AI Article Synopsis
- Interpreting machine learning model predictions is critical, especially in fields like medicine where errors can have serious consequences; this has spurred interest in creating models that are both powerful and interpretable.
- A new neural network called MonoNet is introduced, designed to maintain performance while being more transparent by ensuring monotonic relationships between features and outputs.
- MonoNet has been tested on various datasets, including biological data, demonstrating effective classification while offering insights into important biomarkers, and its code is available for public use.
Article Abstract
Motivation: Being able to interpret and explain the predictions made by a machine learning model is of fundamental importance. Unfortunately, a trade-off between accuracy and interpretability is often observed. As a result, the interest in developing more transparent yet powerful models has grown considerably over the past few years. Interpretable models are especially needed in high-stake scenarios, such as computational biology and medical informatics, where erroneous or biased models' predictions can have deleterious consequences for a patient. Furthermore, understanding the inner workings of a model can help increase the trust in the model.
Results: We introduce a novel structurally constrained neural network, , which is more transparent, while still retaining the same learning capabilities of traditional neural models. MonoNet contains connected layers that ensure monotonic relationships between (high-level) features and outputs. We show how, by leveraging the monotonic constraint in conjunction with other strategies, we can interpret our model. To demonstrate our model's capabilities, we train MonoNet to classify cellular populations in a single-cell proteomic dataset. We also demonstrate MonoNet's performance in other benchmark datasets in different domains, including non-biological applications (in the Supplementary Material). Our experiments show how our model can achieve good performance, while providing at the same time useful biological insights about the most important biomarkers. We finally carry out an information-theoretical analysis to show how the monotonic constraint actively contributes to the learning process of the model.
Availability And Implementation: Code and sample data are available at https://github.com/phineasng/mononet.
Supplementary Information: Supplementary data are available at online.
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Source |
|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10152389 | PMC |
| http://dx.doi.org/10.1093/bioadv/vbad016 | DOI Listing |
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