Novex™ Tris-Glycine Mini Protein Gels, 10%, 1.0 mm, 2D-well

Novex™ Tris-Glycine polyacrylamide gel chemistry is based on the Laemmli system (1) with minor modifications for maximum performance in theRead more

Catalog Number	Quantity
EC6076BOX	10 gels (1 box)

Catalog number EC6076BOX

Price (JPY)

29,500

Quantity:

10 gels (1 box)

Novex™ Tris-Glycine polyacrylamide gel chemistry is based on the Laemmli system (1) with minor modifications for maximum performance in the pre-cast format. These gels do not contain SDS and can therefore be used to accurately separate both native and denatured proteins. Novex™ Tris-Glycine Gels provide reproducible separation of a wide range of proteins into well-resolved bands.

Formulation: Novex™ Tris-Glycine Gels are made with high-purity, strictly quality-controlled reagents: Tris base, HCl, acrylamide, bisacrylamide, TEMED, APS, and highly purified water. They do not contain SDS.

Recommended Buffers: By choosing the appropriate Novex™ pre-mixed buffer, you can create either native, denaturing or reducing running conditions with any Novex™ Tris-Glycine Gel.

For Research Use Only. Not for use in diagnostic procedures.

Specifications

For Use With (Equipment)Mini Gel Tank, XCell SureLock Mini-Cell

Gel Thickness1.0 mm

Length (Metric)8 cm

Length (Metric) Gel8 cm

Mode of SeparationMolecular Weight

Quantity10 gels (1 box)

Shelf Life8 Weeks

Shipping ConditionWet Ice

Thickness1.0 mm

Well Design2D Well

Width (Metric)8 cm

Width (Metric) Gel8 cm

Gel Percentage10%

Gel SizeMini

Gel TypeTris-Glycine

Product LineNovex

Product TypeHomogeneous Page

Separation Range30 to 250 kDa

Separation TypeDenaturing, Native

Separation ofProtein

System TypeZOOM

Wells1-well

Unit SizeEach

Contents & Storage

One box contains 10 gels. Store in refrigerator (2–8°C). Do not freeze. Shelf life is 8 weeks.

Frequently asked questions (FAQs)

What does it mean when bands appear to be getting narrower (or "funneling") as they progress down a protein gel?

There may be too much beta-mercaptoethanol (BME), sample buffer salts, or dithiothreitol (DTT) in your samples. If the proteins are over-reduced, they can be negatively charged and actually repel each other across the lanes causing the bands to get narrower as they progress down the gel.

Find additional tips, troubleshooting help, and resources within our Protein Electrophoresis and Western Blotting Support Center.

What is meant by the terms "Straightness" and "Curvature" on the Certificate of Analysis for a Invitrogen protein gel?

Gel straightness is defined as the straightness across all lanes of the gel, measured at the bottom, expressed relative to the total length of the gel. For example, a gel with straightness of 0.020 Rf is flat to within 2% of the length of the gel (1.6 mm) across. Band curvature is defined as the curvature of the bands in the outer lanes of the gel, expressed relative to the total length of the gel. For example, bands with curvature of 0.010 Rf are straight to within 1% of the length of the gel (0.8 mm).

Find additional tips, troubleshooting help, and resources within our Protein Electrophoresis and Western Blotting Support Center.

What procedures are carried out for QC of Invitrogen gels?

The QC of our gels includes several processes:

1) Each gel is checked by eye for visible anomalies.

2) Under defined conditions, gels retained from each lot are tested as follows:

--When gels are run at a defined voltage, the resulting current and power of the electrophoresis are measured.

--Protein samples are electrophoresed on test gels to determine the gel run time and the protein band quality after electrophoresis. Bands are examined for: straightness within bands, curvature of bands across the gel ("smiling" or "frowning"), and reproducibility of the Rf values for protein molecular weight markers. According to these results, a Certificate of Analysis is created, which is available upon request.

Find additional tips, troubleshooting help, and resources within our Protein Electrophoresis and Western Blotting Support Center.

After western detection, my membrane has a lot of spots. What could have gone wrong?

Here are possible causes and solutions:

- Membrane blotting pads are dirty or contaminated. Soak pads with detergent and rinse thoroughly with purified water before use. Replace pads when they become worn or discolored.
- Blocking was uneven. The incubation dish must be sufficiently big to allow thorough coverage of membrane. Shake or agitate during each step.

Find additional tips, troubleshooting help, and resources within our Protein Assays and Analysis Support Center.

I am getting a lot of non-specific binding after western detection. Can you offer some tips?

Here are possible causes and solutions:

- Membrane contaminated by fingerprints or keratin proteins: Wear clean gloves at all times and use forceps when handling membranes. Always handle membranes around the edges.
- Concentrated secondary antibody used: Make sure the secondary antibody is diluted as recommended. If the background remains high, but with strong band intensity, decrease the concentration of the secondary antibody.
- Concentrated Primary antibody used: Decrease the concentration of the primary antibody.
- Affinity of the primary antibody for the protein standards: Check with the protein standard manufacturer for homologies with primary antibody.
- Insufficient removal of SDS or weakly bound proteins from membrane after blotting: Follow instructions for membrane preparation before immunodetection.
- Short blocking time or long washing time: Make sure that each step is performed for the specified amount of time.

Find additional tips, troubleshooting help, and resources within our Protein Assays and Analysis Support Center.

View all Novex™ Tris-Glycine Mini Protein Gels, 10%, 1.0 mm, 2D-well FAQs