COVID-19 Cytokine Storm Multiplex Assays
GeniePlex COVID-19 Multiplex Cytokine Storm Immunoassays
GeniePlex COVID-19 Multiplex Cytokine Storm Immunoassays are bead-based
multiplex immunoassay kits for the simultaneous and quantitative detection of
Cytokine Storm (Cytokine Release Syndrome or CRS).
Not only can
GeniePlex Cytokine Storm Multiplex Immunoassays detect and quantify a wide
variety of pro-inflammatory cytokines, but they can do this with as little
15ul of sample, in as little as 2 hours!
GeniePlex kits can also
be run on almost any Flow Cytometer using a range of samples such as Serum,
Plasma, Cell culture supernatant, Cell lysates, Tissue lysates and other
samples types.
Features
- Quantitatively measure key analytes involved in Cytokine Storm
- Simultaneously analyze up to 24 analytes per well via Flow Cytometry
- Only 15µL of sample needed per well
- Pre-mixed panels for Human, Mouse, Rat & Non-Human Primate models using Serum, Plasma, Cell culture supernatant, Tissues & other samples types
- Create your own custom panel
Human Kits
| SKU | Product Name | Reactivity | Analytes |
HUAMCOV01 |
Human |
IL2, IL7, IL10, GSCF, IP10, MCP1, MIP1A, and TNF alpha |
|
HUAMCOV02 |
Human |
IL-6, IL-10, IFN-gamma |
|
HUAMCOV04
|
Human |
IL-6, IL-10, IFN-gamma, CCL2/SYCA2/MCP-1, and GM-CSF/CSF-2 |
|
HUAMCOV03 |
Human |
IL-6, IL-10, IFN-gamma, TNF-alpha, IL-1beta, IL-8/CXCL8, and CCL2/SYCA2/MCP-1 |
|
Human |
IL-6, IL-10, IFN-gamma, CCL2/SYCA2/MCP-1, GM-CSF/CSF-2, TNF-alpha, IL-1beta, IL-2, and IL-8/CXCL8 |
||
HUAMCOV06
|
Human
|
IFNγ, IL-1RA, IL-1β, IL-2, IL-4, IL-5, IL-6, IL-8, IL-10, IL-12p70, IL-17A, IL-18, MCP-1, MIP-1α, RANTES and TNFα
|
Murine Kits
| SKU | Product Name | Reactivity | Analytes |
MOAMCOV01
|
Mouse |
IL-2, IL-7, IL-10/CSIF, GCSF/CSF-3, IP-10/CXCL10, MCP-1/JE/CCL2, MIP-1 alpha/CCL3, and TNF-alpha. |
|
MOAMCOV02
|
Mouse |
IL-6, IL-10, and IFN-gamma |
|
MOAMCOV04 |
Mouse |
IL-6, IL-10, IFN-gamma, MCP-1/JE/CCL2, and GM-CSF/CSF-2 |
|
MOAMCOV03 |
Mouse |
IL-6, IL-10, IFN-gamma, TNF-alpha, IL-1beta, CXCL1/KC/CINC1/KC/Gro alpha (there is no IL-8 in Mouse. KC is a homologous), and MCP-1/JE/CCL2 |
|
MOAMCOV05 |
Mouse |
IL-6, IL-10, IFN-gamma, MCP-1/JE/CCL2, GM-CSF/CSF-2, TNF-alpha, IL-1beta, IL-2, and CXCL1/KC/CINC1/KC/Gro alpha |
Rat Kits
| SKU | Product Name | Reactivity | Analytes |
RTAMCOV01
|
Rat |
IL2, IL10, GSCF, IP10, MCP1, MIP1A, and TNFα |
|
RTAMCOV02
|
Rat |
IL-6, IL-10, and IFN-gamma |
|
RTAMCOV04 |
Rat |
IL-6, IL-10, IFN-gamma, MCP-1/JE/CCL2, and GM-CSF/CSF-3 |
|
RTAMCOV03
|
Rat |
IL-6, IL-10, IFN-gamma, TNF-alpha, IL-1beta/IL-1F2, GRO alpha/KC/CINC1 (there is no IL-8 in Rat. KC is a homologous), and MCP-1/JE/CCL2 |
|
RTAMCOV05 |
Rat |
IL-6, IL-10, IFN-gamma, MCP-1/JE/CCL2, GM-CSF/CSF-2, TNF-alpha, IL-1beta, IL-2, and GRO alpha/KC/CINC1. |
Non-Human Primate Kits
| SKU | Product Name | Reactivity | Analytes |
MKAMCOV01
|
Non-Human Primate |
IL-2, IL-10, IP-10/CXCL10, MCP-1/JE/CCL2, and TNFalpha |
|
MKAMCOV02 |
Non-Human Primate |
IL-6, IL-10, and IFN-gamma |
|
MKAMCOV04
|
Non-Human Primate |
IL-6, IL-10/CSIF, IFNgamma, and MCP-1/JE/CCL2 |
|
MKAMCOV03 |
Non-Human Primate |
IL-6, IL-10/CSIF, IFN-gamma, TNF-alpha, IL-1beta, IL-8/CXCL8, and MCP-1/JE/CCL2 |
|
MKAMCOV05
|
Non-Human Primate |
IL-6, IL-10/CSIF, IFN-gamma, MCP-1/JE/CCL2, TNF-alpha, IL-1beta, IL-2, and IL-8/CXCL8 |
|
MKAMCOV01
|
Non-Human Primate |
IL-2, IL-10, IP-10/CXCL10, MCP-1/JE/CCL2, and TNFalpha |
|
MKAMCOV02 |
Non-Human Primate |
IL-6, IL-10, and IFN-gamma |
|
MKAMCOV04
|
Non-Human Primate |
IL-6, IL-10/CSIF, IFNgamma, and MCP-1/JE/CCL2 |
|
MKAMCOV03 |
Non-Human Primate |
IL-6, IL-10/CSIF, IFN-gamma, TNF-alpha, IL-1beta, IL-8/CXCL8, and MCP-1/JE/CCL2 |
|
MKAMCOV05
|
Non-Human Primate |
IL-6, IL-10/CSIF, IFN-gamma, MCP-1/JE/CCL2, TNF-alpha, IL-1beta, IL-2, and IL-8/CXCL8 |
|
MKAMCOV01
|
Non-Human Primate |
IL-2, IL-10, IP-10/CXCL10, MCP-1/JE/CCL2, and TNFalpha |
|
MKAMCOV02 |
Non-Human Primate |
IL-6, IL-10, and IFN-gamma |
|
MKAMCOV04
|
Non-Human Primate |
IL-6, IL-10/CSIF, IFNgamma, and MCP-1/JE/CCL2 |
|
MKAMCOV03 |
Non-Human Primate |
IL-6, IL-10/CSIF, IFN-gamma, TNF-alpha, IL-1beta, IL-8/CXCL8, and MCP-1/JE/CCL2 |
|
MKAMCOV05
|
Non-Human Primate |
IL-6, IL-10/CSIF, IFN-gamma, MCP-1/JE/CCL2, TNF-alpha, IL-1beta, IL-2, and IL-8/CXCL8 |
Cytokine Storm Information
Symptoms of Cytokine Release Syndrome
CRS is a heterogeneous condition which can present with different symptoms that vary in severity. It most commonly begins with symptoms such as fever, chills, fatigue, nausea, vomiting, and headache. In serious cases it may lead to seizures, arrythmia, and possible organ failure.
Figure: CRS Cytokines and Symptoms
Cytokine Storm and COVID-19
Some of the most well-known causes of CRS include allogeneic transplants, therapeutic interventions, and viral infections. Recently however, focus has been on the involvement of CRS in COVID-19. With the collation and publication of more and more clinical data, a large number of data suggest that there are mild or severe cytokine storms in severe patients, which is an important cause of death.
Pathogenesis of Cytokine Release Syndrome
The pathogenesis of CRS is not fully understood. However, certain key mediators of cytokine release syndrome have been identified. Chief among these is interleukin 6 (IL-6), an activator of the JAK/STAT signalling pathway which can bind to two forms of its receptor (soluble and transmembrane).
IL-6, along with IL-10 and IFNγ are the cytokines most consistently implicated in CRS. These three cytokines are usually elevated in the serum of patients with cytokine storm. TNF, IL-1, IL-8 and MCP-1 are more prominent early in CRS onset, with IL-6 produced later in the progression of the syndrome in higher quantities. IL-6 production is increased by TNF and IL-1, thus linking the signal of early-response cytokines to late onset profiles.
Diagnosis and Treatment of Cytokine Release Syndrome
At present, multiple therapeutics target the pathways which are affected by the pro-inflammatory cytokines of CRS. In particular, blocking IL-6 with therapies such as Tocilizumab and Siltuximab has gained much support globally.
However, to proactively tackle the issue there is need for an accurate diagnostic assay that can rapidly establish if a patient is suffering from Cytokine Release Syndrome. This may be the difference between the development of mild CRS to severe CRS, even the difference between life and death.
This is where our Genie Plex Cytokine Storm Multiplex Immunoassays come in.
GeniePlex COVID-19 Multiplex Cytokine Immunoassay Technology
GeniePlex COVID-19 Multiplex Cytokine Immunoassays are a form of bead-based Multiplex Immunoassay kit that enables the simultaneous and quantitative detection of a range of cytokines. The selection of cytokines targeted is dependent on the species in which the kit is created for.
Not only can Genie Plex Cytokine Storm Multiplex Immunoassays detect and quantify a wide variety of pro-inflammatory cytokines, but they can do this with as little 15ul of sample, in as little as 2 hours!
Our kits can also be run on almost any Flow Cytometer using a range of samples such as Serum, Plasma, Cell culture supernatant, Cell lysates, Tissue lysates and other samples types.
Multiplex Assay Video Protocol
Multiplex ELISA Protocol Overview
Figure 1. Protocol Overview
1.) Add you Genieplex antibody bead conjugates to your well. 2.) Add your samples and standards to the wells. Incubate your samples at room temperature for 60 mins. Followed by washing the plate X3 using a filter plate vacuum system. 3) Add your biotinylated antibodies and incubate for 30 mins. Followed by washing the plate X3 using a filter plate vacuum system. 4) Add your streptavidin-PE solution and incubate for 20 mins. Followed by washing the plate X3 using a filter plate vacuum system. 5) Add Reading Buffer and read your samples on a flow cytometer. 7) Analyze your data.
Protocol Steps
| Step | Procedure |
1. |
Prepare the filter plate template. Mark the standard, sample and blank wells. Standards and samples should be run in duplicates or triplicates. If the whole plate will not be used, seal the unused well with a plate seal.
|
2. |
Vortex working bead suspension for 15 seconds. |
3. |
Add 45 µL of capture bead working suspension to each well. NOTE: Save the remaining capture bead working suspension and store at 2-8°C with light protection. It can be used for setting up acquisition parameters on the flow cytometer. |
4. |
Remove buffer in the wells by using the “flow-through“ Filter Plate Washer connected to a vacuum source that has been adjusted according to the Filter Plate Washer Instructions. |
5. |
Gently tap the plate bottom onto several layers of paper towels to remove residual buffer after the “flow-through” removal of the buffer. |
6. |
Add 30 µL of CCS, SPB or TL Assay Buffer to each sample well. NOTE: Cell culture supernatant samples can be run without diluting in Assay Buffer if very low levels (less than 20 pg/mL) of cytokines are expected. If it is the case, skip this step and add 45 µL of cell culture supernatant samples to each sample well in Step 7.
|
7. |
Add 15 µL of samples to each sample well. |
8. |
Add 45 µL of standards to each standard well. |
9. |
Cover the plate with a plate seal. |
10. |
Incubate on the shaker (set at 700 rpm) for 60 min at room temperature. Protect from light by wrapping the filter plate in aluminum foil. |
11. |
Remove the plate seal. |
12. |
Remove solutions in the wells by using the Filter Plate Washer connected to a vacuum source. |
13. |
Wash the wells three times with 100 µL 1x Wash Buffer using the Filter Plate Washer.
|
14. |
Gently tap the plate bottom onto several layers of paper towels to remove residual buffer on the plate bottom after the last wash. |
15. |
Add 25 µL of biotinylated antibody working solution to each well. |
16. |
Cover the plate with a plate seal. |
17.
|
Incubate on the shaker (set at 700 rpm) for 30 min at room temperature. Protect from light by wrapping the filter plate in aluminum foil. |
18. |
Remove the plate seal. |
19. |
Remove solutions in the wells by using the Filter Plate Washer. |
20. |
Wash the wells three times with 100 µL 1x Wash Buffer using the Filter Plate Washer. |
21. |
Gently tap the plate bottom onto several layers of paper towels to remove residual buffer on the plate bottom after the last wash. |
22. |
Add 25 µL of streptavidin-PE working solution to each well.
|
23. |
Cover the plate with a plate seal. |
24. |
Incubate on the shaker (set at 700 rpm) for 20 min at room temperature. Protect from light by wrapping the filter plate in aluminum foil. |
25. |
Remove the plate seal. |
26. |
Remove solutions in the wells by using the Filter Plate Washer. |
27. |
Wash the wells twice with 100 µL 1x Wash Buffer. |
28. |
Gently tap the plate bottom onto several layers of paper towels to remove residual solution. 2 Add 150 µL to 300 µL of 1x Reading Buffer to each well depending on the sample loading mechanism of a flow cytometer to re-suspend the beads. |
29. |
Cover the plate with a plate seal. |
30. |
Place the plate on the microtiter shaker and shake for 30 seconds at 700 rpm. NOTE: If the flow cytometer has no 96-well plate loader and more than 200 µL of 1x Reading Buffer is needed to re-suspend the beads, do not shake the plate. Re-suspend the beads in each well by pipetting up and down 6–8 times with a P200 pipette then transfer to a test tube for acquisition. |
31. |
Remove the plate seal. |
32. |
Read on a flow cytometer. |