4000-520-616
欢迎来到免疫在线!(蚂蚁淘生物旗下平台)  请登录 |  免费注册 |  询价篮
BioMatrix(优势品牌)
主营:胶原蛋白、纤连蛋白、玻连蛋白、水性凝胶、低代成纤维细胞
咨询热线电话
4000-520-616
当前位置: 首页 > 产品中心 > Electrophysiological > 高级生物矩阵/PureCol®-S//5015-20ML
商品详细高级生物矩阵/PureCol®-S//5015-20ML
高级生物矩阵/PureCol®-S//5015-20ML
高级生物矩阵/PureCol®-S//5015-20ML
商品编号: 5015-20ML
品牌: BioMatrix
市场价: ¥4700.00
美元价: 2820.00
产地: 美国(厂家直采)
公司:
产品分类: 电生理设备
公司分类: Electrophysiological
联系Q Q: 3392242852
电话号码: 4000-520-616
电子邮箱: info@ebiomall.com
商品介绍

Product Description

PureCol®-S collagen is provided as a standard for use in assays where ultra-pure collagen is required.PureCol®-S collagen standard is approximately 97% Type I collagen with the remainder being comprised of Type III collagen. It contains a high monomer content as measured by gel permeation chromatography. This product is supplied at approximately a 3 mg/ml concentration. The concentration is confirmed by Biuret protein determination assay. The concentration for each specific lot is provided on a Certificate of Analysis that is available with the purchase of each product.PureCol®-Sis soluble atelo-collagen in 0.01 N HCI, therefore, the pH is approximately 2.0.

PureCol®-S is ideal for using as a collagen standard in controlled testing and assay procedures.PureCol®-Sis sterile filtered and is supplied as a ready to use solution.

Parameter, Testing, and MethodPureCol®-S Collagen Standard #5015
Sterilization MethodFiltration
Extraction MethodEnzyme - atelocollagen
FormSolution
Package Size20 mL
Storage Temperature2-10°C
Shelf LifeMinimum of 6 months from date of receipt

Collagen Concentration - Biuret

2.9-3.2 mg/mL

Collagen Concentration - AAA

2.9-3.2 mg/mL

Collagen Purity - Silver Staining

>99.9%
pH1.9-2.1
Kinetic Gel Test (Minutes)<40
Gel Formation Tube Test (Minutes)<40

Fibrillogenesis(Absorbance Units)

>0.5

Electrophoretic Pattern - Coomassie Blue

Characteristic
Sterility - USP modifiedNo growth
Endotoxin -LAL<1.0 EU/mL
Osmolality (mOsmo H2O/kg)<35
SourceBovine Hide
Hydrogel Young's Modulus E (Pa)Characteristic

Directions for Use

Download the full PDF versionor continue reading below:

Coating Procedure

Note: Use these recommendations as guidelines to determine the optimal coating conditions for your culture system.

  1. Remove required quantity of collagen from the bottle and dispense into a dilution vessel.
  2. Dilute PureCol®-S in water to ~50 to 100 µg/ml (~1:30). A 0.01 N HCl solution may also be used.
  3. Swirl contents gently until material is completely mixed.
  4. Add appropriate amount of diluted PureCol®-S material to the culture surface ensuring that the entire surface is coated.
  5. Incubate at room temperature, covered, for 1-2 hours. Aspirate any remaining material. Alternatively, incubate at room temperature until surface is dry.
  6. Rinse coated surfaces carefully with sterile medium or PBS, avoid scratching surfaces.
  7. Coated surfaces are ready for use. They may also be stored at 2-8°C damp or air dried if sterility is maintained.

3-D Gel Preparation Procedure

  1. Slowly add 1 part of chilled 10X PBS or 10X culture media to 8 parts of chilled collagen solution with gentle swirling.
  2. Adjust pH of mixture to 7.2–7.6 using sterile 0.1 M NaOH. Monitor pH adjustment carefully (pH meter, phenol red, or pH paper).
  3. Adjust final volume to a total of 10 parts with sterile water.
  4. To prevent gelation, maintain temperature of mixture at 2–10°C.
  5. To form gel, warm to 37°C. Allow approximately 90 to 120 minutes for gel formation.

Product Q & A

The purity of PureCol® collagen is determined by SDS-PAGE, sodium dodecyl sulfate polyacrylamide gel electrophoresis in conjunction with bacterial collagenase sensitivity and silver staining techniques with a method sensitivity of 99.9%. It was found that PureCol® collagen is 95 to 98% Type I collagen and the remainder being comprised of Type III collagen.

SDS polyacrylamide gel electrophoresis demonstrates the presence of alpha, beta and gamma components in an appropriate ratio of approximately 40:30:30, respectively. PureCol® collagen is a native collagen as judged by polarimetry and trypsin sensitivity although the product does contain a low percentage of collagen fragments or shortened helices.

Conclusion: With the test method sensitivity of 99.9% (SDS-PAGE gel electrophoresis in conjunction with bacterial collagenase sensitivity and silver staining techniques) and no other proteins present in the preparation, it can be concluded that the purity of the PureCol® collagen is 99.9%.

The viscosity of PureCol® is ~32 cp.

PureCol® product has an isoelectric zone instead of isoelectric point. The isoelectric zone is pH 7 to 8. In addition, the collagen molecules in the PureCol® product will come out ofsolution starting at a pH above 5.5 and reach its plateau at pH 7 to 8 then gradually tapering off at pH 8 to 9.5.

Reduction of a commercially available, pepsin-solubilized, bovine dermal collagen (Vitrogen 100) (PureCol’s old product name) with sodium [3H]borohydride provided radiolabeled collagen preparations with specific activities ranging from 7.1-12.0 muCi/mg collagen. These specific activities were 2-3 times greater than those obtained by reduction of intact rat tail tendon collagen under similar conditions.

The alpha, beta, and higher aggregate components of type I collagen were radiolabeled as well as the alpha component of a small amount of type III collagen present in the samples. Fractionation of cyanogen bromide peptides showed that alpha 1(I)CB7, alpha 1(I)CB8, and alpha 2(I)CB3,5 were the predominant peptides labeled by this procedure. Amino acid analysis indicated that the majority of the radioactivity was in reducible cross-links, precursors of these cross-links, and in hexosyllysine residues.

Reconstitution experiments comparing this radiolabeled collagen with nonlabeled collagen showed them to be indistinguishable. Bacterial collagenase digestion of this reconstituted fibrillar collagen in both a lightly cross-linked (glutaraldehyde 0.0075%) and noncross-linked form provided evidence that digestion of labeled and nonlabeled collagens proceeded at similar rates. Thus, labeling did not change the properties of the collagen. Cross-linking made the preparation refractory to proteolytic degradation. Injection of fibrillar collagen preparations, spiked with radiolabeled collagen, into the guinea pig dermis followed by quantitation of the amount of radioactivity recovered from implant sites as a function of time, indicated that the lightly cross-linked samples also were more resistant to degradation in vivo than the noncross-linked preparation.

The half-life of noncross-linked collagen was about 4 days while that of the cross-linked collagen was about 25 days. These degradation rates were much faster than observed for similar, nonlabeled samples injected into the dermis of humans, presumably due to a higher metabolic activity in the guinea pig dermis.

Since the collagen in PureCol collagen contains approximately 95% Type I bovine collagen and 5% Type III bovine collagen, an anti-bovine collagen Type I antibody for your study can be used.

There is no difference. Vitrogen was the old tradename, and PureCol®is the new tradename.

We completed a study to show that DNA is completely destroyed at pH 2, and demonstrated that our collagen products do not contain DNA.

The collagen is fully hydrolyzed. The amino acid analysis is done using the Waters AccQ-Tag derivatization method.During the acid hydrolysis step, asparagine (N) is converted to aspartic acid (D) and glutamine (Q) is converted to glutamic acid (E). Tryptophan (W), if present, is destroyed during acid hydrolysis. Experimentally, one can determine the picomoles (pmol) of each amino acid per injected detected using amino acid standards.For the concentration determination, the total number of pmol of each amino acid is summed to get the total pmol of the 18 amino acids detected. The total pmol amino acids is divided by the theoretical number of amino acid residues in collagen based on the published sequence. The result is the pmol of collagen injected. The result is then multiplied by the dilution and 300,000 is used as the collagen molecular weight to get to mg/mL. The molecular weight of collagen is not well agreed upon.

Diluting with 1X PBS (rather than water or 0.01 N HCl) would have an effect for coating purposes. It would change the pH of the diluted collagen solution from acid to neutral pH. The pH change will transform the collagen molecules from a molecular form to a fibrillar form; and then the nature of coating surface will be changed from a monomeric coating to a fibrillar coating.

We use thefollowing antibodies from SouthernBiotech:

1. 1310-02 – Goat Anti-Type I Collagen-FITC

2. 1310-08 – Goat Anti-Type I Collagen-BIOT

3. 7100-05 – Streptavidin-HRP

The major collagen molecular species in our Type I collagen products are monomers (approx. 70%), but there are dimers, trimers and a few percentages of oligomers too (approx. 30%) with some minor amounts of collagen fragments. The collagen monomer is a rod shaped molecule with 300 nm in length and 1.5 nm in diameter. The dimer, trimer and oligomer are 600 nm, 900nm and even longer in length respectively. According to the coating procedures, the collagen molecules are attached to the charged polystyrene surface randomly by charge or affinity in acid conditions during the 1-2 hrs incubation period at 37°C, and any unattached materials are removed by aspiration and rinsing. Therefore, the coated surface is a single layer of collagen monomer, dimer, trimer and oligomer mixtures.The thickness of the mono-molecular layer is dependent on how those molecules are attached on the surface. The coating density thickness would generally be characterized as a 1 molecule thickness which could be ranging from a few nanometers to a few hundred nanometers with the whole surface being covered by collagen.

The net charge of Type I collagen products’ (PureCol®, Bovine Collagen and VitroCol®, Human Collagen) molecule is directly related to the pH. At an acidic pH, the amino acids (zwitterions) along the collagen molecule are positively charged, making the entire collagen molecule positive. At the isoelectric point (or zone) of collagen, around pH 7-8, the amino acids along the collagen molecule are positively and negatively charged, making the net charge of the collagen molecule close to zero. At a basic pH, the amino acids along the collagen molecule were negatively charged, making the entire collagen molecule negative.

Further, the nature of the charge of the collagen coating surface will be dependent on the type of coating applied. For a monomeric collagen coatings when the collagen is applied under an acidic pH condition, the surface is positively charged. If the surface is rinsed with pH neutral buffer or media then it will change the charge of the collagen surface net charge close to zero. For a 3D gel coating, the collagen prepared under neutral pH; the net charge of the collagen surface is close to zero.

Using rotary shadowing technique under transmission electron microscopy, it was found that our collagen, on average, consists of approximately 80% monomers, 13% dimers, trimers, and oligomers with the remaining 7% collagen fragments.

Yes.The collagen molecule in PureCol, Nutragen, VitroCol, and all of our other Atelo collagen products were prepared from native collagen matrix by pepsin treatment under controlled conditions to remove the non-helical portion, telo-peptides, only and the helical portion is intact. In this case, the enzymatic active sites for MMP (Matrix Metalloproteinase), such as for Mammalian Collagenase Matrix Metalloproteinase 8 (MMP-8), on the molecule was preserved.

These pepsin treated collagen products should behave as native intact collagen.

TGF beta would have been digested with the pepsin enzymatic digestion step. It was undetectable by SDS PAGE silver stain as well. We didn’t do any specific measurements by ELISA however but presences of TGF betais not anticipated.

We primarily use the Biuret method, but we also use BCA, AAA, and hydroxyl-proline assays.

- Collagen solutions that are frozen tend to have issues forming 3D hydrogels, and will likely not work. The solutions should still be good for 2D coatings.

- Collagen solutions that are left out at room temperature for extended periods of time may show signs of degradation, which will affect the formation of 3D hydrogels. It is likely still fine for 2D coatings.

Our recommendation is this: If you are using the product directly for a publication, we highly suggest buying a new bottle if the one you have was compromised.

Product References

Because PureCol® has been cited in over 2000 publications, we have only posted a few below:

Sorensen, Jacob R., et al. "An altered response in macrophage phenotype following damage in aged human skeletal muscle: implications for skeletal muscle repair."The FASEB Journal(2019): fj-201900519R.

Sorensen, Jacob R., et al. "An altered response in macrophage phenotype following damage in aged human skeletal muscle: implications for skeletal muscle repair."The FASEB Journal(2019): fj-201900519R.

Colaço, E., et al. "Hierarchical Collagen-Hydroxyapatite Nanostructures Designed Through Layer-by-Layer Assembly of Crystal-Decorated Fibrils."J., Hierarchical Collagen-Hydroxyapatite Nanostructures Designed Through Layer-by-Layer Assembly of Crystal-Decorated Fibrils (May 13, 2019)(2019).

Schwerdtfeger, Luke A., et al. "Human colon function ex vivo: Dependence on oxygen and sensitivity to antibiotic."PloS one14.5 (2019): e0217170.

Cardoso, Ana, et al. "MiR-144 overexpression as a promising therapeutic strategy to overcome glioblastoma cell invasiveness and resistance to chemotherapy."Human molecular genetics(2019).

Steele, Hannah E., et al. "Mechanotransduction of mitochondrial AMPK and its distinct role in flow-induced breast cancer cell migration."Biochemical and biophysical research communications514.2 (2019): 524-529.

Gehwolf, Renate, et al. "Global Responses of Il-1β-Primed 3D Tendon Constructs to Treatment with Pulsed Electromagnetic Fields."Cells8.5 (2019): 399.

Alexander, Frank, Sebastian Eggert, and Dorielle Price. "Label-Free Monitoring of 3D Tissue Models via Electrical Impedance Spectroscopy." (2019): 1-24.

Matysik-Woźniak, Anna, et al. "Examination of Kynurenine Toxicity on Corneal and Conjunctival Epithelium: In vitro and in vivo Studies."Ophthalmic research(2019): 1-12.

Compton, Clayton, et al. "Reconstitution of the Ventricular Endocardium Within Acellular Hearts."Regenerative Engineering and Translational Medicine(2019): 1-11.

Müller, A. L., et al. "4. Identification of miR-301a in Primary Human Atrial Fibroblasts and Bone Marrow-Derived Mesenchymal Progenitor Cells to Attenuate Endogenous Differentiation into Pro-Fibrotic Cells."Differentiation of Primary Human Pro-Fibrotic Mesenchymal Cells Influenced by Extracellular Matrix Environment Determined by Micro-RNA Expression(2018): 130.

Doblinger, Nina, et al. "Impact of hydroxyethyl starch and modified fluid gelatin on granulocyte phenotype and function."Transfusion(2019).

Elisabeth, et al. "Pro-Inflammatory Responses in Human Bronchial Epithelial Cells Induced by Spores and Hyphal Fragments of Common Damp Indoor Molds."International journal of environmental research and public health16.6 (2019): 1085.

Dodmane, Puttappa R., et al. "Biphasic changes in airway epithelial cell EGF receptor binding and phosphorylation induced by components of hogbarn dust."Experimental lung research44.10 (2018): 443-454.

McClellan, Alyce, et al. "A novel mechanism for the protection of embryonic stem cell derived tenocytes from inflammatory cytokine interleukin 1 beta."Scientific reports9 (2019).

Wang, Weiling, et al. "Aquaporin-3 deficiency slows cyst enlargement in experimental mouse models of autosomal dominant polycystic kidney disease."The FASEB Journal(2019): fj-201801338RRR.

Teo, Jye Yng, et al. "Surface tethering of stem cells with H2O2-responsive anti-oxidizing colloidal particles for protection against oxidation-induced death."Biomaterials201 (2019): 1-15.

Gehwolf, Renate, et al. "3D-Embedded Cell Cultures to Study Tendon Biology." (2019): 1-11.

Product Certificate of Analysis

No result for .

Product Videos

link to library blog - How to Make 3D Collagen Hydrogels
How to Make 3D Collagen Hydrogels

Video

link to library blog - Seeding Collagen Gels with Cells
Seeding Collagen Gels with Cells

Video

link to library blog - 30+ Type I Collagen Options
30+ Type I Collagen Options

Video

link to library blog - Coating a Glass Coverslip with Collagen
Coating a Glass Coverslip with Collagen

Video

See More

Safety and Documentation

Safety Data Sheet

Certificate of Origin

Declaration of Material Source

Product Disclaimer

This product is for R&D use only and is not intended for human or other uses. Please consult the Material Safety Data Sheet for information regarding hazards and safe handling practices.

品牌介绍
美国Advanced BioMatrix是3D组织培养、细胞检测和细胞增殖等领域实验解决方案的佼佼者。Advanced BioMatrix在分离、纯化、冻干、细胞培养和蛋白检测、多肽粘附、附着因子、基质硬度和其他3D matrix 产品开发方面有着丰富的经验。Advanced BioMatrix的研发经验和专业知识确保其产品可达到最佳质量,并保证产品之间一致性,方便研究客户使用。 以下为Advanced BioMatrix 3D Matrices 产品竞争优势: 1. 提供高纯度和成分确定的胞外基质; 2. 超过1000余篇文献引用PureCol产品,品质非常均一; 3. 在3D培养基领域可提供最全面的产品线; 4. 唯一可提供特异性刚性有机硅基板的公司(CytoSoft); 5. 唯一可提供可溶性丝纤蛋白的供应商(可运用于多种3D培养); 6. 如果客户首次接触3D胶原凝胶,Advanced BioMatrix还是唯一的预制胶原蛋白(PureCol EZ Gel)供应商。 以下产品为Advanced BioMatrix全球畅销品: 1. PureCol 牛源I型胶原蛋白 3 mg/ml #5005-100ML 2. Nutragen牛源I型胶原蛋白 6 mg/ml #5005-100ML 3. FibriCol 牛源I型胶原蛋白 10 mg/ml #5133-20ML 4. VitroCol 人源I型胶原蛋白 #5007-20ML 5. 弹性蛋白原 #5052-1MG 6. ECM Select Array kit Ultra-36 #5170-1EA 7. CytoSoft(刚性可变的基底,Advanced BioMatrix最新添加产品5190-7EA) 8. 人III型胶原蛋白 #5021-10MG 9. 人IV型胶原蛋白 #5022-5MG 10. Silk Fibroin溶液 #5154-20ML 11. Fibronectin #5080-5MG 12. Vitronectin #5051-0.1MG Advanced BioMatrix最畅销的产品是PureCol(5005-100ML)。目前已有上千发表的论文使用这款产品。(Nutragen 5010、fibricol 5133和PureCol的物质成分一样,仅仅是浓度不同)浓度越高,胶原蛋白硬度越强。