Graph Neural Networks for Molecular Machine Learning

Navigation

Verified details

These details have been verified by PyPI
Maintainers
Avatar for akensert from gravatar.com akensert

Unverified details

These details have not been verified by PyPI
Project links
Meta
  • License: MIT License (MIT License)
  • Author: Alexander Kensert
  • Tags python , machine-learning , deep-learning , graph-neural-networks , molecular-machine-learning , molecular-graphs , computational-chemistry , computational-biology
  • Requires: Python >=3.10
  • Provides-Extra: gpu
Classifiers
Report project as malware

Project description

molcraft-logo

Deep Learning on Molecules: Graph Neural Networks for Molecular Machine Learning.

Examples

Context-Aware Graph Neural Network

Implement a context-aware graph neural network by embedding context features in the super node. The super node is a virtual node bidirectionally linked to all atomic nodes, allowing both efficient information propagation and inclusion of context features. Context features may be continuous or discrete (categorical); for discrete context features, specify the number of categories expected via num_categories of the AddContext layer.

from molcraft import features
from molcraft import featurizers 
from molcraft import layers
from molcraft import models

import keras
import pandas as pd

featurizer = featurizers.MolGraphFeaturizer(
    atom_features=[
        features.AtomType(),
        features.NumHydrogens(),
        features.Degree(),
    ],
    bond_features=[
        features.BondType(),
        features.IsRotatable(),
    ],
    super_node=True,
    self_loops=True,
)

df = pd.DataFrame({
    'smiles': [
        'N[C@@H](C)C(=O)O', 'N[C@@H](CS)C(=O)O' 
    ],
    'label': [3.5, -1.5],
    'ph': [7.2, 4.5],
    'temperature': [35., 45.],
})

graph = featurizer(df)

model = models.GraphModel.from_layers(
    [
        layers.Input(graph.spec),
        layers.NodeEmbedding(dim=128),
        layers.EdgeEmbedding(dim=128),
        layers.AddContext(field='ph'),
        layers.AddContext(field='temperature'),
        layers.GraphConv(units=128),
        layers.GraphConv(units=128),
        layers.GraphConv(units=128),
        layers.GraphConv(units=128),
        layers.Readout(mode='mean'),
        keras.layers.Dense(units=1024, activation='elu'),
        keras.layers.Dense(units=1024, activation='elu'),
        keras.layers.Dense(1)
    ]
)

model.compile(
    keras.optimizers.Adam(1e-4), keras.losses.MeanSquaredError()
)
model.fit(graph, epochs=30)
pred = model.predict(graph)

# Uncomment below to save and load model (including featurizer)
# featurizers.save_featurizer(featurizer, '/tmp/featurizer.json')
# models.save_model(model, '/tmp/model.keras')

# loaded_featurizer = featurizers.load_featurizer('/tmp/featurizer.json')
# loaded_model = models.load_model('/tmp/model.keras')

Hybrid Model for Peptides

Implement a GNN-RNN hybrid model for peptides.

from molcraft import features
from molcraft import featurizers 
from molcraft import layers
from molcraft import models

import keras
import pandas as pd

featurizer = featurizers.PeptideGraphFeaturizer(
    atom_features=[
        features.AtomType(),
        features.NumHydrogens(),
        features.Degree(),
    ],
    bond_features=[
        features.BondType(),
        features.IsRotatable(),
    ],
)

# Allow modified amino acids:
# featurizer.monomers.update({
#     "C[Carbamidomethyl]": "N[C@@H](CSCC(=O)N)C(=O)O"
# })

df = pd.DataFrame({
    'sequence': [
        'CYIQNCPLG', 'KTTKS' 
    ],
    'label': [1.0, 0.0],
})

graph = featurizer(df)

model = models.GraphModel.from_layers(
    [
        layers.Input(graph.spec),
        layers.NodeEmbedding(dim=128),
        layers.EdgeEmbedding(dim=128),
        layers.GraphConv(units=128),
        layers.GraphConv(units=128),
        layers.GraphConv(units=128),
        layers.GraphConv(units=128),
        layers.PeptideReadout(),
        keras.layers.Masking(),
        keras.layers.Bidirectional(
            keras.layers.LSTM(units=128, return_sequences=True)
        ),
        keras.layers.GlobalAveragePooling1D(),
        keras.layers.Dense(units=1024, activation='elu'),
        keras.layers.Dense(units=1024, activation='elu'),
        keras.layers.Dense(1, activation='sigmoid')
    ]
)

model.compile(
    keras.optimizers.Adam(1e-4), keras.losses.BinaryCrossentropy()
)
model.fit(graph, epochs=30)
pred = model.predict(graph)

# Uncomment below to save and load model (including featurizer)
# featurizers.save_featurizer(featurizer, '/tmp/featurizer.json')
# models.save_model(model, '/tmp/model.keras')

# loaded_featurizer = featurizers.load_featurizer('/tmp/featurizer.json')
# loaded_model = models.load_model('/tmp/model.keras')

Installation

For CPU users:

pip install molcraft

For GPU users:

pip install molcraft[gpu]

Project details

Verified details

These details have been verified by PyPI
Maintainers
Avatar for akensert from gravatar.com akensert

Unverified details

These details have not been verified by PyPI
Project links
Meta
  • License: MIT License (MIT License)
  • Author: Alexander Kensert
  • Tags python , machine-learning , deep-learning , graph-neural-networks , molecular-machine-learning , molecular-graphs , computational-chemistry , computational-biology
  • Requires: Python >=3.10
  • Provides-Extra: gpu
Classifiers

Release history Release notifications | RSS feed

0.10.0

0.9.0

0.8.0

0.7.0

0.6.2

0.6.1

0.5.5

0.5.4

0.5.3

0.5.2

0.5.1

This version

0.5.0

0.4.3

0.4.2

0.4.1

0.4.0

0.3.5

0.3.4

0.3.3

0.3.2

0.3.1

0.3.0

0.2.3

0.2.2

0.2.1

0.2.0

0.1.1

0.1.0

0.1.0rc11 pre-release

0.1.0rc10 pre-release

0.1.0rc9 pre-release

0.1.0rc8 pre-release

0.1.0rc7 pre-release

0.1.0rc6 pre-release

0.1.0rc5 pre-release

0.1.0rc4 pre-release

0.1.0rc3 pre-release

0.1.0rc2 pre-release

0.1.0rc1 pre-release

Download files

Download the file for your platform. If you're not sure which to choose, learn more about installing packages.

Source Distribution

molcraft-0.5.0.tar.gz (55.4 kB view details)

Uploaded Source

Built Distribution

If you're not sure about the file name format, learn more about wheel file names.

molcraft-0.5.0-py3-none-any.whl (54.7 kB view details)

Uploaded Python 3

File details

Details for the file molcraft-0.5.0.tar.gz.

File metadata

  • Download URL: molcraft-0.5.0.tar.gz
  • Upload date:
  • Size: 55.4 kB
  • Tags: Source
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/6.1.0 CPython/3.12.3

File hashes

Hashes for molcraft-0.5.0.tar.gz
Algorithm Hash digest
SHA256 09c6f5d52c1e7d953b7902bf7bc232ca0b6c22c69e13eae33a013ab86aa7ccf2
MD5 c5930eac7d7cf0de1753f9a6eabdb8a5
BLAKE2b-256 f7b4ed63a5d21f33f8e96b25865b5d623e93fe50ec4817ae9ff51f6a75307ac3

See more details on using hashes here.

File details

Details for the file molcraft-0.5.0-py3-none-any.whl.

File metadata

  • Download URL: molcraft-0.5.0-py3-none-any.whl
  • Upload date:
  • Size: 54.7 kB
  • Tags: Python 3
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/6.1.0 CPython/3.12.3

File hashes

Hashes for molcraft-0.5.0-py3-none-any.whl
Algorithm Hash digest
SHA256 9a721280accedd2810657d2a5a4f4b27cf31e9ca9c5b855bc05abaca03e59ca1
MD5 5a999cb3728a243d843f2a9844550feb
BLAKE2b-256 413e6d99de6fc5a2e6d3e55c319cea35f88cb0924932939036d253cd35c70196

See more details on using hashes here.

Supported by

AWS Cloud computing and Security Sponsor Datadog Monitoring Depot Continuous Integration Fastly CDN Google Download Analytics Pingdom Monitoring Sentry Error logging StatusPage Status page