Bridging Olink® Explore 3072 to Olink® Explore HT

Compiled: November 22, 2024

Introduction

Individual Olink® NPXTM projects are generally normalized using either plate control normalization or intensity normalization methods. Since NPX is a relative measurement, in the case when a study is separated into multiple projects, an additional normalization step is needed to allow the data to be comparable across projects. The following tutorial is designed to give you an overview of the Olink bridging procedure for combining data sets from Olink® Explore 3072 and Olink® Explore HT products.

Important Terminology

Within- and between-product bridging

The joint analysis of two or more NPX projects run on the same Olink product often requires a project correction step to remove technical variation. One such method of normalizing two projects is referred to as bridge sample reference normalization, bridge normalization, or just simply bridging. For more information on within-product bridging, see the Introduction to Bridging tutorial. Bridging makes certain assumptions on the distributions of the assays, namely that we are measuring the same true biological range no matter the setting. If an assay displays different distributions between projects, then both bridging and downstream statistical analysis will be affected. Within a product, we assume the variance and shape of the distribution remains constant within assays.

In the case where a study consists of separate projects run on Olink Explore 3072 and Olink Explore HT, an additional project correction step is required to allow data from these two products to be analyzed together, which is referred to as between-product bridging, or Olink Explore 3072 to Olink Explore HT bridging. Olink Explore 3072 and Olink Explore HT are both products that use PEA technology combined with next generation sequencing to calculate NPX for thousands of proteins. However, assays may vary more between products then within a product, and fewer assumptions can be made regarding the similarity of assay distributions and variance between products.

Since many of the assays profiled in Olink Explore 3072 are also found on Olink Explore HT, bridging data across products enables increased power in studies consisting of both Explore 3072 and Explore HT data sets, rather than limiting these studies to meta-analysis. However, differences between products, such as the number of assays being measured and the reagents being used, can sometimes lead to signal in one product and noise in another product. Bridging signal to noise can have detrimental effects on downstream statistical analysis. This means that while some assays will be able to be bridged using the same method as in within-product bridging, others will require a different normalization method, and some will not be bridgeable at all.This normalization strategy combines median-centering (as is used in within-product bridging) and quantile smoothing to normalize assays across products based on the assumption that assays can be bridged provided they have signal in both products or noise in both products.

Considerations for between-product bridging

Product bridging allows the NPX values of an Olink Explore 3072 project to be normalized and made comparable to the NPX values of an Olink Explore HT project. This process is one-directional, and normalizing Olink Explore HT NPX values to Olink Explore 3072 is not supported.

The product bridging normalization uses the ~2900 assays that are overlapping between Olink Explore 3072 and Olink Explore HT. Each overlapping assay undergoes a series of checks that evaluate the number of counts, correlation, and difference of NPX ranges between the two data sets. If an assay has enough counts and comparable metrics between the two data sets, it is determined to be suitable for bridging (referred to as a “bridgeable assay”). Assays that are not suitable for bridging can either be excluded from downstream analysis in one or both products or results can be integrated across products using meta-analysis. The set of bridgeable assays across products will vary from data set to data set, based on the samples present within the studies. Depending on the NPX distribution of each bridgeable assay in the two data sets, the assay is normalized using either median normalization or quantile smoothing.

Bridging an Explore 3072 data set to an Explore HT NPX data set requires 40 - 64 bridging samples. Bridging samples are shared samples among data sets and, as such, are analyzed in both data sets. Olink NPX data sets without shared samples cannot be combined using the bridging approach described below. More information on bridge sample selection can be found in the selecting bridging samples section of the Introduction to Bridging tutorial.

Bridge Sample Selection

Prior to running a study with Explore HT, bridging samples must be selected from the study run with Explore 3072 and be run on the Explore HT study. These samples can be selected using the olink_bridgeselector() function in Olink Analyze as detailed in the Introduction to bridging tutorial. The recommended number of bridge samples for within- and between- product bridging is summarized in the table below. When selecting bridge samples, the aim is to select samples that represent the dynamic range of the assay expression in the product. As such, quality control of the sample and, if available, proportion of data above LOD in the sample are considered when determining if a sample is chosen as a bridging sample. When LOD data is not available in the data export from Olink NPX software, LOD can optionally be calculated from fixed LOD or negative controls as detailed in the Calculating LOD from Olink Explore data tutorial.

Recommended number of bridging samples for Olink platforms
Platform BridgingSamples
Target 96 8-16
Explore 384: Cardiometabolic, Inflammation, Neurology, and Oncology 8-16
Explore 384: Cardiometabolic II, Inflammation II,Neurology II, and Oncology II 16-24
Explore HT 16-32
Explore 3072 to Explore HT 40-64

Workflow Overview

Olink Explore 3072 to Olink Explore HT bridging requires Explore 3072 data and Explore HT data which have at least 40 to 64 bridging samples. For studies containing multiple projects of Explore 3072 data, the Explore 3072 data sets should be bridged using within-product bridging as detailed in the Introduction to bridging tutorial or otherwise normalized together prior to performing between-product bridging.

The assays from Explore 3072 are matched to the corresponding assays in Explore HT and evaluated to determine if the assay is bridgeable. Additionally, all assays are normalized using both quantile smoothing and normalization using the median of paired differences. The result is an adjusted Explore 3072 data set with five additional columns. Three of these columns relate to bridging normalization:

Data from Explore 3072 and Explore HT will be concatenated in the function export. Two additional columns are added to aid in data mapping and export.

Note that regardless of the bridging recommendation, NPX values will be available for both normalization methods. A visual representation of the between-product bridging workflow is shown below.

Schematic of Explore 3072 to Explore HT Bridging Workflow

Schematic of Explore 3072 to Explore HT Bridging Workflow

Import NPX files

To normalize Explore 3072 data to Explore HT data, first the two data sets are read into R using read_NPX(). If more than two data sets are being normalized, all Explore 3072 studies should be normalized together prior to normalizing between products and the concatenated bridged data set should be used as the input. In the case of multiple Explore HT studies, only one Explore HT study should be chosen as the reference data set. The data can be loaded using read_NPX() function with default Olink Software NPX file as input, as shown below.

# Note: Explore 3072 NPX files can be CSV or parquet.
data_explore3072 <- read_NPX("~/NPX_Explore3072_location.parquet")
data_exploreht <- read_NPX("~/NPX_ExploreHT_location.parquet")

Checking input datasets and bridging samples

First, confirm that there are overlapping sample IDs within the study. Note that external controls should not be included in the list of bridging samples, as detailed in the Bridge Sample Selection section of this tutorial. External control samples often share the same naming convention across data sets but may represent different samples due to reagent batch differences. Appending the project name to the end of the control samples can ensure unique Sample IDs.

data_explore3072_samples <- data_explore3072 |>
  dplyr::filter(SampleType == "SAMPLE") |>
  dplyr::distinct(SampleID) |>
  dplyr::pull()

data_exploreht_samples <- data_exploreht |>
  dplyr::filter(SampleType == "SAMPLE") |>
  dplyr::distinct(SampleID) |>
  dplyr::pull()

overlapping_samples <- unique(intersect(data_explore3072_samples,
                                        data_exploreht_samples))
# Note that if `SampleType` is not is input data:
# stringr::str_detect can be used to exclude control samples based on SampleID.
Overlapping bridging samples
Sample_A Sample_N Sample_AA Sample_AN
Sample_B Sample_O Sample_AB Sample_AO
Sample_C Sample_P Sample_AC Sample_AP
Sample_D Sample_Q Sample_AD Sample_AQ
Sample_E Sample_R Sample_AE Sample_AR
Sample_F Sample_S Sample_AF Sample_AS
Sample_G Sample_T Sample_AG Sample_AT
Sample_H Sample_U Sample_AH Sample_AU
Sample_I Sample_V Sample_AI Sample_AV
Sample_J Sample_W Sample_AJ Sample_AW
Sample_K Sample_X Sample_AK Sample_AX
Sample_L Sample_Y Sample_AL Sample_AY
Sample_M Sample_Z Sample_AM Sample_AZ

PCA plots for each dataset can be used to assess if any bridge samples are outliers in the dataset.

#### Extract bridging samples

data_explore3072_before_br <- data_explore3072 |>
  dplyr::filter(SampleType == "SAMPLE") |>
  # Note that if `SampleType` is not is input data,
  # stringr::str_detect can be used to exclude control samples
  #  based on naming convention.
  dplyr::mutate(Type = if_else(SampleID %in% overlapping_samples,
                               paste0("Explore 3072 Bridge"),
                               paste0("Explore 3072 Sample")))

data_exploreht_before_br <- data_exploreht |>
  dplyr::filter(SampleType == "SAMPLE") |>
  dplyr::mutate(Type = if_else(SampleID %in% overlapping_samples,
                               paste0("Explore HT Bridge"),
                               paste0("Explore HT Sample")))

### PCA plot
pca_E3072 <- OlinkAnalyze::olink_pca_plot(df = data_explore3072_before_br,
                                         color_g = "Type",
                                         quiet = TRUE)
pca_EHT <- OlinkAnalyze::olink_pca_plot(df = data_exploreht_before_br,
                                        color_g = "Type",
                                        quiet = TRUE)
PCA plot prior to bridging for Explore 3072 and Explore HT data. Bridge samples are indicated by color. PCA plots can be helpful in assessing if any bridge samples were outliers in one of the platforms.

PCA plot prior to bridging for Explore 3072 and Explore HT data. Bridge samples are indicated by color. PCA plots can be helpful in assessing if any bridge samples were outliers in one of the platforms.

Normalization

The olink_normalization() functionality has been expanded and can be used to determine which assays are bridgeable and of the bridgeable assays what normalization method is advised, and to calculate normalized NPX values for the Explore 3072 (non-reference) project. Normalized NPX values are calculated for all assays across products as described in the Workflow Overview and in the sections below. Within this function, the bridging recommendations for each assay are determined and the NPX values are normalized using the two methods described below.

# Find shared samples
npx_ht <- data_exploreht |>
  dplyr::mutate(Project = "data1") 
npx_3072 <- data_explore3072 |>
  dplyr::mutate(Project = "data2")

npx_br_data <- olink_normalization(df1 = npx_ht, 
                                   df2 = npx_3072,
                                   overlapping_samples_df1 =
                                     overlapping_samples,
                                   df1_project_nr = "Explore HT",
                                   df2_project_nr = "Explore 3072",
                                   reference_project = "Explore HT")

Determining bridging recommendations

For an assay to be bridgeable across products, it must either have signal in both products or be primarily background signal in both products. Bridging noise into signal or signal into noise can negatively impact downstream statistical analysis. To determine if an assay is bridgeable, the bridge samples from both products are used to assess the following criteria:

For assays that are bridgeable, the shape of the NPX distribution is compared between the two products:

An overview of these criteria is visualized below.

Criteria to determine the bridging recommendation for an assay. The assessment of linearity ensures bridging between signal in both platforms or noise in both platforms (but not between signal and noise). Similar NPX ranges and sufficient counts provide additional insight into an assay's bridgeability. Distribution shape is assessed to determine recommended bridging method.

Criteria to determine the bridging recommendation for an assay. The assessment of linearity ensures bridging between signal in both platforms or noise in both platforms (but not between signal and noise). Similar NPX ranges and sufficient counts provide additional insight into an assay’s bridgeability. Distribution shape is assessed to determine recommended bridging method.



Prior to assessment, outlier bridging samples are excluded. A sample is considered an outlier if the NPX value is more than 3 times the interquartile range above or below the median on either product.

After assessment, an assay is considered bridgeable if it meets the first three criteria. The fourth criteria determines which normalization method is recommended for bridging. If all four criteria are met then the recommended method is normalization using the median of paired differences. If only the first three criteria are met then quantile smoothing is recommended. If any of the first three criteria are not met then bridging is not recommended for that assay. Note that bridgeable assays will differ between projects based on the expression of bridge samples in the studies.

Normalization using the median of paired differences

If it is expected that both the kind of distribution and the variance per test between runs are the same, then normalization using the median of paired differences will be preferred. Normalization using the median of paired differences based on the bridging samples is performed in the following steps:

  1. For each assay in the Explore 3072 project, the pairwise difference is calculated for each of the bridging samples with the Explore HT project.

  2. The normalization factor is estimated for each assay by finding the median of the pairwise differences.

  3. The assay-specific normalization factor for each assay is used to normalize each data point from Explore 3072 to Explore HT.

Quantile smoothing

Since Explore HT and Explore 3072 are two distinct products with different workflows involved in generating NPX data, some of the assays exist in corresponding but distinct NPX spaces. For those assays, the median of paired differences is insufficient for bridging as it only considers one anchor point (the median/50% quantile). Instead, quantile smoothing (QS) using multiple anchor points (5%, 10%, 25%, 50%, 75%, 90% and 95% quantiles) is favored to map the Explore 3072 data to the Explore HT distribution. The normalization using QS uses bridging samples to perform the following steps:

  1. Each data point of the samples from Explore 3072 is mapped to the equivalent space in Explore HT using an empirical cumulative distribution function. An empirical cumulative distribution function is a probability model which uses the observed data, in this case the NPX values of the bridging samples for an assay, to create a step function which interpolates linearly between the available data points.

  2. The empirical distribution function is used to map the data points from Explore 3072 to the Explore HT space using the specified quantiles. At this point all data points from the bridging samples have NPX values that are normalized to the data points in Explore HT.

  3. To normalize the remaining data, a spline regression model is constructed using the sorted Explore 3072 data (prior to mapping) and the mapped Explore 3072 data, along with the anchor points of the spline function. A spline regression model divides a data set at the quantiles and uses the quantile as an anchor point or knot. Then a model is generated to fit the points between each anchor point.

  4. The spline regression model is then used to predict all the data points from Explore 3072 to Explore HT. The spline regression model results in a combination of linear regression models within intervals. The Explore 3072 NPX values are input as the x value within the corresponding interval, which results in a y value equivalent to the Explore HT NPX value.

Function Output

The output from olink_normalization() function when used for between product bridging is a dataframe with concatenated data from the two products and additional columns including adjusted NPX values, bridging recommendations, mapping information, and project names. The adjusted NPX values are notated in the columns MedianCenteredNPX and QSNormalizedNPX. For each assay a recommendation is listed in the BridgingRecommendation column and lists what method, if any should be used for that assay. Additional columns including OlinkID and OlinkID_E3072 map the assays across products and the Project column lists the name of the project based on the df1_project_nr and df2_project_nr arguments. The resulting data set will contain the newly bridged Explore 3072 data set. The reference Explore HT data will be concatenated to the Explore 3072 data. As the reference data is not altered during normalization, the normalized NPX values in the Explore HT data will be the same as the values in the NPX column which contains the non-normalized data.

Table 4. First 5 rows of combined datasets after bridging.
SampleID OlinkID SampleType WellID PlateID UniProt Assay AssayType Panel Block NPX PCNormalizedNPX Count Normalization AssayQC SampleQC DataAnalysisRefID Project OlinkID_E3072 MedianCenteredNPX QSNormalizedNPX BridgingRecommendation
Sample_A OID40770 SAMPLE A1 Plate1 P08319 ADH4 assay Cardiometabolic A 2.5 2.5 237 Plate control PASS PASS DAR001 Explore 3072 OID20117 0.8 1.3 QuantileSmoothing
Sample_A OID40835 SAMPLE A1 Plate1 P18848 ATF4 assay Oncology_II A 1.0 1.0 186 Plate control PASS PASS DAR002 Explore 3072 OID31162 2.1 0.9 MedianCentering
Sample_A OID40981 SAMPLE A1 Plate1 O76039 CDKL5 assay Neurology_II A 2.2 2.2 122 Plate control PASS PASS DAR003 Explore 3072 OID30796 0.6 0.9 QuantileSmoothing
Sample_A OID40986 SAMPLE A1 Plate1 P17676 CEBPB assay Cardiometabolic A 1.1 1.1 419 Plate control PASS PASS DAR001 Explore 3072 OID20052 0.1 0.1 QuantileSmoothing
Sample_A OID41012 SAMPLE A1 Plate1 O96017 CHEK2 assay Cardiometabolic A -2.0 -0.7 423 Plate control PASS PASS DAR001 Explore 3072 OID20054 -2.7 -0.4 NotBridgeable

Evaluating the quality of bridging

PCA is used to assess the quality of bridging by determining if the sample controls (SCs) and bridging samples appear closer after bridging. Two PCAs can be generated, one containing the SCs and one containing the bridging samples. Prior to bridging there will be a noticeable separation between products which should decrease after bridging.

## Before Bridging
npx_br_data |> 
  dplyr::filter(SampleType == "SAMPLE_CONTROL") |> 
  dplyr::mutate(OlinkID = paste0(OlinkID, "_", OlinkID_E3072)) |> 
  dplyr:::mutate(SampleID = paste0(Project, SampleID)) |> 
  OlinkAnalyze::olink_pca_plot(color_g = "Project")
Combined PCA of sample controls from both platforms prior to normalization.

Combined PCA of sample controls from both platforms prior to normalization.

## Before Bridging
npx_br_data |> 
  dplyr::filter(SampleType == "SAMPLE") |> 
  dplyr::filter(SampleID %in% overlapping_samples) |> 
  dplyr::mutate(OlinkID = paste0(OlinkID, "_", OlinkID_E3072)) |> 
  dplyr:::mutate(SampleID = paste0(Project, SampleID)) |> 
  OlinkAnalyze::olink_pca_plot(color_g = "Project")
  
Combined PCA of bridging samples from both platforms prior to normalization.

Combined PCA of bridging samples from both platforms prior to normalization.

## After bridging PCA

### Keep the data following BridgingRecommendation
npx_after_br_reco <- npx_br_data |>
  dplyr::filter(BridgingRecommendation != "NotBridgeable") |>
  dplyr::mutate(NPX = case_when(
    BridgingRecommendation == "MedianCentering" ~ MedianCenteredNPX,
    BridgingRecommendation == "QuantileSmoothing" ~ QSNormalizedNPX,
    .default = NPX)) |>
  dplyr::filter(AssayType == "assay") |> 
  dplyr::mutate(OlinkID = paste0(OlinkID, "_", OlinkID_E3072))

### Generate unique SampleIDs
npx_after_br_final <- npx_after_br_reco |>
  dplyr:::mutate(SampleID = paste0(Project, SampleID))
  
### PCA plot of the data from SCs
npx_after_br_final |> 
    dplyr::filter(SampleType == "SAMPLE_CONTROL") |> 
    OlinkAnalyze::olink_pca_plot(color_g = "Project")
  
Combined PCA of sample controls from both platforms after normalization.

Combined PCA of sample controls from both platforms after normalization.

### PCA plot of the data from bridging samples
npx_after_br_reco |> 
  dplyr::filter(SampleType == "SAMPLE") |> 
  dplyr::filter(SampleID %in% overlapping_samples) |> 
  dplyr:::mutate(SampleID = paste0(Project, SampleID)) |> 
  OlinkAnalyze::olink_pca_plot(color_g = "Project")
Combined PCA of bridging samples from both platforms after normalization.

Combined PCA of bridging samples from both platforms after normalization.

Exporting Normalized Data

The normalized Explore 3072 data can be exported using arrow::write_parquet() to create a long format Olink Explore file.

df <- npx_br_data |>
    dplyr::filter(Project == "Explore_3072") |>
    arrow::as_arrow_table()

df$metadata$FileVersion <- "NA"
df$metadata$ExploreVersion <- "NA"
df$metadata$ProjectName <- "NA"
df$metadata$SampleMatrix <- "NA"
df$metadata$DataFileType <- "Olink Analyze Export File"
df$metadata$ProductType <- "Explore3072"
df$metadata$Product <- "Explore3072"
arrow::write_parquet(x = df, sink = "path_to_output.parquet")

FAQs

Overlapping Assays within products

Both the Explore 3072 and Explore HT products contain assays that appear multiple times in the product, known as overlapping assays or correlation assays. In Explore 3072, these present as overlapping assays across panels. In Explore HT, these are overlapping assays across blocks. These assays are included for QC purposes and allow users to evaluate data performance across panels in Explore 3072 and across blocks in Explore HT. Within each product, the assays contain unique OlinkID values for each of their corresponding panels and blocks in Explore 3072 and Explore HT, respectively.

IL6, IL8 (CXCL8), and TNF are included in the Cardiometabolic, Oncology, Neurology and Inflammation panels, while IDO1, LMOD1, and SCRIB are included in the Cardiometabolic II, Oncology II, Neurology II and Inflammation II panels. Each correlation assay is measured four times in an Olink Explore 3072 run. In Explore HT, GBP1 and MAPK1 serve as overlapping assays and are measured three times in a run.

Downstream Analysis

Olink Analyze statistical analysis functions default to use the data in the NPX column. This means that if the resulting data from the olink_normalization() function is used in a downstream analysis function, then the non-normalized NPX data will be used. To use the recommended normalized data, dplyr::mutate() can be used to reassign the NPX data. Additionally, to ensure that overlapping assays within products are analyzed individually, OlinkID can be temporarily assigned to the concatenated version of the OlinkIDs. This dataframe can then be used in any downstream analysis function within Olink Analyze.

Assays which are not recommended for bridging should be analyzed separately and can be combined using a meta-analysis. Depending on the study design these assays can either be excluded from the downstream analysis or the assays can be treated as non-overlapping assays.

# Option 1: Exclude non bridgeable assays from both products
npx_recommended <- npx_after_br_final |> 
  dplyr::mutate(NPX_original = NPX) |> 
  dplyr::filter(BridgingRecommendation != "NotBridgeable") |>
  dplyr::mutate(NPX = case_when(
    BridgingRecommendation == "MedianCentering" ~ MedianCenteredNPX,
    BridgingRecommendation == "QuantileSmoothing" ~ QSNormalizedNPX,
    .default = NPX)) |> 
  dplyr::mutate(OlinkID_HT = OlinkID) |> 
  dplyr::mutate(OlinkID = paste0(OlinkID, "_", OlinkID_E3072))

# Option 2: Analyze non bridgeable assays separately
npx_recommended <- npx_after_br_final |> 
  dplyr::mutate(NPX_original = NPX) |> 
  dplyr::mutate(NPX = case_when(
    BridgingRecommendation == "MedianCentering" ~ MedianCenteredNPX,
    BridgingRecommendation == "QuantileSmoothing" ~ QSNormalizedNPX,
    .default = NPX)) |> 
  dplyr::mutate(OlinkID_HT = OlinkID) |> 
  dplyr::mutate(OlinkID = ifelse(BridgingRecommendation != "NotBridgeable",
                                 paste0(OlinkID, "_", OlinkID_E3072), 
                                 # Concatenated OlinkID for bridgeable Assays
                                 ifelse(Project == "Explore HT", 
                                        # replace with HT project name as set in function
                                        OlinkID, 
                                        OlinkID_E3072))

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