Labyrinth is a human-inspired computational framework for personalized drug prioritization.
labyrinth
is a computational framework designed at drug prioritization at both the population and individual levels. It integrates multiple sources of prior medical knowledge, including:
- Clinical trial information.
- Co-occurrence networks from literature citations.
- Drug-target interactions.
- Drug-indication importance.
- Disease-drug distance.
labyrinth
emphasizes the importance of aligning computational models with intuitive human reasoning. Thus, it employs a human-like knowledge retrieval methodology to identify potential drug candidates for various diseases. labyrinth
aims to strike a balance between predictive accuracy and model interpretability, as demonstrated by its robust performance across diverse diseases, evaluated using ROC-AUC metrics.
I developed and tested labyrinth
on Fedora Linux version 38 and 39. While this package does not contain any operating system-specific code, it has not been tested on other operating systems. In theory, labyrinth
should work on other Unix-like operating systems as long as the required dependencies are installed.
We recommended these dependencies to be installed:
- R (≥ 4.3.0): We developed this R package using R version 4.3.x.
- Python: Python is required for drawing plots in demos. It is recommended to have Python and
seaborn
installed, as thereticulate
package will use the system's Python installation. - OpenMP: This package uses OpenMP for parallelization and multithreading if OpenMP exists. Having OpenMP installed can significantly improve performance.
- Intel oneAPI Math Kernel Library (oneMKL): This library can further enhance mathematical performance, especially on Intel processors. oneMKL is not required but highly recommended.
It would takes less than ten minutes to install this package. If you encounter any issues while running this package on other operating system, please open an issue.
Before installation, we recommended you install Intel oneAPI Math Kernel Library (oneMKL) to optimize the computational performance of linear algebra.
Windows users can download oneMKL from Intel's website and install it in the default directory. The default directory is: C:\Program Files (x86)\Intel\oneAPI
.
Debian and Ubuntu users can download oneMKL using apt in the non-free repo:
# Install oneMKL version 2020.4.304-4
sudo apt install intel-mkl-full
Or using the Intel repo:
# Set up the repository and signed the entry
wget -O- https://apt.repos.intel.com/intel-gpg-keys/GPG-PUB-KEY-INTEL-SW-PRODUCTS.PUB \
| gpg --dearmor | sudo tee /usr/share/keyrings/oneapi-archive-keyring.gpg > /dev/null
echo "deb [signed-by=/usr/share/keyrings/oneapi-archive-keyring.gpg] https://apt.repos.intel.com/oneapi all main" | sudo tee /etc/apt/sources.list.d/oneAPI.list
# Update the package list
sudo apt update
# Install the latest oneMKL (version 2024.1)
sudo apt install intel-oneapi-mkl
Fedora users can download oneMKL by using dnf:
# Create dnf repository file
tee > /tmp/oneAPI.repo << EOF
[oneAPI]
name=Intel® oneAPI repository
baseurl=https://yum.repos.intel.com/oneapi
enabled=1
gpgcheck=1
repo_gpgcheck=1
gpgkey=https://yum.repos.intel.com/intel-gpg-keys/GPG-PUB-KEY-INTEL-SW-PRODUCTS.PUB
EOF
sudo mv /tmp/oneAPI.repo /etc/yum.repos.d
# Install the latest oneMKL (version 2025.0)
sudo dnf install intel-oneapi-mkl intel-oneapi-mkl-devel intel-oneapi-mkl-core
Install labyrinth
using:
install.packages(c('devtools', 'BiocManager'))
remotes::install_github("randef1ned/labyrinth", upgrade = "always", build_vignettes = TRUE, build_manual = TRUE)
Or you can download the pre-built binary packages from Releases.
Load the package using library(labyrinth)
. We provide a vignette for the package that can be called using: vignette("labyrinth")
. Alternatively, you can view the online version on GitHub, or pkgdown
documentation. The examples I provided would take several minutes to run on a normal desktop computer. Basically that is all you have to know.
This documentation contains information about the contents and the necessary information for training the model used in this project. The tools/
folder contains all the code and scripts required for constructing your own model, so that you can understand the technical details. Besides, you can refer to this documentation for the background and inspirations behind the overall workflow of `labyrinth.
Changelog: see this