Query artifacts¶
Here, we’ll query artifacts and inspect their metadata.
This guide can be skipped if you are only interested in how to leverage the overall collection.
import lamindb as ln
import bionty as bt
→ connected lamindb: testuser1/test-scrna
ln.context.uid = "agayZTonayqA0000"
ln.context.track()
→ notebook imports: bionty==0.49.0 lamindb==0.76.3
→ created Transform('agayZTonayqA0000') & created Run('2024-09-04 11:39:41.275922+00:00')
Query artifacts by provenance metadata¶
users = ln.User.lookup()
ln.Transform.filter(created_by=users.testuser1).search("scrna").df()
| uid | version | is_latest | name | key | description | type | source_code | hash | reference | reference_type | _source_code_artifact_id | created_by_id | updated_at | |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| id | ||||||||||||||
| 1 | Nv48yAceNSh80000 | None | True | scRNA-seq | scrna.ipynb | None | notebook | None | None | None | None | None | 1 | 2024-09-04 11:37:52.072365+00:00 |
| 2 | ManDYgmftZ8C0000 | None | True | Standardize and append a batch of data | scrna2.ipynb | None | notebook | None | None | None | None | None | 1 | 2024-09-04 11:39:15.299152+00:00 |
| 3 | agayZTonayqA0000 | None | True | Query artifacts | scrna3.ipynb | None | notebook | None | None | None | None | None | 1 | 2024-09-04 11:39:41.272218+00:00 |
transform = ln.Transform.get(uid="Nv48yAceNSh80000")
ln.Artifact.filter(transform=transform).df()
| uid | version | is_latest | description | key | suffix | type | size | hash | n_objects | n_observations | _hash_type | _accessor | visibility | _key_is_virtual | storage_id | transform_id | run_id | created_by_id | updated_at | |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| id | ||||||||||||||||||||
| 1 | tTIivRK02X3JjvVk0000 | None | True | Human immune cells from Conde22 | None | .h5ad | dataset | 57612943 | 9sXda5E7BYiVoDOQkTC0KB | None | 1648 | sha1-fl | AnnData | 1 | True | 1 | 1 | 1 | 1 | 2024-09-04 11:39:08.825902+00:00 |
Query artifacts by biological metadata¶
organism = bt.Organism.lookup()
tissues = bt.Tissue.lookup()
query = ln.Artifact.filter(
organisms=organism.human,
tissues=tissues.bone_marrow,
)
query.df()
| uid | version | is_latest | description | key | suffix | type | size | hash | n_objects | n_observations | _hash_type | _accessor | visibility | _key_is_virtual | storage_id | transform_id | run_id | created_by_id | updated_at | |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| id |
Inspect artifact metadata¶
query_set = ln.Artifact.filter().all()
artifact1, artifact2 = query_set[0], query_set[1]
artifact1.describe()
Artifact(uid='tTIivRK02X3JjvVk0000', is_latest=True, description='Human immune cells from Conde22', suffix='.h5ad', type='dataset', size=57612943, hash='9sXda5E7BYiVoDOQkTC0KB', n_observations=1648, _hash_type='sha1-fl', _accessor='AnnData', visibility=1, _key_is_virtual=True, updated_at='2024-09-04 11:39:08 UTC')
Provenance
.created_by = 'testuser1'
.storage = '/home/runner/work/lamin-usecases/lamin-usecases/docs/test-scrna'
.transform = 'scRNA-seq'
.run = '2024-09-04 11:37:52 UTC'
.input_of_runs = ["'2024-09-04 11:39:15 UTC'"]
Labels
.tissues = 'blood', 'thoracic lymph node', 'spleen', 'lung', 'mesenteric lymph node', 'lamina propria', 'liver', 'jejunal epithelium', 'omentum', 'bone marrow', ...
.cell_types = 'classical monocyte', 'T follicular helper cell', 'memory B cell', 'alveolar macrophage', 'naive thymus-derived CD4-positive, alpha-beta T cell', 'effector memory CD8-positive, alpha-beta T cell, terminally differentiated', 'alpha-beta T cell', 'CD4-positive helper T cell', 'naive thymus-derived CD8-positive, alpha-beta T cell', 'macrophage', ...
.experimental_factors = '10x 3' v3', '10x 5' v2', '10x 5' v1'
.ulabels = 'D496', '621B', 'A29', 'A36', 'A35', '637C', 'A52', 'A37', 'D503', '640C', ...
Features
'assay' = '10x 3' v3', '10x 5' v2', '10x 5' v1'
'cell_type' = 'classical monocyte', 'T follicular helper cell', 'memory B cell', 'alveolar macrophage', 'naive thymus-derived CD4-positive, alpha-beta T cell', 'effector memory CD8-positive, alpha-beta T cell, terminally differentiated', 'alpha-beta T cell', 'CD4-positive helper T cell', 'naive thymus-derived CD8-positive, alpha-beta T cell', 'macrophage', ...
'donor' = 'D496', '621B', 'A29', 'A36', 'A35', '637C', 'A52', 'A37', 'D503', '640C', ...
'tissue' = 'blood', 'thoracic lymph node', 'spleen', 'lung', 'mesenteric lymph node', 'lamina propria', 'liver', 'jejunal epithelium', 'omentum', 'bone marrow', ...
Feature sets
'var' = 'MIR1302-2HG', 'FAM138A', 'OR4F5', 'None', 'OR4F29', 'OR4F16', 'LINC01409', 'FAM87B', 'LINC01128', 'LINC00115', 'FAM41C'
'obs' = 'donor', 'tissue', 'cell_type', 'assay'
artifact1.view_lineage()
artifact2.describe()
Artifact(uid='x7bINozXr7yzDY5D0000', is_latest=True, description='10x reference adata', suffix='.h5ad', type='dataset', size=853388, hash='jxR7kj0-xk-84u5sv3J9CQ', n_observations=70, _hash_type='md5', _accessor='AnnData', visibility=1, _key_is_virtual=True, updated_at='2024-09-04 11:39:35 UTC')
Provenance
.created_by = 'testuser1'
.storage = '/home/runner/work/lamin-usecases/lamin-usecases/docs/test-scrna'
.transform = 'Standardize and append a batch of data'
.run = '2024-09-04 11:39:15 UTC'
Labels
.cell_types = 'B cell, CD19-positive', 'dendritic cell', 'effector memory CD4-positive, alpha-beta T cell, terminally differentiated', 'cytotoxic T cell', 'CD8-positive, CD25-positive, alpha-beta regulatory T cell', 'CD16-positive, CD56-dim natural killer cell, human', 'CD14-positive, CD16-negative classical monocyte', 'CD38-positive naive B cell', 'CD38-high pre-BCR positive cell'
Features
'cell_type' = 'B cell, CD19-positive', 'dendritic cell', 'effector memory CD4-positive, alpha-beta T cell, terminally differentiated', 'cytotoxic T cell', 'CD8-positive, CD25-positive, alpha-beta regulatory T cell', 'CD16-positive, CD56-dim natural killer cell, human', 'CD14-positive, CD16-negative classical monocyte', 'CD38-positive naive B cell', 'CD38-high pre-BCR positive cell'
Feature sets
'var' = 'TLE5', 'S1PR4', 'CD164', 'SMIM24', 'DCAF10', 'RAB13', 'TPM3', 'HES4', 'HAX1', 'ADD3', 'GSTK1', 'GTF3C6', 'SNX2', 'ACAA1', 'MATK', 'ZYX', 'JAML', 'CD3E', 'CD3D', 'EXOG'
'obs' = 'cell_type'
artifact2.view_lineage()
Compare features¶
Here we compute shared genes:
artifact1_genes = artifact1.features["var"]
artifact2_genes = artifact2.features["var"]
shared_genes = artifact1_genes & artifact2_genes
len(shared_genes)
749
shared_genes.list("symbol")[:10]
['HES4',
'TNFRSF4',
'SSU72',
'PARK7',
'RBP7',
'SRM',
'MAD2L2',
'AGTRAP',
'TNFRSF1B',
'EFHD2']
Compare cell types¶
artifact1_celltypes = artifact1.cell_types.all()
artifact2_celltypes = artifact2.cell_types.all()
shared_celltypes = artifact1_celltypes & artifact2_celltypes
shared_celltypes_names = shared_celltypes.list("name")
shared_celltypes_names
['CD16-positive, CD56-dim natural killer cell, human']
Load the individual artifacts¶
We could either load the artifacts into memory or access them in backed mode through .open() to lazily load their content.
Let’s load them into memory:
adata1 = artifact1.load()
adata2 = artifact2.load()
We can now subset the two collections by shared cell types:
adata1_subset = adata1[adata1.obs["cell_type"].isin(shared_celltypes_names)]
adata2_subset = adata2[adata2.obs["cell_type"].isin(shared_celltypes_names)]