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MIMIC-II IAC Patient Fate#
In the previous introduction tutorial, we explored the MIMIC-II IAC dataset, comprising electronic health records (EHR) of 1776 patients in 46 features, and identified patient group-specific clusters using ehrapy. Please go through the MIMIC-II IAC introduction before performing this tutorial to get familiar with the dataset.
As a next step, we want to determine patient fate. The goal is to detect terminal states and the corresponding origins based on pseudotime. Real time very rarely reflects the actual progression of a disease. When measurements are done on a certain day, some patients will show no sign of disease (e.g. healthy or recovered), some are at the onset of a specific disease and some are in a more severe stage or even at the height. For an appropriate analysis, we are interested in a continuous transition of states, such as from healthy to diseased to death, for which the real time is therefore not informative. Identification of transition states can be achieved by identifying source states (e.g. healthy) and then calculating pseudotime from this state. Based on Markov chain modelling, we uncover patient dynamics using CellRank. For more details, please read the CellRank paper.
In this tutorial we will be using CellRank to:
Simulate patient trajectories with random walks.
Compute patient macrostates and infer fate probabilities towards predicted terminal states.
Identify potential driver features for each identified trajectory.
Visualize feature trends along specific patient states, while accounting for the continuous nature of fate determination.
Before performing this tutorial, we highly recommend to read the extensive and well written CellRank documentation, especially the general tutorial chapter is useful. If you are not familiar with single-cell data, do not be afraid and replace cells with patients visits and genes with features in your mind.
This tutorial requires cellrank
to be installed. As this packages is not a dependency of ehrapy, it must be installed separately.
[1]:
%%capture --no-display
!pip install cellrank
Before we start with the patient fate analysis of the MIMIC-II IAC dataset, we set up our environment including the import of packages and preparation of the dataset.
Environment setup#
Ensure that the latest version of ehrapy is installed. A list of all dependency versions can be found at the end of this tutorial.
[2]:
import ehrapy as ep
import seaborn as sns
import matplotlib.pyplot as plt
from matplotlib import rcParams
import pandas as pd
import cellrank as cr
import scvelo as scv
import numpy as np
We are ignoring a few warnings for readability reasons.
[3]:
import warnings
warnings.filterwarnings("ignore")
Getting and preprocessing the MIMIC-II dataset#
This tutorial is based on the MIMIC-II IAC dataset which was previously introduced in the MIMIC-II IAC introduction tutorial. We will load the encoded version of the dataset as an AnnData object, ehrapy’s default encoding is a simple one-hot encoding in this case.
[4]:
%%capture
adata = ep.dt.mimic_2(encoded=False)
adata
2023-08-10 17:59:28,683 - root INFO - Added all columns to `obs`.
2023-08-10 17:59:28,699 - root INFO - Transformed passed dataframe into an AnnData object with n_obs x n_vars = `1776` x `46`.
The MIMIC-II dataset has 1776 patients with 46 features. Now that we have our AnnData object ready, we need to perform the standard preprocessing steps as performed in the introduction tutorial again before we can use ehrapy and CellRank for patient fate analysis.
[5]:
%%capture
adata = ep.pp.encode(adata, encodings={"one_hot_encoding": ["service_unit", "day_icu_intime"]})
ep.pp.knn_impute(adata, n_neighbours=5)
ep.pp.log_norm(adata, vars=['iv_day_1', "po2_first"], offset=1)
ep.pp.pca(adata)
ep.pp.neighbors(adata, n_pcs=10)
ep.tl.umap(adata)
ep.tl.leiden(adata, resolution=0.3, key_added="leiden_0_3")
2023-08-10 17:59:28,707 - root INFO - The original categorical values `['service_unit', 'day_icu_intime']` were added to uns.
2023-08-10 17:59:28,739 - root INFO - Updated the original layer after encoding.
2023-08-10 17:59:28,747 - root INFO - Added `['service_unit', 'day_icu_intime']` columns to `X`.
2023-08-10 17:59:28,751 - root INFO - The original categorical values `['service_unit', 'day_icu_intime']` were added to obs.
2023-08-10 17:59:28,883 - root INFO - Added the calculated metrics to AnnData's `obs` and `var`.
2023-08-10 17:59:29,208 - root INFO - Values in columns ['iv_day_1', 'po2_first'] were replaced by [[5.2832036 7.7105975]
[5.1973915 6.398595 ]
[5.7004437 7.643866 ]
...
[5.757007 5.0657544]
[4.4426513 3.125444 ]
[6.35437 8.38229 ]].
[6]:
ep.settings.set_figure_params(figsize=(5, 4), dpi = 100)
ep.pl.umap(adata, color=["leiden_0_3"], title="Leiden 0.3", size = 20)
This UMAP embedding is exactly the same as previously computed in the MIMIC-II IA introduction tutorial. Now we continue with the patient fate analysis.
Analysis using ehrapy and CellRank#
Depending on the data it may not always be possible to clearly define a cluster or specific patient visits as the origin or terminus of a trajectory. Working with single-cell data simplifies matters since the detection of stem cells generally signifies the start of cell differentiation.
In this tutorial, we will define a patient cluster as the origin (root cluster) and explore possible terminal states.
Pseudotime calculation#
As the root cluster for pseudotime calculation we choose cluster 0 since patients in that cluster do not show very severe comorbidities and features yet. Then we calculate the Diffusion Pseudotime with the el.dpt()
function.
[7]:
adata.uns["iroot"] = np.flatnonzero(adata.obs["leiden_0_3"] == "0")[0]
ep.tl.dpt(adata)
WARNING: Trying to run `tl.dpt` without prior call of `tl.diffmap`. Falling back to `tl.diffmap` with default parameters.
Now we define the kernel, compute the transition matrix and plot a projection onto the UMAP.
Determining patient fate with a PseudotimeKernel#
The PseudotimeKernel computes direct transition probabilities based on a KNN graph and pseudotime.
The KNN graph contains information about the (undirected) conductivities among cells, reflecting their similarity. Pseudotime can be used to either remove edges that point against the direction of increasing pseudotime, or to downweight them.
[8]:
from cellrank.kernels import PseudotimeKernel
pk = PseudotimeKernel(adata, time_key = "dpt_pseudotime")
pk.compute_transition_matrix()
[8]:
PseudotimeKernel[n=1776, dnorm=False, scheme='hard', frac_to_keep=0.3]
[9]:
ep.settings.set_figure_params(figsize=(5, 4), dpi = 100)
pk.plot_projection(basis="umap", color="leiden_0_3")
We observe that two main trajectories originating from cluster 0 going to clusters 4 and 2. Let’s check the metadata again.
[10]:
ep.pl.umap(adata, color = "censor_flg", title = "Censored or Death (0 = death, 1 = censored)")
ep.pl.umap(adata, color = "mort_day_censored", title = "Day post ICU admission of censoring or death")
Cluster 2 consists of patients that deceased and had severe comorbidities while cluster 4 includes patients with a high day post ICU admission.
Simulating transitions with random walks#
Cellrank makes it easy to simulate the behavior of random walks from specific clusters. This allows us to not only visualize where the patients end up, but also roughly how many in which clusters after a defined number of iterations. We can either just start walking…
[11]:
pk.plot_random_walks(
seed=0,
n_sims=100,
start_ixs={"leiden_0_3": ["0"]},
legend_loc="right",
dpi=100,
show_progress_bar=False
)
… or set a number of required hits in one or more terminal clusters. Here, we require 50 hits in cluster 2 or 4.
[12]:
pk.plot_random_walks(
seed=0,
n_sims=100,
start_ixs={"leiden_0_3": ["0"]},
stop_ixs={"leiden_0_3": ["2", "4"]},
successive_hits = 50,
legend_loc="right",
dpi=100,
show_progress_bar=False
)
Black and yellow dots indicate random walk start and terminal patient visits, respectively.
Determining macrostates and terminal states#
To find the terminal states of cluster 0, well will use an estimator to predict the patient fates using the above calculated transition matrix. The main objective is to decompose the patient state space into a set of macrostates, that represent the slow-time scale dynamics of the process and predict terminal states. Here, we will use an Generalized Perron Cluster Cluster Analysis (GPCCA) estimator.
As a first step we try to identify macrostates in the data using the fit()
function.
[13]:
g = cr.estimators.GPCCA(pk)
g.fit(cluster_key="leiden_0_3")
g.macrostates_memberships
WARNING: Unable to import `petsc4py` or `slepc4py`. Using `method='brandts'`
WARNING: For `method='brandts'`, dense matrix is required. Densifying
[13]:
2_1 | 2_2 | 4 |
---|---|---|
0.269916 | 0.729933 | 0.000151 |
0.031573 | 0.197438 | 0.770989 |
0.032702 | 0.190196 | 0.777102 |
0.072695 | 0.927274 | 0.000031 |
0.034733 | 0.852121 | 0.113145 |
0.024949 | 0.435004 | 0.540046 |
0.026108 | 0.737380 | 0.236511 |
0.069814 | 0.868942 | 0.061245 |
0.030265 | 0.218087 | 0.751648 |
0.017000 | 0.982999 | 0.000001 |
... | ... | ... |
0.084016 | 0.915038 | 0.000945 |
0.018946 | 0.981051 | 0.000003 |
0.007253 | 0.064232 | 0.928515 |
0.029628 | 0.131999 | 0.838373 |
0.138710 | 0.861214 | 0.000076 |
0.024621 | 0.482775 | 0.492604 |
0.101163 | 0.898778 | 0.000060 |
0.232216 | 0.767657 | 0.000128 |
0.010151 | 0.989821 | 0.000027 |
0.284932 | 0.709794 | 0.005274 |
1776 cells x 3 lineages
[14]:
g.predict_terminal_states()
g.plot_macrostates(which="terminal")
[15]:
g.plot_macrostates(which = "terminal", same_plot=False)
As a next step we will calculate the fate probabilities. For each patient visit, this computes the probability of being absorbed in any of the terminal states by aggregating over all random walks that start in a given patient visit and end in some terminal population.
[16]:
g.compute_fate_probabilities(preconditioner="ilu", tol=1e-15)
g.plot_fate_probabilities()
WARNING: Unable to import petsc4py. For installation, please refer to: https://petsc4py.readthedocs.io/en/stable/install.html.
Defaulting to `'gmres'` solver.
WARNING: `3` solution(s) did not converge
The plot above combines fate probabilities towards all terminal states, each patient visit is colored according to its most likely fate, color intensity reflects the degree of fate priming.
[17]:
g.plot_fate_probabilities(same_plot=False)
╭─────────────────────────────────────── Traceback (most recent call last) ───────────────────────────────────────╮ │ /home/zeth/miniconda3/envs/ehrapy/lib/python3.10/site-packages/IPython/core/formatters.py:223 in │ │ catch_format_error │ │ │ │ 220 def catch_format_error(method, self, *args, **kwargs): │ │ 221 │ """show traceback on failed format call""" │ │ 222 │ try: │ │ ❱ 223 │ │ r = method(self, *args, **kwargs) │ │ 224 │ except NotImplementedError: │ │ 225 │ │ # don't warn on NotImplementedErrors │ │ 226 │ │ return self._check_return(None, args[0]) │ │ │ │ /home/zeth/miniconda3/envs/ehrapy/lib/python3.10/site-packages/IPython/core/formatters.py:340 in __call__ │ │ │ │ 337 │ │ │ except KeyError: │ │ 338 │ │ │ │ pass │ │ 339 │ │ │ else: │ │ ❱ 340 │ │ │ │ return printer(obj) │ │ 341 │ │ │ # Finally look for special method names │ │ 342 │ │ │ method = get_real_method(obj, self.print_method) │ │ 343 │ │ │ if method is not None: │ │ │ │ /home/zeth/miniconda3/envs/ehrapy/lib/python3.10/site-packages/IPython/core/pylabtools.py:169 in retina_figure │ │ │ │ 166 │ .. versionadded:: 7.29 │ │ 167 │ │ base64 argument │ │ 168 │ """ │ │ ❱ 169 │ pngdata = print_figure(fig, fmt="retina", base64=False, **kwargs) │ │ 170 │ # Make sure that retina_figure acts just like print_figure and returns │ │ 171 │ # None when the figure is empty. │ │ 172 │ if pngdata is None: │ │ │ │ /home/zeth/miniconda3/envs/ehrapy/lib/python3.10/site-packages/IPython/core/pylabtools.py:152 in print_figure │ │ │ │ 149 │ │ from matplotlib.backend_bases import FigureCanvasBase │ │ 150 │ │ FigureCanvasBase(fig) │ │ 151 │ │ │ ❱ 152 │ fig.canvas.print_figure(bytes_io, **kw) │ │ 153 │ data = bytes_io.getvalue() │ │ 154 │ if fmt == 'svg': │ │ 155 │ │ data = data.decode('utf-8') │ │ │ │ /home/zeth/miniconda3/envs/ehrapy/lib/python3.10/site-packages/matplotlib/backend_bases.py:2353 in print_figure │ │ │ │ 2350 │ │ │ │ │ bbox_inches = bbox_inches.padded(pad_inches) │ │ 2351 │ │ │ │ │ │ 2352 │ │ │ │ # call adjust_bbox to save only the given area │ │ ❱ 2353 │ │ │ │ restore_bbox = _tight_bbox.adjust_bbox( │ │ 2354 │ │ │ │ │ self.figure, bbox_inches, self.figure.canvas.fixed_dpi) │ │ 2355 │ │ │ │ │ │ 2356 │ │ │ │ _bbox_inches_restore = (bbox_inches, restore_bbox) │ │ │ │ /home/zeth/miniconda3/envs/ehrapy/lib/python3.10/site-packages/matplotlib/_tight_bbox.py:28 in adjust_bbox │ │ │ │ 25 │ for ax in fig.axes: │ │ 26 │ │ locator = ax.get_axes_locator() │ │ 27 │ │ if locator is not None: │ │ ❱ 28 │ │ │ ax.apply_aspect(locator(ax, None)) │ │ 29 │ │ locator_list.append(locator) │ │ 30 │ │ current_pos = ax.get_position(original=False).frozen() │ │ 31 │ │ ax.set_axes_locator(lambda a, r, _pos=current_pos: _pos) │ │ │ │ /home/zeth/miniconda3/envs/ehrapy/lib/python3.10/site-packages/matplotlib/colorbar.py:156 in __call__ │ │ │ │ 153 │ │ │ 154 │ def __call__(self, ax, renderer): │ │ 155 │ │ if self._orig_locator is not None: │ │ ❱ 156 │ │ │ pos = self._orig_locator(ax, renderer) │ │ 157 │ │ else: │ │ 158 │ │ │ pos = ax.get_position(original=True) │ │ 159 │ │ if self._cbar.extend == 'neither': │ │ │ │ /home/zeth/miniconda3/envs/ehrapy/lib/python3.10/site-packages/mpl_toolkits/axes_grid1/inset_locator.py:73 in │ │ __call__ │ │ │ │ 70 │ │ │ 71 │ def __call__(self, ax, renderer): │ │ 72 │ │ self.axes = ax │ │ ❱ 73 │ │ bbox = self.get_window_extent(renderer) │ │ 74 │ │ px, py = self.get_offset(bbox.width, bbox.height, 0, 0, renderer) │ │ 75 │ │ bbox_canvas = Bbox.from_bounds(px, py, bbox.width, bbox.height) │ │ 76 │ │ tr = ax.figure.transSubfigure.inverted() │ │ │ │ /home/zeth/miniconda3/envs/ehrapy/lib/python3.10/site-packages/matplotlib/offsetbox.py:399 in get_window_extent │ │ │ │ 396 │ def get_window_extent(self, renderer=None): │ │ 397 │ │ # docstring inherited │ │ 398 │ │ if renderer is None: │ │ ❱ 399 │ │ │ renderer = self.figure._get_renderer() │ │ 400 │ │ bbox = self.get_bbox(renderer) │ │ 401 │ │ try: # Some subclasses redefine get_offset to take no args. │ │ 402 │ │ │ px, py = self.get_offset(bbox, renderer) │ ╰─────────────────────────────────────────────────────────────────────────────────────────────────────────────────╯ AttributeError: 'NoneType' object has no attribute '_get_renderer'
<Figure size 1500x400 with 6 Axes>
We can also visualize the fate probabilities jointly in a circular projection where each dot represents a patient visit, colored by cluster labels. Patient visits are arranged inside the circle according to their fate probabilities, fate biased visits are placed next to their corresponding corner while undetermined patient fates are placed in the middle.
[18]:
cr.pl.circular_projection(adata, keys="leiden_0_3", legend_loc="right")
Identification of driver features#
We uncover putative driver features by correlating fate probabilities with gene expression using the compute_lineage_drivers()
method. In other words, if a feature is systematically higher or lower in patient visits that are more or less likely to differentiate towards a given terminal states, respectively, then we call this feature a putative driver feature.
We calculate these driver features for our three lineages 2_1
, 2_2
and 4
.
[19]:
%%capture
ep.settings.set_figure_params(figsize=(3, 3), dpi = 100)
[20]:
drivers_2_1 = g.compute_lineage_drivers(lineages="2_1")
adata.obs["fate_probs_2_1"] = g.fate_probabilities["2_1"].X.flatten()
ep.pl.umap(
adata,
color=["fate_probs_2_1"] + list(drivers_2_1.index[:8]),
color_map="viridis",
s=50,
ncols=3,
vmax="p96",
)
/home/zeth/miniconda3/envs/ehrapy/lib/python3.10/site-packages/scanpy/plotting/_tools/scatterplots.py:163: MatplotlibDeprecationWarning: The get_cmap function was deprecated in Matplotlib 3.7 and will be removed two minor releases later. Use ``matplotlib.colormaps[name]`` or ``matplotlib.colormaps.get_cmap(obj)`` instead.
cmap = copy(get_cmap(cmap))
[21]:
drivers_2_2 = g.compute_lineage_drivers(lineages="2_2")
adata.obs["fate_probs_2_2"] = g.fate_probabilities["2_2"].X.flatten()
ep.pl.umap(
adata,
color=["fate_probs_2_2"] + list(drivers_2_2.index[:8]),
color_map="viridis",
s=50,
ncols=3,
vmax="p96",
)
/home/zeth/miniconda3/envs/ehrapy/lib/python3.10/site-packages/scanpy/plotting/_tools/scatterplots.py:163: MatplotlibDeprecationWarning: The get_cmap function was deprecated in Matplotlib 3.7 and will be removed two minor releases later. Use ``matplotlib.colormaps[name]`` or ``matplotlib.colormaps.get_cmap(obj)`` instead.
cmap = copy(get_cmap(cmap))
[22]:
drivers_4 = g.compute_lineage_drivers(lineages="4")
adata.obs["fate_probs_4"] = g.fate_probabilities["4"].X.flatten()
ep.pl.umap(
adata,
color=["fate_probs_4"] + list(drivers_4.index[:8]),
color_map="viridis",
s=50,
ncols=3,
vmax="p96",
)
/home/zeth/miniconda3/envs/ehrapy/lib/python3.10/site-packages/scanpy/plotting/_tools/scatterplots.py:163: MatplotlibDeprecationWarning: The get_cmap function was deprecated in Matplotlib 3.7 and will be removed two minor releases later. Use ``matplotlib.colormaps[name]`` or ``matplotlib.colormaps.get_cmap(obj)`` instead.
cmap = copy(get_cmap(cmap))
The lineage 2_1
seems to have a lot of patients that deceased in hospital, are of high age and had a high platelet measurement, while lineage 2_2
consists of patients that deceased in hospital, had a high first SAPS I and SOFA score and lineage 4
consists of patients with a high day after ICU release.
Determining feature trends#
Given fate probabilities and a pseudotime, we can plot trajectory-specific feature trends. Specifically, we fit Generalized Additive Models (GAMs), weighting each cells contribution to each trajectory according to its vector of fate probabilities. We start by initializing a model
.
[23]:
model = cr.models.GAM(adata)
With the model initialized, we can visualize feature dynamics along specific trajectories. Here, we have a closer look at a selection of features that were previously identified as lineage drivers.
[24]:
cr.pl.gene_trends(
adata,
model,
["sapsi_first", "sofa_first", "age", "weight_first",
"sodium_first", "chloride_first", "platelet_first", "wbc_first"],
time_key="dpt_pseudotime",
show_progress_bar=False,
same_plot=True,
ncols=2,
hide_cells=True,
figsize=(10,12)
)
Conclusion#
In this tutorial we applied CellRank and ehrapy to identify patient visit trajectories from selected root clusters, computed macrostates of clusters and pointed out features that are driving those trajectories. Following that, we visualized feature trends across the pseudotime for the patient trajectories. In particular, we inspected trajectories of patients originating from cluster 0, which was defined by less severe features, and identified 3 major trajectories. Two trajectories (2_1 and 2_2) were terminated in a bad outcome cluster and were driven by severity features such as age, death and comorbidities.
As a next tutorial, we suggest to have a closer look at our survival analysis, continue with that tutorials or go back to our tutorial overview page.
References#
Raffa, J. (2016). Clinical data from the MIMIC-II database for a case study on indwelling arterial catheters (version 1.0). PhysioNet. https://doi.org/10.13026/C2NC7F.
Raffa J.D., Ghassemi M., Naumann T., Feng M., Hsu D. (2016) Data Analysis. In: Secondary Analysis of Electronic Health Records. Springer, Cham
Goldberger, A., Amaral, L., Glass, L., Hausdorff, J., Ivanov, P. C., Mark, R., … & Stanley, H. E. (2000). PhysioBank, PhysioToolkit, and PhysioNet: Components of a new research resource for complex physiologic signals. Circulation [Online]. 101 (23), pp. e215–e220.
Marius Lange, Volker Bergen, Michal Klein, Manu Setty, Bernhard Reuter, Mostafa Bakhti, Heiko Lickert, Meshal Ansari, Janine Schniering, Herbert B. Schiller, Dana Pe’er, and Fabian J. Theis. Cellrank for directed single-cell fate mapping. Nat. Methods, 2022. doi:10.1038/s41592-021-01346-6.
Lars Velten, Simon F. Haas, Simon Raffel, Sandra Blaszkiewicz, Saiful Islam, Bianca P. Hennig, Christoph Hirche, Christoph Lutz, Eike C. Buss, Daniel Nowak, Tobias Boch, Wolf-Karsten Hofmann, Anthony D. Ho, Wolfgang Huber, Andreas Trumpp, Marieke A. G. Essers, and Lars M. Steinmetz. Human haematopoietic stem cell lineage commitment is a continuous process. Nature Cell Biology, 19(4):271–281, 2017. doi:10.1038/ncb3493.
Bergen, V., Lange, M., Peidli, S. et al. Generalizing RNA velocity to transient cell states through dynamical modeling. Nat Biotechnol 38, 1408–1414 (2020). https://doi.org/10.1038/s41587-020-0591-3
Haghverdi, L., Büttner, M., Wolf, F. et al. Diffusion pseudotime robustly reconstructs lineage branching. Nat Methods 13, 845–848 (2016). https://doi.org/10.1038/nmeth.3971
Package versions#
[25]:
%%capture --no-display
ep.print_versions()
----- ehrapy 0.6.0 rich NA session_info 1.0.0 ----- Levenshtein 0.21.1 PIL 10.0.0 absl NA aiofiles NA aiohttp 3.8.5 aiosignal 1.3.1 anndata 0.9.2 anyio NA argcomplete NA arrow 1.2.3 astor 0.8.1 asttokens NA async_timeout 4.0.2 attr 23.1.0 attrs 23.1.0 autograd NA autograd_gamma NA babel 2.12.1 backcall 0.2.0 backoff 2.2.1 blis NA bs4 4.12.2 cachetools 5.3.1 catalogue NA category_encoders 2.6.1 cellrank 1.5.2.dev242+ge0f46cd certifi 2023.07.22 cffi 1.15.1 charset_normalizer 3.2.0 chex 0.1.7 click 8.1.6 comm 0.1.3 confection NA contextlib2 NA croniter NA cryptography 41.0.1 cvxopt 1.3.1 cycler 0.10.0 cymem NA cython_runtime NA datasets 2.14.4 dateutil 2.8.2 db_dtypes 1.1.1 debugpy 1.6.7 decorator 5.1.1 deep_translator 1.9.1 deepdiff 6.3.1 deepl 1.15.0 defusedxml 0.7.1 dill 0.3.7 docrep 0.3.2 dot_parser NA dowhy 0.10 etils 1.3.0 executing 1.2.0 fastapi 0.100.0 fastjsonschema NA fhiry 3.0.0 filelock 3.12.2 flax 0.7.0 formulaic 0.6.4 fqdn NA frozenlist 1.4.0 fsspec 2023.6.0 future 0.18.3 gensim 4.3.1 google NA graphlib NA graphviz 0.20.1 grpc 1.56.2 grpc_status NA h5py 3.9.0 html5lib 1.1 huggingface_hub 0.16.4 idna 3.4 igraph 0.10.6 importlib_resources NA interface_meta 1.3.0 ipykernel 6.24.0 ipywidgets 8.1.0 isoduration NA jax 0.4.13 jaxlib 0.4.13 jedi 0.19.0 jinja2 3.0.3 joblib 1.3.1 json5 NA jsonpickle 3.0.1 jsonpointer 2.4 jsonschema 4.18.0 jsonschema_specifications NA jupyter_events 0.7.0 jupyter_server 2.7.0 jupyterlab_server 2.24.0 kiwisolver 1.4.4 langcodes NA leidenalg 0.10.1 lifelines 0.27.7 lightning 2.0.5 lightning_cloud NA lightning_utilities 0.9.0 llvmlite 0.40.1 markdown_it 2.2.0 markupsafe 2.1.3 matplotlib 3.7.2 matplotlib_inline 0.1.6 mdurl 0.1.2 medcat 1.9.0 missingno 0.5.2 ml_collections NA ml_dtypes 0.2.0 mpl_toolkits NA mpmath 1.3.0 msgpack 1.0.5 mudata 0.2.3 multidict 6.0.4 multipart 0.0.6 multipledispatch 0.6.0 multiprocess 0.70.15 murmurhash NA natsort 8.4.0 nbformat 5.9.1 networkx 3.1 numba 0.57.1 numpy 1.24.4 numpyro 0.12.1 nvfuser NA opt_einsum v3.3.0 optax 0.1.5 ordered_set 4.1.0 overrides NA packaging 23.1 pandas 2.0.3 parso 0.8.3 patsy 0.5.3 pexpect 4.8.0 pickleshare 0.7.5 pkg_resources NA platformdirs 3.10.0 preshed NA progressbar 4.2.0 prometheus_client NA prompt_toolkit 3.0.39 psutil 5.9.5 ptyprocess 0.7.0 pure_eval 0.2.2 pyarrow 12.0.1 pycparser 2.21 pydantic 1.10.12 pydev_ipython NA pydevconsole NA pydevd 2.9.5 pydevd_file_utils NA pydevd_plugins NA pydevd_tracing NA pydot 1.4.2 pygam 0.8.0 pygments 2.16.1 pygpcca 1.0.4 pynndescent 0.5.10 pyparsing 3.0.9 pyro 1.8.5 python_utils NA pythonjsonlogger NA pytz 2023.3 rapidfuzz 3.2.0 referencing NA regex 2.5.132 requests 2.31.0 rfc3339_validator 0.1.4 rfc3986_validator 0.1.1 rpds NA ruamel NA scanpy 1.9.3 scipy 1.11.1 scvelo 0.3.0 scvi 1.0.2 seaborn 0.12.2 send2trash NA setuptools 68.0.0 shellingham 1.5.0.post1 six 1.16.0 sklearn 1.1.3 smart_open 6.3.0 sniffio 1.3.0 soupsieve 2.4.1 spacy 3.6.1 sparse 0.14.0 sphinxcontrib NA srsly 2.4.7 stack_data 0.6.2 starlette 0.27.0 statsmodels 0.14.0 sympy 1.12 texttable 1.6.7 thefuzz 0.19.0 thinc 8.1.11 threadpoolctl 3.2.0 tokenizers 0.12.1 tomli 2.0.1 toolz 0.12.0 torch 2.0.1+cu117 torchmetrics 1.0.1 tornado 6.3.2 tqdm 4.65.0 traitlets 5.9.0 tree 0.1.8 typer 0.9.0 typing_extensions NA umap 0.5.3 uri_template NA urllib3 2.0.4 uvicorn 0.23.1 wasabi NA wcwidth 0.2.6 webcolors 1.13 webencodings 0.5.1 websocket 1.6.1 websockets 11.0.3 wrapt 1.15.0 xarray 2023.7.0 xxhash NA yaml 6.0.1 yarl 1.9.2 zmq 25.1.0 zoneinfo NA ----- IPython 8.14.0 jupyter_client 8.3.0 jupyter_core 5.3.1 jupyterlab 4.0.3 ----- Python 3.10.12 | packaged by conda-forge | (main, Jun 23 2023, 22:40:32) [GCC 12.3.0] Linux-6.4.8-arch1-1-x86_64-with-glibc2.38 ----- Session information updated at 2023-08-10 18:01