MicroVue™ Bb Plus EIA
The MicroVue Bb Plus EIA kit measures the amount of the complement fragment Bb in human plasma or serum.
Product Specifications
Citations | 47 |
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Specimen |
Serum 25 μL, EDTA Plasma 50 μL |
LLOQ | 0.033 μg/mL |
ULOQ | 0.836 μg/mL |
Assay Time | 1.5 hours |
Cross Reactivity |
Cynomolgous monkey, Pig, Rhesus monkey |
Ordering Information
Catalog Number | A027 |
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Catalog Number (CE) | |
Size | 96 wells/test |
Price (USD) | $725.00 |
Price (EURO) | 650,00 € |
Contact us
US Phone | +1 (858) 552 1100 |
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EU Phone | +353 (91) 412 474 |
US Email | contact-us@quidelortho.com |
EU Email | contact-emea@quidelortho.com |
- Specifications
- Citations
- Certificate of Analysis
Specifications
Description |
The MicroVue Bb Plus EIA kit measures the amount of the complement fragment Bb in human plasma or serum. |
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Size | 96 wells/test |
Form |
96 well plate with 12 eight-well strips in a resealable foil pouch |
Specimen | Serum 25 μL, EDTA Plasma 50 μL |
Limit of Detection (LOD) | 0.018 μg/mL |
Lower Limit of Quantitation (LLOQ) | 0.033 μg/mL |
Upper Limit of Quantitation (ULOQ) | 0.836 μg/mL |
Intra Assay | 2.4–4.0% |
Inter Assay | 6.2–9.1% |
Standards | 5 |
Controls | 2 |
Sample Values |
Serum 0.0–7.6 μg/mL, EDTA Plasma 0.3–1.7 μg/mL |
Assay Time | 1.5 hours |
Cross Reactivity |
Cynomolgous monkey, Pig, Rhesus monkey |
Storage |
Store the unopened kit at 2°C to 8°C. Refer to Product Insert for additional storage details. |
Background |
The alternative complement pathway provides innate protection against microbial agents in the absence of specific antibody. The activation of this complement pathway can be triggered by a variety of substances including microbial polysaccharides or lipids, gram-negative bacterial lipopolysaccharides, and surface determinants present on some viruses, parasites, virally infected mammalian cells, and cancer cells. In autoimmune diseases, the alternative complement pathway may contribute directly to tissue damage. A centrally important reaction that occurs during alternative pathway activation is the conversion of the 93 Kd molecular weight Factor B zymogen to an active proteolytic enzyme. This is accomplished in a two-step reaction. During the first reaction step the Factor B forms a magnesium-dependent complex with C3(H20) or C3b.4 The C3(H20),B complex is formed only in fluid-phase while the C3b,B complex can be formed either in fluid-phase or on a target surface. Factor B, which is present in the C3(H20),B or the C3b,B complex, is cleaved into the Ba (33 Kd) and Bb (60 Kd) fragments in the second reaction step by the alternative pathway enzyme, Factor D. The resulting C3b,Bb bimolecular complex is the C3 convertase enzyme of the alternative pathway. The Bb subunit is the catalytically active site of the complex that is capable of cleaving C3 to C3a and C3b fragments. The additional C3b fragments produced in this manner may form the C3b,Bb,C3b trimolecular complex that is the C5 convertase enzyme of the alternative pathway. This C5 convertase is capable of cleaving C5 to C5a and C5b fragments. The C3 and C5 convertases of the alternative pathway can be stabilized by Factor P (also called Properdin), a component of the alternative pathway normally present in human plasma or serum, or by C3 nephritic factor, an autoantibody produced in some patients experiencing extensive alternative pathway activation. The C3 and C5 convertases of the alternative pathway can be dissociated, and thereby inactivated, by spontaneous decay dissociation, or by the binding of Factor H or Complement Receptor 1 (CR1 ). The Bb fragment that is dissociated from either convertase retains some biological activities, e.g., retention of functional hemolytic activity, the ability to induce macrophage- spreading, and plasminogen activation. Although alternative pathway activation is thought to occur primarily in the absence of specific antibody, many situations arise in which alternative pathway activation can occur as the result of classical pathway activation. For example, immune complexes that are present in autoimmune disease patients can trigger classical complement pathway activation with resultant production of C3b fragments. As described above, these C3b molecules are capable of binding Factor B and initiating its cleavage into the Ba and Bb fragments. Thus, alternative pathway activation can occur in antibody-mediated autoimmune disease states and may contribute significantly to enhanced complement activation and concomitant tissue destruction. By assessing Factor B cleavage products in test specimens, one can estimate the extent of alternative pathway utilization occurring at the time of sample collection in the disease state under investigation. The MicroVue Bb Plus EIA provides a simple, rapid, non-radioactive, highly specific, and quantitative procedure for measuring Factor B activation. It is ideal for investigations involving the role or status of the alternative complement pathway in numerous research and clinical settings, and for monitoring the generation of Bb in vitro. |
Citations
Title | Year | Applications | Sample Species | Sample | Sample Details |
---|---|---|---|---|---|
Clinical Value of Complement Activation Biomarkers in Overt Diabetic Nephropathy |
2019 | ELISA |
Human |
Urine |
Diabetic nephropathy |
2019 | ELISA |
Human |
Plasma |
ANCA-AAV |
|
Subvisible Particles in IVIg Formulations Activate Complement in Human Serum. |
2020 | ELISA |
Human |
Serum |
IVIg formulations |
2019 | ELISA |
Human |
Plasma |
aHUS |
|
Complement Activation Profile of Patients With Primary Focal Segmental Glomerulosclerosis. |
2020 | ELISA |
Human |
Plasma |
FSGS |
Complement Activation Profile of Patients With Primary Focal Segmental Glomerulosclerosis. |
2020 | ELISA |
Human |
Serum |
FSGS |
2020 | ELISA |
Human |
Serum |
SiNP coated proteins |
|
2021 | ELISA |
Human |
Serum |
COVID-19 |
|
von Willebrand factor variants in C3 glomerulopathy: A Chinese cohort study. |
2021 | ELISA |
Human |
Plasma |
C3G |
von Willebrand factor variants in C3 glomerulopathy: A Chinese cohort study. |
2021 | ELISA |
Human |
Urine |
C3G |
Complement dysregulation is associated with severe COVID-19 illness. |
2021 | ELISA |
Human |
Serum |
COVID-19 |
2021 | ELISA |
Human |
Plasma |
||
2021 | ELISA |
Human |
Plasma |
||
2022 | ELISA |
Human |
Plasma |
COVID-19 |
|
2022 | ELISA |
Human |
Serum |
COVID-19 |
|
Comparison of Complement Pathway Activation in Autoimmune Glomerulonephritis. |
2022 | ELISA |
Human |
Urine |
AAV, FSGS, IgAN, MN, and LN |
Complement activation during cardiopulmonary bypass and association with clinical outcomes. |
2022 | ELISA |
Human |
Plasma |
Cardiopulmonary bypass |
Indices of complement activation and coagulation changes in trauma patients |
2022 | ELISA |
Human |
Plasma |
Trauma |
2000 | ELISA |
Human |
Plasma |
Rheumatoid Arthritis |
|
Assessment of Disease activity and impending flare in patients with systemic lupus erythematosis |
1992 | ELISA |
Human |
Plasma |
Systemic Lupus Erythematosus |
Macrophage scavenger receptor A mediates the uptake of gold colloids by macrophages in vitro |
2011 | ELISA |
Human |
Plasma |
|
2011 | ELISA |
Human |
Plasma |
Lymphatic filariasis |
|
2012 | ELISA |
Human |
Plasma |
||
Mannose binding lectin is required for alphavirus-induced arthritis/myositis |
2012 | ELISA |
Human |
Synovial fluid |
|
In Vitro Hematological and In Vivo Vasoactivity Assessment of Dextran Functionalized Graphene |
2013 | ELISA |
Human |
Plasma |
|
Multifunctional silk-heparin biomaterials for vascular tissue engineering applications |
2014 | ELISA |
Human |
Plasma |
|
2014 | ELISA |
Human |
Plasma |
Lupus Nephritis |
|
Defining the complement biomarker profile of C3 glomerulopathy |
2014 | ELISA |
Human |
Plasma |
C3G |
2014 | ELISA |
Human |
Serum |
SPIO nanoworms |
|
Complement factor B activation in patients with preeclampsia |
2015 | ELISA |
Human |
Umbillical cord blood |
|
2015 | ELISA |
Human |
Plasma |
Stx-HUS |
|
2015 | ELISA |
Human |
Plasma |
||
2015 | ELISA |
Human |
Serum |
Nanoparticles incubated |
|
2015 | ELISA |
Human |
Amniotic Fluid |
||
2015 | ELISA |
Human |
Serum |
||
2016 | ELISA |
Human |
Serum |
||
Immunological response to nitroglycerin-loaded shear-responsive liposomes in vitro and in vivo |
2017 | ELISA |
Human |
Serum |
|
2018 | ELISA |
Human |
Serum |
||
2020 | ELISA |
Human |
Plasma |
Immune‐mediated thrombotic thrombocytopenic purpura |
|
Complement activation during painful crisis in sickle cell anemia |
1995 | ELISA |
Human |
Plasma |
Sickel Cell Anemia |
1994 | ELISA |
Human |
Plasma |
Rheumatoid Arthritis |
|
1996 | ELISA |
Human |
Plasma |
Systemic Lupus Erythematosus |
|
Effects of Synthetic Oligonucleotides on human complement and coagulation |
1997 | ELISA |
Human |
Plasma |
|
2023 | ELISA |
Human |
Plasma |
Diabetes |
|
2024 | ELISA |
Human |
Plasma |
Diabetes, Type 1 |
|
2002 | ELISA |
Rhesus Monkey |
Serum |