2024 · Bioinformatics · Oxford University Press · added 2026-04-21
Motivation: Drug–target interaction (DTI) prediction is a relevant but challenging task in the drug repurposing field. In-silico approaches have drawn particular attention as they can reduce associate Show more
Motivation: Drug–target interaction (DTI) prediction is a relevant but challenging task in the drug repurposing field. In-silico approaches have drawn particular attention as they can reduce associated costs and time commitment of traditional methodologies. Yet, current state-of-the-art methods present several limitations: existing DTI prediction approaches are computationally expensive, thereby hindering the ability to use large networks and exploit available datasets and, the generalization to unseen datasets of DTI prediction methods remains unexplored, which could Show less
Screening new drug-target interactions (DTIs) by traditional experimental methods is costly and time-consuming. Recent advances in knowledge graphs, chemical linear notations, and genomic data enable Show more
Screening new drug-target interactions (DTIs) by traditional experimental methods is costly and time-consuming. Recent advances in knowledge graphs, chemical linear notations, and genomic data enable researchers to develop computational-based-DTI models, which play a pivotal role in drug repurposing and discovery. However, there still needs to develop a multimodal fusion DTI model that integrates available heterogeneous data into a unified framework. Show less
2023 · Bioinformatics · Oxford University Press · added 2026-04-21
Motivation: Screening new drug–target interactions (DTIs) by traditional experimental methods is costly and time-consuming. Recent advances in knowledge graphs, chemical linear notations, and genomic Show more
Motivation: Screening new drug–target interactions (DTIs) by traditional experimental methods is costly and time-consuming. Recent advances in knowledge graphs, chemical linear notations, and genomic data enable researchers to develop computational-based-DTI models, which play a pivotal role in drug repurposing and discovery. However, there still needs to develop a multimodal fusion DTI model that integrates available heterogeneous data into a unified framework. Results: We developed MDTips, a multimodal-data-based DTI prediction system, by fusing the knowledge graphs, gene expression profiles, and Show less
Drug discovery (DD) is a time-consuming and expensive process. Thus, the industry
employs strategies such as drug repositioning and drug repurposing, which allows the application of
already approved d Show more
Drug discovery (DD) is a time-consuming and expensive process. Thus, the industry
employs strategies such as drug repositioning and drug repurposing, which allows the application of
already approved drugs to treat a different disease, as occurred in the first months of 2020, during the
COVID-19 pandemic. The prediction of drug–target interactions is an essential part of the DD process
because it can accelerate it and reduce the required costs. DTI prediction performed in silico have used
approaches based on molecular docking simulations, including similarity-based and network- and
graph-based ones. This paper presents MPS2IT-DTI, a DTI prediction model obtained from research
conducted in the following steps: the definition of a new method for encoding molecule and protein
sequences onto images; the definition of a deep-learning approach based on a convolutional neural
network in order to create a new method for DTI prediction. Training results conducted with the
Davis and KIBA datasets show that MPS2IT-DTI is viable compared to other state-of-the-art (SOTA)
approaches in terms of performance and complexity of the neural network model. With the Davis
dataset, we obtained 0.876 for the concordance index and 0.276 for the MSE; with the KIBA dataset,
we obtained 0.836 and 0.226 for the concordance index and the MSE, respectively. Moreover, the
MPS2IT-DTI model represents molecule and protein sequences as images, instead of treating them as
an NLP task, and as such, does not employ an embedding layer, which is present in other models.
Academic Editors: Kyriakos
Kachrimanis, David Barlow, Jakub Show less
Identifying drug-target interactions is an important task in drug discovery. To reduce heavy time and financial cost in experimental way, many computational approaches have been proposed. Although the Show more
Identifying drug-target interactions is an important task in drug discovery. To reduce heavy time and financial cost in experimental way, many computational approaches have been proposed. Although these approaches have used many different principles, their performance is far from satisfactory, especially in predicting drug-target interactions of new candidate drugs or targets. Show less