Widgets
- Corpus
- Import Documents
- Create Corpus
- The Guardian
- NY Times
- Pubmed
- Twitter
- Wikipedia
- Preprocess Text
- Corpus to Network
- Bag of Words
- Document Embedding
- Similarity Hashing
- Sentiment Analysis
- Tweet Profiler
- Topic Modelling
- LDAvis
- Corpus Viewer
- Score Documents
- Word Cloud
- Concordance
- Document Map
- Word Enrichment
- Duplicate Detection
- Word List
- Extract Keywords
- Annotated Corpus Map
- Ontology
- Semantic Viewer
- Collocations
- Statistics
Score Cells
Add a cell score based on the given set of genes.
Inputs
- Data: input dataset
- Genes: dataset with gene names
Outputs
- Data: dataset with a meta column reporting on cell scores
Score Cells scores the cells (rows) in the input data based on expression of input marker genes. Input data has to include gene names in column headers (as attribute names). The score is computed independently for each cell and is equal to the maximum expression of the marker genes. If expressions for all the marker genes are missing, the cell obtains a score of zero. If Genes input is provided, one of the columns must include names of genes that match those from expression data.
- A column name from table on genes that provides names of genes that are included in the input gene expression table.
- Tick to automatically process input data and send the result of scoring to the output. If left unchecked, processing must be triggered manually.
Example
We will use Single Cell Datasets widget to load Bone marrow mononuclear cells with AML (sample) data. Then we will pass it through k-Means and select 2 clusters from Silhouette Scores. Ok, it looks like there might be two distinct clusters here.
But can we find subpopulations in these cells? Let us load Bone marrow mononuclear cells with AML (markers) with Single Cell Datasets. Now, pass the marker genes to Data Table and select, for example, natural killer cells from the list (NKG7).
Pass the markers and k-Means results to Score Cells widget and select geneName to match markers with genes. Finally, add t-SNE to visualize the results.
In t-SNE, use Scores attribute to color the points and set their size. We see that killer cells are nicely clustered together and that t-SNE indeed found subpopulations.