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Gain deep insights with complementary and highly correlative multiplex panels. You can measure gene expression and protein on a single platform enabling you to have confidence in your results. Get more information from your samples by analyzing up to 80 proteins per well—almost twice as many as conventional xMAP assays. It enables efficient immune response profiling and biomarker discovery. Analyze different types of samples including serum and plasma cell lysates, cell culture supernatants or tissue homogenates CCS. Get deep insight in a single assay, helping save time and precious sample which can help reduce consumables cost. ProcartaPlex and QuantiGene preconfigured panels come in a ready-to-use format.
Invitrogen ProcartaPlex and QuantiGene Plex assays enable a unique high-throughput multi-omics approach by utilizing the Luminex xMAP (Multi-Analyte Profiling) technology. Easily combine genomic and proteomic workflows without compromising data interpretation or sensitivity.
Examination of both RNA and protein expression variations can provide a robust and accurate indication of cell states (see workflow and sample data below). RNA levels can be transient and may not correlate with protein levels, which are likely to be maintained for longer periods of time to maintain cellular functions. Due to differences in timing and expression levels, one assay may detect changes that the other does not. Alternatively, the two data sets can further support key findings. The ability to perform both RNA and protein measurements using simple, unified high-throughput workflows can make the Invitrogen ProcartaPlex and QuantiGene Plex assays well suited for tools for large-scale screening studies that benefit from automation workflows.
U937 cells were stimulated with PMA (24 hr) or LPS (48 hr) and the cell culture supernatant was collected to measure secreted proteins using the Th1/Th2 cytokine and chemokine 20-plex ProcartaPlex panel. The cells were lysed using the QuantiGene lysis mixture and the cell lysate was directly used to measure gene expression changes with the 36-plex QuantiGene Plex panel. Both assays were read on a Luminex xMAP INTELLIFLEX DR-SE instrument.
ProcartaPlex assays | QuantiGene Plex assays | |
Intra-assay CV | <15% | |
Inter-assay CV | <15% | |
Linearity | 3–5 logarithmic units | |
Maximum assay plex size | 80 proteins | 80 RNA targets |
Formats | 96- and 384-well | |
Sample types | Serum, plasma, cell culture supernatant (CCS), cerebral spinal fluid (CSF) | RNA; cell and blood lysates; tissues and FFPE homogenates |
Species | Human, mouse, rat, canine, porcine, non-human primate (NHP) | All |
Compatible Luminex instruments | xMAP INTELLIFLEX System | |
Sample volume | 6.3–50 µL | 20–80 µL |
Customizable | Yes | Yes |
High-Plex multiplexing offers a transformative advantage for biomarker discovery and validation by enabling simultaneous assessment of up to 80 analytes on the Luminex instrument within a single experiment. This approach greatly improves efficiency by helping conserve resources, precious samples and time, while also providing a holistic view of complex biological interactions.
The Immune Response 80-Plex Human ProcartaPlex Panel and Immune Response 64-Plex Mouse ProcartaPlex Panel are the largest ready-to-use protein panels on the Luminex platform and are meticulously designed to deliver reliable and precise results, helping ensure you can confidently make informed decisions based on your findings.
Maximize your results by combining ProcartaPlex Panels with the complementary Immune Response 80-Plex Human QuantiGene Plex and Immune Response 80-Plex Mouse QuantiGene Plex Panel and get deeper insights from your sample.
Invitrogen Immune Response 80-Plex Human ProcartaPlex Panel | |||||||
---|---|---|---|---|---|---|---|
Cat. No. EPX800-10080-901 | |||||||
APRIL | CD40L | GM-CSF | IL-15 | IL-23 | IL-7 | M-CSF | PTX3 |
BAFF | CXCL6 (GCP-2) | Granzyme A | IL-16 | IL-27 | IL-8 | MDC | SCF |
BLC | ENA-78 | Granzyme B | IL-17A | IL-2R | IL-9 | MIF | TNF alpha |
bNGF | Eotaxin | GRO alpha | IL-18 | IL-3 | IP-10 | MIG | TNF beta |
CCL1 (I-309) | Eotaxin-2 | HGF | IL-1a alpha | IL-31 | I-TAC | MIP-1 alpha | TNF-R2 |
CCL17 (TARC) | Eotaxin-3 | IFN alpha | IL-1 beta | IL-34 | LIF | MIP-1 beta | TRAIL |
CCL21 (6Ckine/SLC) | FGF-2 | IFN gamma | IL-2 | IL-37 | MCP-1 | MIP-2 alpha (CXCL2) | TREM-1 |
CCL23 (MPIF) | Fractalkine | IL-10 | IL-20 | IL-4 | MCP-2 | MIP-3 beta (CCL19) | TSLP |
CCL25 (TECK) | Gal-3 | IL-12p70 | IL-21 | IL-5 | MCP-3 | MIP-3 alpha | TWEAK |
CD30 | G-CSF | IL-13 | IL-22 | IL-6 | MCP-4 (CCL13) | MMP-1 | VEGF-A |
To demonstrate the power of the 80-plex as a screening method, 30 samples were analyzed. 23 human serum samples were untreated, and 7 plasma samples were treated with LPS 100 ng/mL for 20 hours.
These were quantified in parallel using Invitrogen ProcartaPlex Human Immune Response Panel (80-plex). Differences in the expression pattern of 80 targets in untreated human serum samples and pre-treated plasma samples are shown in the following figures, grouped by low, medium, and high expression levels. Analytes are displayed on the x-axis, and mean concentration for untreated (blue lines) versus treated (orange lines) samples for each analyte on the y-axis.
Figure 1. Differences in the expression pattern of 80 targets in untreated human serum samples and pre-treated plasma samples.
Additionally, a few analytes in the medium expressed samples are shown in more detail. These analytes showed the greatest degree of difference between treated versus untreated samples. This data is presented in four figures as demonstrated here.
Figure 2. Concentration levels for a few analytes with medium expression levels.
To confirm scalability of ProcartaPlex multiplex immunoassays, human serum and stimulated plasma samples were run in parallel using both the Invitrogen ProcartaPlex Chemokine Panel 2 (9-plex) and the Invitrogen ProcartaPlex Human Immune Response Panel (80-plex). Experiments demonstrated high consistency between large-scale versus small-scale multiplex panels, verifying that high content screening can be performed without compromising the test results. Concentration levels for MCP-4 and CCL1 at different serum samples for small plex (9-plex) versus 80-plex is presented in the following figure. This was a method to demonstrate the level of correlation between small and big panels.
Figure 3. Concentration levels for MCP-4 and CCL1 at different serum samples for small plex (9-plex) vs 80-plex.
To further demonstrate the degree of correlation between small and big plex, a regression analysis was performed. This yielded a R2 value >0.9. (0.99 for MCP-4, 0.93 for CCL1).
Figure 4. Correlation Analysis between small and big plex.
Invitrogen Immune Response 64-Plex Mouse ProcartaPlex Panel | |||||||
---|---|---|---|---|---|---|---|
Cat. No. EPX640-20064-901 | |||||||
BAFF | G-CSF (CSF-3) | IL-13 | IL-2 | IL-31 | IL-9 | M-CSF | ST2 (IL-33R) |
BLC (CXCL13) | GM-CSF | IL-15/IL-15R | IL-22 | IL-33 | IP-10 (CXCL10) | MDC (CCL22) | SYB16 (CXCL16) |
BTC | Granzyme B | IL-16 | IL-23 | IL-4 | I-TAC (CXCL11) | MIP-1 alpha | TECK (CCL25) |
CD27 | GRO alpha (CXCL1) | IL-17A (CTLA-8) | IL-25 (IL-17E) | IL-5 | Leptin | MIP-1 beta | TNF alpha |
CTACK (CCL27) | IFN alpha | IL-18 | IL-27 | IL-6 | LIF | MIP-2 | TARC (CCL17) |
ENA-78 (CXCL5) | IFN gamma | IL-19 | IL-28 | IL-6R/sIL-6R | MCP-1 (CCL2) | MIP-3b (CCL19) | TSLP |
Eotaxin (CCL11) | IL-10 | IL-1 alpha | IL-2Ra | IL-7 | MCP-3 (CCL7) | RANKL | VEGF-A |
Eotaxin-2 (CCL24) | IL-12p70 | IL-1 beta | IL-3 | IL-7R alpha | MCP-5 (CCL12) | RANTES (CCL5) | VEGF-R2 (KDR) |
Targets highlighted in bold are additional in the Immune Response 64-Plex Mouse ProcartaPlex Panel compared to the Immune Monitoring 48-Plex Mouse ProcartaPlex Panel (EPX480-20834-901).
The ability to scale the number of analytes and correlate data in multiplex experiments is critical for the progression of many projects. For example, it is not uncommon to begin a project by analyzing a large, comprehensive panel on few samples to determine which analytes are affected by a particular disease or drug treatment. The resulted list of analytes can then be investigated further with a smaller panel on a larger set of samples. Thus, there is a great need for scalability in multiplex panel assays to correlate data across different stages of investigation.
To demonstrate the scalability and reproducible performance regardless of plex size mouse serum and plasma samples of healthy, untreated mice were run in parallel on the ProcartaPlex Mouse Immune Monitoring Panel 48-Plex and the ProcartaPlex Mouse Immune Response Panel 64-Plex. Data in Figure 5 and 6 illustrates the high correlation for sample measurements for the same analytes in a large and small panel.
Figure 6. Data illustrate the high correlation between large and small-scale ProcartaPlex panels.
PBMC were stimulation with Lipopolysaccharide (LPS) and the gene expression change over time was measured with the Immune Response 80-Plex Human QuantiGene Plex. The majority of the 80 gene targets tested showed expression changes over unstimulated control samples with 10 µg/mL LPS-stimulation of PBMCs at 3 time points (see figure 7). Raw MFI data from the QuantiGene Plex assay using the Immune Response 80-Plex Human QuantiGene Plex Panel were normalized to the housekeeping control PPIB and data is displayed as log2 fold change over unstimulated control samples at the 3 different timepoints.
Figure 7. Effect of LPS stimulation on gene expression in PBMCs.
Additionally, PBMC were stimulated with 5 µg/mL Phytohemagglutinin (PHA) and 5 µg/mL Concanavalin A (ConA) or 10 µg/mL LPS to measure the top ten induced and top ten repressed gene targets at 24h post simulation (see figure 8). Raw MFI data from the QuantiGene Plex assay using the Immune Response 80-Plex Human QuantiGene Plex Panel were normalized to the housekeeping control PPIB and data is displayed as log2 fold change over unstimulated control samples.
Figure 8. Gene expression changes after 48h of stimulation with PHA, ConA or LPS.
Analyze 80 cytokine, chemokine, and growth factor targets simultaneously to enable efficient immune response profiling, biomarker discovery, and validation.
CCL1 = I-309 | CCL26 = Eotaxin-3 | CXCL11 = I-TAC | HGF = HGF | IL18 = IL-18 | IL3 = IL-3 | LGALS3 = GAL-3 | TNFSF10 = TRAIL |
CCL13 = MCP-4 | CCL4 = MIP-1b | CXCL13 = BLC | IFNA1 = INF-a | IL1A = IL-1A | IL31 = IL-31 | LIF = LIF | TNFSF13 = APRIL |
CCL17 = TARC | CCL7 = MCP-3 | CXCL2 = MIP-2a | IFNG = INF-g | IL1B = IL-1B | IL34 = IL-34 | LTA = TNF-b | TNFSF13B = BAFF |
CCL19 = MIP-3b | CCL8 = MCP-2 | CXCL5 = ENA-78 | IL10 = IL-10 | IL2 = IL-2 | IL37 = IL-37 | MIF = MIF | TREM1 = TREM-1 |
CCL2 = MCP-1 | CD40LG = CD40L | CXCL6 = GCP-2 | IL12A = IL-12p35 | IL20 = IL-12p35 | IL4 = IL-4 | NGF = b-NGF | TSLP = TSLP |
CCL21 = 6Ckine/SLC | CSF1 = M-CSF | CXCL9 = MIG | IL12B = IL12-p40 | IL12B = IL12-p40 | IL5 = IL-5 | PTX3 = PTX3 | VEGFA = VEGF-A |
CCL22 = MDC | CSF2 = GM-CSF | CXCR3 = IP-10 | IL13 = IL-13 | IL13 = IL-13 | IL6 = IL-6 | TNF = TNF-a | PPIB |
CCL23 = MPIF | CSF3 = G-CSF | FGF2 = FGF-2 | IL15 = IL-15 | IL15 = IL-15 | IL8 = IL-8 | TNFRSF12A = TWEAK | HPRT1 |
CCL24 = Eotaxin-2 | CX3CL1 = Fractalkine | GZMA = Granzyme A | IL16 = IL-16 | IL16 = IL-16 | IL9 = IL-9 | TNFRSF1B = TNF-R2 | GAPDH |
CCL25 = TECK | CCXL1 = GRO-a | GZMB = Granzyme B | IL17A = IL-17A | IL17A = IL-17A | KITLG = SCF | TNFRSF8 = CD30 | GUSB |
*QuantiGene panel (RNA) targets in red, QuantiGene housekeeping genes in blue, ProcartaPlex panel (protein) targets in black. Targets in ProcartaPlex panel that are NOT in QuantiGene panel are Eotaxin, IL-7, MIP-1a, MIP-3a, MMP-1.
PBMC were stimulated with 10 µg/mL Lipopolysaccharide (LPS) and correlation of RNA and protein expression was measured. Relative RNA and protein expression of ENA (CXCL5), GRO-alpha (CXCL1), MCP-3 (CCL7) and BLC (CXCL13) at 48h post stimulation with LPS is shown in figure 9. Raw MFI data from the Immune Response 80-Plex Human QuantiGene Plex were normalized to the housekeeping control PPIB. Protein data was acquired using the complementary Immune Response 80-Plex Human ProcartaPlex Panel. Data is displayed as normalized gene expression (RNA) and total amounts of protein (pg/mL) for unstimulated and LPS-stimulated samples at the 48h timepoint. RNA expression is represented by lines and protein expression by bars in the figure below.
Figure 9. Correlation of Gene (RNA) vs Protein expression at 3 different timepoints after stimulation with LPS.
Invitrogen Immune Response 80-Plex Human ProcartaPlex Panel | |||||||
---|---|---|---|---|---|---|---|
Cat. No. EPX800-10080-901 | |||||||
APRIL | CD40L | GM-CSF | IL-15 | IL-23 | IL-7 | M-CSF | PTX3 |
BAFF | CXCL6 (GCP-2) | Granzyme A | IL-16 | IL-27 | IL-8 | MDC | SCF |
BLC | ENA-78 | Granzyme B | IL-17A | IL-2R | IL-9 | MIF | TNF alpha |
bNGF | Eotaxin | GRO alpha | IL-18 | IL-3 | IP-10 | MIG | TNF beta |
CCL1 (I-309) | Eotaxin-2 | HGF | IL-1a alpha | IL-31 | I-TAC | MIP-1 alpha | TNF-R2 |
CCL17 (TARC) | Eotaxin-3 | IFN alpha | IL-1 beta | IL-34 | LIF | MIP-1 beta | TRAIL |
CCL21 (6Ckine/SLC) | FGF-2 | IFN gamma | IL-2 | IL-37 | MCP-1 | MIP-2 alpha (CXCL2) | TREM-1 |
CCL23 (MPIF) | Fractalkine | IL-10 | IL-20 | IL-4 | MCP-2 | MIP-3 beta (CCL19) | TSLP |
CCL25 (TECK) | Gal-3 | IL-12p70 | IL-21 | IL-5 | MCP-3 | MIP-3 alpha | TWEAK |
CD30 | G-CSF | IL-13 | IL-22 | IL-6 | MCP-4 (CCL13) | MMP-1 | VEGF-A |
To demonstrate the power of the 80-plex as a screening method, 30 samples were analyzed. 23 human serum samples were untreated, and 7 plasma samples were treated with LPS 100 ng/mL for 20 hours.
These were quantified in parallel using Invitrogen ProcartaPlex Human Immune Response Panel (80-plex). Differences in the expression pattern of 80 targets in untreated human serum samples and pre-treated plasma samples are shown in the following figures, grouped by low, medium, and high expression levels. Analytes are displayed on the x-axis, and mean concentration for untreated (blue lines) versus treated (orange lines) samples for each analyte on the y-axis.
Figure 1. Differences in the expression pattern of 80 targets in untreated human serum samples and pre-treated plasma samples.
Additionally, a few analytes in the medium expressed samples are shown in more detail. These analytes showed the greatest degree of difference between treated versus untreated samples. This data is presented in four figures as demonstrated here.
Figure 2. Concentration levels for a few analytes with medium expression levels.
To confirm scalability of ProcartaPlex multiplex immunoassays, human serum and stimulated plasma samples were run in parallel using both the Invitrogen ProcartaPlex Chemokine Panel 2 (9-plex) and the Invitrogen ProcartaPlex Human Immune Response Panel (80-plex). Experiments demonstrated high consistency between large-scale versus small-scale multiplex panels, verifying that high content screening can be performed without compromising the test results. Concentration levels for MCP-4 and CCL1 at different serum samples for small plex (9-plex) versus 80-plex is presented in the following figure. This was a method to demonstrate the level of correlation between small and big panels.
Figure 3. Concentration levels for MCP-4 and CCL1 at different serum samples for small plex (9-plex) vs 80-plex.
To further demonstrate the degree of correlation between small and big plex, a regression analysis was performed. This yielded a R2 value >0.9. (0.99 for MCP-4, 0.93 for CCL1).
Figure 4. Correlation Analysis between small and big plex.
Invitrogen Immune Response 64-Plex Mouse ProcartaPlex Panel | |||||||
---|---|---|---|---|---|---|---|
Cat. No. EPX640-20064-901 | |||||||
BAFF | G-CSF (CSF-3) | IL-13 | IL-2 | IL-31 | IL-9 | M-CSF | ST2 (IL-33R) |
BLC (CXCL13) | GM-CSF | IL-15/IL-15R | IL-22 | IL-33 | IP-10 (CXCL10) | MDC (CCL22) | SYB16 (CXCL16) |
BTC | Granzyme B | IL-16 | IL-23 | IL-4 | I-TAC (CXCL11) | MIP-1 alpha | TECK (CCL25) |
CD27 | GRO alpha (CXCL1) | IL-17A (CTLA-8) | IL-25 (IL-17E) | IL-5 | Leptin | MIP-1 beta | TNF alpha |
CTACK (CCL27) | IFN alpha | IL-18 | IL-27 | IL-6 | LIF | MIP-2 | TARC (CCL17) |
ENA-78 (CXCL5) | IFN gamma | IL-19 | IL-28 | IL-6R/sIL-6R | MCP-1 (CCL2) | MIP-3b (CCL19) | TSLP |
Eotaxin (CCL11) | IL-10 | IL-1 alpha | IL-2Ra | IL-7 | MCP-3 (CCL7) | RANKL | VEGF-A |
Eotaxin-2 (CCL24) | IL-12p70 | IL-1 beta | IL-3 | IL-7R alpha | MCP-5 (CCL12) | RANTES (CCL5) | VEGF-R2 (KDR) |
Targets highlighted in bold are additional in the Immune Response 64-Plex Mouse ProcartaPlex Panel compared to the Immune Monitoring 48-Plex Mouse ProcartaPlex Panel (EPX480-20834-901).
The ability to scale the number of analytes and correlate data in multiplex experiments is critical for the progression of many projects. For example, it is not uncommon to begin a project by analyzing a large, comprehensive panel on few samples to determine which analytes are affected by a particular disease or drug treatment. The resulted list of analytes can then be investigated further with a smaller panel on a larger set of samples. Thus, there is a great need for scalability in multiplex panel assays to correlate data across different stages of investigation.
To demonstrate the scalability and reproducible performance regardless of plex size mouse serum and plasma samples of healthy, untreated mice were run in parallel on the ProcartaPlex Mouse Immune Monitoring Panel 48-Plex and the ProcartaPlex Mouse Immune Response Panel 64-Plex. Data in Figure 5 and 6 illustrates the high correlation for sample measurements for the same analytes in a large and small panel.
Figure 6. Data illustrate the high correlation between large and small-scale ProcartaPlex panels.
PBMC were stimulation with Lipopolysaccharide (LPS) and the gene expression change over time was measured with the Immune Response 80-Plex Human QuantiGene Plex. The majority of the 80 gene targets tested showed expression changes over unstimulated control samples with 10 µg/mL LPS-stimulation of PBMCs at 3 time points (see figure 7). Raw MFI data from the QuantiGene Plex assay using the Immune Response 80-Plex Human QuantiGene Plex Panel were normalized to the housekeeping control PPIB and data is displayed as log2 fold change over unstimulated control samples at the 3 different timepoints.
Figure 7. Effect of LPS stimulation on gene expression in PBMCs.
Additionally, PBMC were stimulated with 5 µg/mL Phytohemagglutinin (PHA) and 5 µg/mL Concanavalin A (ConA) or 10 µg/mL LPS to measure the top ten induced and top ten repressed gene targets at 24h post simulation (see figure 8). Raw MFI data from the QuantiGene Plex assay using the Immune Response 80-Plex Human QuantiGene Plex Panel were normalized to the housekeeping control PPIB and data is displayed as log2 fold change over unstimulated control samples.
Figure 8. Gene expression changes after 48h of stimulation with PHA, ConA or LPS.
Analyze 80 cytokine, chemokine, and growth factor targets simultaneously to enable efficient immune response profiling, biomarker discovery, and validation.
CCL1 = I-309 | CCL26 = Eotaxin-3 | CXCL11 = I-TAC | HGF = HGF | IL18 = IL-18 | IL3 = IL-3 | LGALS3 = GAL-3 | TNFSF10 = TRAIL |
CCL13 = MCP-4 | CCL4 = MIP-1b | CXCL13 = BLC | IFNA1 = INF-a | IL1A = IL-1A | IL31 = IL-31 | LIF = LIF | TNFSF13 = APRIL |
CCL17 = TARC | CCL7 = MCP-3 | CXCL2 = MIP-2a | IFNG = INF-g | IL1B = IL-1B | IL34 = IL-34 | LTA = TNF-b | TNFSF13B = BAFF |
CCL19 = MIP-3b | CCL8 = MCP-2 | CXCL5 = ENA-78 | IL10 = IL-10 | IL2 = IL-2 | IL37 = IL-37 | MIF = MIF | TREM1 = TREM-1 |
CCL2 = MCP-1 | CD40LG = CD40L | CXCL6 = GCP-2 | IL12A = IL-12p35 | IL20 = IL-12p35 | IL4 = IL-4 | NGF = b-NGF | TSLP = TSLP |
CCL21 = 6Ckine/SLC | CSF1 = M-CSF | CXCL9 = MIG | IL12B = IL12-p40 | IL12B = IL12-p40 | IL5 = IL-5 | PTX3 = PTX3 | VEGFA = VEGF-A |
CCL22 = MDC | CSF2 = GM-CSF | CXCR3 = IP-10 | IL13 = IL-13 | IL13 = IL-13 | IL6 = IL-6 | TNF = TNF-a | PPIB |
CCL23 = MPIF | CSF3 = G-CSF | FGF2 = FGF-2 | IL15 = IL-15 | IL15 = IL-15 | IL8 = IL-8 | TNFRSF12A = TWEAK | HPRT1 |
CCL24 = Eotaxin-2 | CX3CL1 = Fractalkine | GZMA = Granzyme A | IL16 = IL-16 | IL16 = IL-16 | IL9 = IL-9 | TNFRSF1B = TNF-R2 | GAPDH |
CCL25 = TECK | CCXL1 = GRO-a | GZMB = Granzyme B | IL17A = IL-17A | IL17A = IL-17A | KITLG = SCF | TNFRSF8 = CD30 | GUSB |
*QuantiGene panel (RNA) targets in red, QuantiGene housekeeping genes in blue, ProcartaPlex panel (protein) targets in black. Targets in ProcartaPlex panel that are NOT in QuantiGene panel are Eotaxin, IL-7, MIP-1a, MIP-3a, MMP-1.
PBMC were stimulated with 10 µg/mL Lipopolysaccharide (LPS) and correlation of RNA and protein expression was measured. Relative RNA and protein expression of ENA (CXCL5), GRO-alpha (CXCL1), MCP-3 (CCL7) and BLC (CXCL13) at 48h post stimulation with LPS is shown in figure 9. Raw MFI data from the Immune Response 80-Plex Human QuantiGene Plex were normalized to the housekeeping control PPIB. Protein data was acquired using the complementary Immune Response 80-Plex Human ProcartaPlex Panel. Data is displayed as normalized gene expression (RNA) and total amounts of protein (pg/mL) for unstimulated and LPS-stimulated samples at the 48h timepoint. RNA expression is represented by lines and protein expression by bars in the figure below.
Figure 9. Correlation of Gene (RNA) vs Protein expression at 3 different timepoints after stimulation with LPS.
Multiplex up to 80 RNA targets from a single biological sample.
Explore the different Luminex systems: Luminex 200, FLEXMAP3D, and INTELLIFLEX models, which are all compatible with Invitrogen Luminex Assays.
Detect very low levels of proteins using as little as 1–5 μL of sample.
Quantitate single analytes with confidence with highly verified Invitrogen ELISA kits.
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