR Assay Kit
Qubit RNA BR(広範囲)Assay Kitは、Qubit Fluorometerと併用することにより、RNAサンプルの正確かつ選択的な定量が可能となります。サンプル量に応じて、このアッセイキットはRNAサンプルの初期濃度が0.5~1,200 ng/μLで、10~1,200 ngの検出範囲を提供するように正確に設計されています。

Qubit RNA XR Assay Kit
Qubit RNA XR(拡張範囲)Assay Kitは、Qubit 4およびQubit Fluorometer用に設計されており、存在量の多いRNAサンプルの正確かつ選択的な定量が可能となります。サンプル量に応じて、このアッセイキットは5~20,000 ng/μLの初期RNAサンプル濃度に対して正確であるように設計されており、100~20,000 ngの検出範囲を実現します。


•Qubit RNA HSおよびBR Assayキットは、すべてのQubit Fluorometerで使用できます。
•Qubit RNA XR Assay Kitは、Qubit 4またはQubit Flex Fluorometerでのみ使用できるように設計されています。
• 薄壁、透明ウェル、0.5-mL PCRチューブ(カタログ番号Q32856)をQubit 4 Fluorometerに使用、8 x 200 μLのチューブストリップ(カタログ番号Q33252)をQubit Flex Fluorometerに使用してください
For Research Use Only. Not for use in diagnostic procedures.
仕様
アッセイRNA Quantification, broad range
励起/発光644/673
使用対象 (装置)Qubit Fluorometer
反応数100反応
製品ラインQuant-iT
定量範囲10~1200 ng
数量100 assays
出荷条件室温
検出法蛍光
Unit SizeEach

よくあるご質問(FAQ)

I'm seeing other kit-related problems besides the "Standards incorrect" message with my Qubit assay. What do you suggest I try?

Here are several suggestions:

1.View the raw fluorescence value (RFU) for the standards under “Check Standards” or “Check Calibration”. Confirm that the values for the samples fall between the values of the standards (or a little above the highest standard). If they do not, the sample is out of the accurate range of the assay. Refer to the confidence ranges for each assay in the product manuals. The readout in the assay will be to 2 significant figures instead of 3 if the assay sample is out of the high confidence range.
To bring the sample into the accurate range, dilute the sample or use more or less of it (for example, 10 µL instead of 2 µL if the sample reads low).

2.Check for temperature issues: The assay is temperature sensitive and the fluorescent signal can decrease at higher temperatures. Temperature fluctuations between samples, or between samples and standards, can cause problems. Make sure that the buffer and Qubit reagent in DMSO are at room temperature. The buffer and Qubit reagent should be stored at room temperature, not in the refrigerator. Even after 2-3 hours at room temperature, buffer previously stored at 4°C can remain below room temperature. Make sure your samples and working solution are not too warm (including those straight from a centrifuge). Samples kept in the Qubit instrument too long or read multiple times can warm up. If you want to perform multiple readings of a single tube, you should remove the tube from the instrument and let it equilibrate to room temperature for 30 seconds before taking another reading. Also, do not hold tubes in your hand for very long before reading them in the instrument, since this can warm the sample, resulting in a low reading.

3.Ensure that you have prepared the Qubit working solution correctly (1:200 dilution using the buffer provided in the kit). Ensure that you have prepared the standard tubes correctly (10 µL of each standard in 190 µL of the working solution). Ensure that the tubes are filled with at least 200 µL (both standards and samples).

4.Ensure that the reagents and standards you are using are less than 6 months old, and that the standards have been stored correctly. The Qubit reagent stock solution should be protected from light as much as possible.

5.Ensure that you have selected the correct assay on the Qubit Fluorometer for the Qubit assay you are performing.

6.Ensure that the lid is completely closed when reading standards and samples.

7.Use recommended tubes (both so the tube does not obstruct the lid, and for optical clarity). Some types of tubes can have high autofluorescence that will affect the assay.

8.Did you enter the number of microliters of stock you pipetted into the working solution into the Qubit instrument? If so, the reading after giving the Qubit Fluorometer this information is the concentration of your stock solution. If you did not, the reading you got is for the concentration in the assay tube (the tube you put into the Qubit Fluorometer) and not your stock solution.

9.If you are comparing Qubit assay results to concentration obtained by UV absorbance, and the concentration based on absorbance is significantly higher, it may be because of nucleic acid or protein contamination. The Qubit assays are much more specific for DNA, RNA, or protein than absorbance readings.

The value is decreasing over time when using the Qubit Fluorometer. What could be causing this?

Please see our suggestions below:

  • Make sure that you take your reading only after incubating for at least 2 minutes (15 minutes for protein).
  • If you leave the assay tube in the Qubit Fluorometer and take multiple readings, the readings will go down as the tube heats up inside the instrument. If you want to take multiple readings, remove the tube from the instrument, place it in a tube rack, and allow it to equilibrate to room temperature for at least 30 seconds before rereading the tube.
  • You may read the sample up to 3 hours after mixing if it is protected from light. After this time, the reading will not be accurate.
  • Keep standards and sample tubes in the dark and protected from light in between readings.

    Find additional tips, troubleshooting help, and resources within ourNucleic Acid Quantification Support Center.

    • What are the excitation/emission wavelengths for dyes in the Qubit Assays?

    The exact excitation/emission wavelength information is proprietary. Here are the approximate excitation/emission wavelengths:

    - Qubit dsDNA HS Assay: ~500 nm/ ~530 nm
    - Qubit dsDNA BR Assay: ~510 nm/ ~530 nm
    - Qubit ssDNA Assay: ~490 nm/ ~520 nm
    - Qubit RNA HS Assay: ~640 nm/ ~670 nm
    - Qubit RNA BR Assay: ~640 nm/ ~670 nm
    - Qubit microRNA Assay: ~500 nm/ ~520 nm
    - Qubit Protein Assay: ~470 nm/ ~570 nm

    Find additional tips, troubleshooting help, and resources within our Nucleic Acid Quantification Support Center.

    Can I make my own assay for the Qubit Fluorometer?

    Yes, you can, for Qubit instruments developed after the original Qubit (1.0) Fluorometer. See MyQubit assay instructions here (http://www.thermofisher.com/us/en/home/life-science/laboratory-instruments/fluorometers/qubit/qubit-assays/myqubit.html.html).

    I have a crude lysate. Will the Quant-iT and Qubit assays work?

    Generally, the cleaner the sample the better. Some salts, proteins, and detergents are tolerated in the assays; see the specific assay protocol for which ones and at what concentrations.

    View all Qubit™ RNA High Sensitivity (HS), Broad Range (BR), and Extended Range (XR) Assay Kits FAQs

    引用および参考文献 (12)

    引用および参考文献
    Abstract
    Comparative transcriptome analysis of field- and chamber-grown samples of Colobanthus quitensis (Kunth) Bartl, an Antarctic flowering plant.
    Authors:Cho SM, Lee H, Jo H, Lee H, Kang Y, Park H, Lee J
    Journal:Sci Rep
    PubMed ID:30038328
    'Colobanthus quitensis is one of the two vascular plants inhabiting the Antarctic. In natural habitats, it grows in the form of a cushion or mats, commonly observed in high latitudes or alpine vegetation. Although this species has been investigated over many years to study its geographical distribution and physiological adaptations ... More
    Enrichment post-library preparation enhances the sensitivity of high-throughput sequencing-based detection and characterization of viruses from complex samples.
    Authors:Paskey AC, Frey KG, Schroth G, Gross S, Hamilton T, Bishop-Lilly KA
    Journal:BMC Genomics
    PubMed ID:30808306
    'Sequencing-based detection and characterization of viruses in complex samples can suffer from lack of sensitivity due to a variety of factors including, but not limited to, low titer, small genome size, and contribution of host or environmental nucleic acids. Hybridization-based target enrichment is one potential method for increasing the sensitivity ... More
    Transcriptomic study of Herpes simplex virus type-1 using full-length sequencing techniques.
    Authors:Boldogkoi Z, Szucs A, Balázs Z, Sharon D, Snyder M, Tombácz D
    Journal:Sci Data
    PubMed ID:30480662
    Herpes simplex virus type-1 (HSV-1) is a human pathogenic member of the Alphaherpesvirinae subfamily of herpesviruses. The HSV-1 genome is a large double-stranded DNA specifying about 85 protein coding genes. The latest surveys have demonstrated that the HSV-1 transcriptome is much more complex than it had been thought before. Here, ... More
    Benchmarking single cell RNA-sequencing analysis pipelines using mixture control experiments.
    Authors:Tian L, Dong X, Freytag S, Lê Cao KA, Su S, JalalAbadi A, Amann-Zalcenstein D, Weber TS, Seidi A, Jabbari JS, Naik SH, Ritchie ME
    Journal:Nat Methods
    PubMed ID:31133762
    Single cell RNA-sequencing (scRNA-seq) technology has undergone rapid development in recent years, leading to an explosion in the number of tailored data analysis methods. However, the current lack of gold-standard benchmark datasets makes it difficult for researchers to systematically compare the performance of the many methods available. Here, we generated ... More
    A Designed Small Molecule Inhibitor of a Non-Coding RNA Sensitizes HER2 Negative Cancers to Herceptin.
    Authors:Costales MG, Hoch DG, Abegg D, Childs-Disney JL, Velagapudi SP, Adibekian A, Disney MD
    Journal:J Am Chem Soc
    PubMed ID:30726072
    A small molecule (1) with overlapping affinity for two microRNA (miRNA) precursors was used to inform design of a dimeric compound (2) selective for one of the miRNAs. In particular, 2 selectively targets the microRNA(miR)-515 hairpin precursor to inhibit production of miR-515 that represses sphingosine kinase 1 (SK1), a key ... More
    View all Qubit™ RNA High Sensitivity (HS), Broad Range (BR), and Extended Range (XR) Assay Kits citations