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1. Learning Deep Dissipative Dynamics

Author

Okamoto, Yuji and Kojima, Ryosuke

Subjects
Computer Science - Machine Learning, Electrical Engineering and Systems Science - Systems and Control, Mathematics - Dynamical Systems
Abstract

This study challenges strictly guaranteeing ``dissipativity'' of a dynamical system represented by neural networks learned from given time-series data. Dissipativity is a crucial indicator for dynamical systems that generalizes stability and input-output stability, known to be valid across various systems including robotics, biological systems, and molecular dynamics. By analytically proving the general solution to the nonlinear Kalman-Yakubovich-Popov (KYP) lemma, which is the necessary and sufficient condition for dissipativity, we propose a differentiable projection that transforms any dynamics represented by neural networks into dissipative ones and a learning method for the transformed dynamics. Utilizing the generality of dissipativity, our method strictly guarantee stability, input-output stability, and energy conservation of trained dynamical systems. Finally, we demonstrate the robustness of our method against out-of-domain input through applications to robotic arms and fluid dynamics. Code here https://github.com/kojima-r/DeepDissipativeModel

Published
2024

2. Out-of-distribution Reject Option Method for Dataset Shift Problem in Early Disease Onset Prediction

Author

Tosaki, Taisei, Uchino, Eiichiro, Kojima, Ryosuke, Mineharu, Yohei, Arita, Mikio, Miyai, Nobuyuki, Tamada, Yoshinori, Mikami, Tatsuya, Murashita, Koichi, Nakaji, Shigeyuki, and Okuno, Yasushi

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Statistics - Applications
Abstract

Machine learning is increasingly used to predict lifestyle-related disease onset using health and medical data. However, the prediction effectiveness is hindered by dataset shift, which involves discrepancies in data distribution between the training and testing datasets, misclassifying out-of-distribution (OOD) data. To diminish dataset shift effects, this paper proposes the out-of-distribution reject option for prediction (ODROP), which integrates OOD detection models to preclude OOD data from the prediction phase. We investigated the efficacy of five OOD detection methods (variational autoencoder, neural network ensemble std, neural network ensemble epistemic, neural network energy, and neural network gaussian mixture based energy measurement) across two datasets, the Hirosaki and Wakayama health checkup data, in the context of three disease onset prediction tasks: diabetes, dyslipidemia, and hypertension. To evaluate the ODROP method, we trained disease onset prediction models and OOD detection models on Hirosaki data and used AUROC-rejection curve plots from Wakayama data. The variational autoencoder method showed superior stability and magnitude of improvement in Area Under the Receiver Operating Curve (AUROC) in five cases: AUROC in the Wakayama data was improved from 0.80 to 0.90 at a 31.1% rejection rate for diabetes onset and from 0.70 to 0.76 at a 34% rejection rate for dyslipidemia. We categorized dataset shifts into two types using SHAP clustering - those that considerably affect predictions and those that do not. We expect that this classification will help standardize measuring instruments. This study is the first to apply OOD detection to actual health and medical data, demonstrating its potential to substantially improve the accuracy and reliability of disease prediction models amidst dataset shift.

Published
2024

3. ReactionT5: a large-scale pre-trained model towards application of limited reaction data

Author

Sagawa, Tatsuya and Kojima, Ryosuke

Subjects
Physics - Chemical Physics, Computer Science - Machine Learning
Abstract

Transformer-based deep neural networks have revolutionized the field of molecular-related prediction tasks by treating molecules as symbolic sequences. These models have been successfully applied in various organic chemical applications by pretraining them with extensive compound libraries and subsequently fine-tuning them with smaller in-house datasets for specific tasks. However, many conventional methods primarily focus on single molecules, with limited exploration of pretraining for reactions involving multiple molecules. In this paper, we propose ReactionT5, a novel model that leverages pretraining on the Open Reaction Database (ORD), a publicly available large-scale resource. We further fine-tune this model for yield prediction and product prediction tasks, demonstrating its impressive performance even with limited fine-tuning data compared to traditional models. The pre-trained ReactionT5 model is publicly accessible on the Hugging Face platform.

Published
2023

5. A New Deep State-Space Analysis Framework for Patient Latent State Estimation and Classification from EHR Time Series Data

Author

Nakamura, Aya, Kojima, Ryosuke, Okamoto, Yuji, Uchino, Eiichiro, Mineharu, Yohei, Harada, Yohei, Kamada, Mayumi, Muto, Manabu, Yanagita, Motoko, and Okuno, Yasushi

Subjects
Computer Science - Machine Learning, J.3, I.2.1
Abstract

Many diseases, including cancer and chronic conditions, require extended treatment periods and long-term strategies. Machine learning and AI research focusing on electronic health records (EHRs) have emerged to address this need. Effective treatment strategies involve more than capturing sequential changes in patient test values. It requires an explainable and clinically interpretable model by capturing the patient's internal state over time. In this study, we propose the "deep state-space analysis framework," using time-series unsupervised learning of EHRs with a deep state-space model. This framework enables learning, visualizing, and clustering of temporal changes in patient latent states related to disease progression. We evaluated our framework using time-series laboratory data from 12,695 cancer patients. By estimating latent states, we successfully discover latent states related to prognosis. By visualization and cluster analysis, the temporal transition of patient status and test items during state transitions characteristic of each anticancer drug were identified. Our framework surpasses existing methods in capturing interpretable latent space. It can be expected to enhance our comprehension of disease progression from EHRs, aiding treatment adjustments and prognostic determinations., Comment: 21 pages, 6 figures

Published
2023

6. An end-to-end framework for gene expression classification by integrating a background knowledge graph: application to cancer prognosis prediction

Author

Inoue, Kazuma, Kojima, Ryosuke, Kamada, Mayumi, and Okuno, Yasushi

Subjects
Quantitative Biology - Quantitative Methods, Computer Science - Machine Learning
Abstract

Biological data may be separated into primary data, such as gene expression, and secondary data, such as pathways and protein-protein interactions. Methods using secondary data to enhance the analysis of primary data are promising, because secondary data have background information that is not included in primary data. In this study, we proposed an end-to-end framework to integrally handle secondary data to construct a classification model for primary data. We applied this framework to cancer prognosis prediction using gene expression data and a biological network. Cross-validation results indicated that our model achieved higher accuracy compared with a deep neural network model without background biological network information. Experiments conducted in patient groups by cancer type showed improvement in ROC-area under the curve for many groups. Visualizations of high accuracy cancer types identified contributing genes and pathways by enrichment analysis. Known biomarkers and novel biomarker candidates were identified through these experiments., Comment: 19 pages including supplementary materials

Published
2023

8. GraphIX: Graph-based In silico XAI(explainable artificial intelligence) for drug repositioning from biopharmaceutical network

Author

Takagi, Atsuko, Kamada, Mayumi, Hamatani, Eri, Kojima, Ryosuke, and Okuno, Yasushi

Subjects
Computer Science - Machine Learning, Quantitative Biology - Quantitative Methods
Abstract

Drug repositioning holds great promise because it can reduce the time and cost of new drug development. While drug repositioning can omit various R&D processes, confirming pharmacological effects on biomolecules is essential for application to new diseases. Biomedical explainability in a drug repositioning model can support appropriate insights in subsequent in-depth studies. However, the validity of the XAI methodology is still under debate, and the effectiveness of XAI in drug repositioning prediction applications remains unclear. In this study, we propose GraphIX, an explainable drug repositioning framework using biological networks, and quantitatively evaluate its explainability. GraphIX first learns the network weights and node features using a graph neural network from known drug indication and knowledge graph that consists of three types of nodes (but not given node type information): disease, drug, and protein. Analysis of the post-learning features showed that node types that were not known to the model beforehand are distinguished through the learning process based on the graph structure. From the learned weights and features, GraphIX then predicts the disease-drug association and calculates the contribution values of the nodes located in the neighborhood of the predicted disease and drug. We hypothesized that the neighboring protein node to which the model gave a high contribution is important in understanding the actual pharmacological effects. Quantitative evaluation of the validity of protein nodes' contribution using a real-world database showed that the high contribution proteins shown by GraphIX are reasonable as a mechanism of drug action. GraphIX is a framework for evidence-based drug discovery that can present to users new disease-drug associations and identify the protein important for understanding its pharmacological effects from a large and complex knowledge base., Comment: add supplementary materials

Published
2022

9. Learning Deep Input-Output Stable Dynamics

Author

Okamoto, Yuji and Kojima, Ryosuke

Subjects
Mathematics - Dynamical Systems, Computer Science - Machine Learning, Computer Science - Robotics, Mathematics - Optimization and Control
Abstract

Learning stable dynamics from observed time-series data is an essential problem in robotics, physical modeling, and systems biology. Many of these dynamics are represented as an inputs-output system to communicate with the external environment. In this study, we focus on input-output stable systems, exhibiting robustness against unexpected stimuli and noise. We propose a method to learn nonlinear systems guaranteeing the input-output stability. Our proposed method utilizes the differentiable projection onto the space satisfying the Hamilton-Jacobi inequality to realize the input-output stability. The problem of finding this projection can be formulated as a quadratic constraint quadratic programming problem, and we derive the particular solution analytically. Also, we apply our method to a toy bistable model and the task of training a benchmark generated from a glucose-insulin simulator. The results show that the nonlinear system with neural networks by our method achieves the input-output stability, unlike naive neural networks. Our code is available at https://github.com/clinfo/DeepIOStability., Comment: NeurIPS 2022

Published
2022

10. Individual health-disease phase diagrams for disease prevention based on machine learning

Author

Nakamura, Kazuki, Uchino, Eiichiro, Sato, Noriaki, Araki, Ayano, Terayama, Kei, Kojima, Ryosuke, Murashita, Koichi, Itoh, Ken, Mikami, Tatsuya, Tamada, Yoshinori, and Okuno, Yasushi

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence
Abstract

Early disease detection and prevention methods based on effective interventions are gaining attention. Machine learning technology has enabled precise disease prediction by capturing individual differences in multivariate data. Progress in precision medicine has revealed that substantial heterogeneity exists in health data at the individual level and that complex health factors are involved in the development of chronic diseases. However, it remains a challenge to identify individual physiological state changes in cross-disease onset processes because of the complex relationships among multiple biomarkers. Here, we present the health-disease phase diagram (HDPD), which represents a personal health state by visualizing the boundary values of multiple biomarkers that fluctuate early in the disease progression process. In HDPDs, future onset predictions are represented by perturbing multiple biomarker values while accounting for dependencies among variables. We constructed HDPDs for 11 non-communicable diseases (NCDs) from a longitudinal health checkup cohort of 3,238 individuals, comprising 3,215 measurement items and genetic data. Improvement of biomarker values to the non-onset region in HDPD significantly prevented future disease onset in 7 out of 11 NCDs. Our results demonstrate that HDPDs can represent individual physiological states in the onset process and be used as intervention goals for disease prevention.

Published
2022

11. MatSat: a matrix-based differentiable SAT solver

Author

Sato, Taisuke and Kojima, Ryosuke

Subjects
Computer Science - Artificial Intelligence
Abstract

We propose a new approach to SAT solving which solves SAT problems in vector spaces as a cost minimization problem of a non-negative differentiable cost function J^sat. In our approach, a solution, i.e., satisfying assignment, for a SAT problem in n variables is represented by a binary vector u in {0,1}^n that makes J^sat(u) zero. We search for such u in a vector space R^n by cost minimization, i.e., starting from an initial u_0 and minimizing J to zero while iteratively updating u by Newton's method. We implemented our approach as a matrix-based differential SAT solver MatSat. Although existing main-stream SAT solvers decide each bit of a solution assignment one by one, be they of conflict driven clause learning (CDCL) type or of stochastic local search (SLS) type, MatSat fundamentally differs from them in that it continuously approach a solution in a vector space. We conducted an experiment to measure the scalability of MatSat with random 3-SAT problems in which MatSat could find a solution up to n=10^5 variables. We also compared MatSat with four state-of-the-art SAT solvers including winners of SAT competition 2018 and SAT Race 2019 in terms of time for finding a solution, using a random benchmark set from SAT 2018 competition and an artificial random 3-SAT instance set. The result shows that MatSat comes in second in both test sets and outperforms all the CDCL type solvers.

Published
2021

12. Complex network prediction using deep learning

Author

Tanaka, Yoshihisa, Kojima, Ryosuke, Ishida, Shoichi, Yamashita, Fumiyoshi, and Okuno, Yasushi

Subjects
Physics - Physics and Society, Computer Science - Social and Information Networks, Quantitative Biology - Molecular Networks
Abstract

Systematic relations between multiple objects that occur in various fields can be represented as networks. Real-world networks typically exhibit complex topologies whose structural properties are key factors in characterizing and further exploring the networks themselves. Uncertainty, modelling procedures and measurement difficulties raise often insurmountable challenges in fully characterizing most of the known real-world networks; hence, the necessity to predict their unknown elements from the limited data currently available in order to estimate possible future relations and/or to unveil unmeasurable relations. In this work, we propose a deep learning approach to this problem based on Graph Convolutional Networks for predicting networks while preserving their original structural properties. The study reveals that this method can preserve scale-free and small-world properties of complex networks when predicting their unknown parts, a feature lacked by the up-to-date conventional methods. An external validation realized by testing the approach on biological networks confirms the results, initially obtained on artificial data. Moreover, this process provides new insights into the retainability of network structure properties in network prediction. We anticipate that our work could inspire similar approaches in other research fields as well, where unknown mechanisms behind complex systems need to be revealed by combining machine-based and experiment-based methods., Comment: 20 pages, 16 figures

Published
2021

13. Health improvement framework for planning actionable treatment process using surrogate Bayesian model

Author

Nakamura, Kazuki, Kojima, Ryosuke, Uchino, Eiichiro, Murashita, Koichi, Itoh, Ken, Nakaji, Shigeyuki, and Okuno, Yasushi

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Statistics - Machine Learning
Abstract

Clinical decision making regarding treatments based on personal characteristics leads to effective health improvements. Machine learning (ML) has been the primary concern of diagnosis support according to comprehensive patient information. However, the remaining prominent issue is the development of objective treatment processes in clinical situations. This study proposes a novel framework to plan treatment processes in a data-driven manner. A key point of the framework is the evaluation of the "actionability" for personal health improvements by using a surrogate Bayesian model in addition to a high-performance nonlinear ML model. We first evaluated the framework from the viewpoint of its methodology using a synthetic dataset. Subsequently, the framework was applied to an actual health checkup dataset comprising data from 3,132 participants, to improve systolic blood pressure values at the individual level. We confirmed that the computed treatment processes are actionable and consistent with clinical knowledge for lowering blood pressure. These results demonstrate that our framework could contribute toward decision making in the medical field, providing clinicians with deeper insights.

Published
2020
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17. Batched Sparse Matrix Multiplication for Accelerating Graph Convolutional Networks

Author

Nagasaka, Yusuke, Nukada, Akira, Kojima, Ryosuke, and Matsuoka, Satoshi

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing
Abstract

Graph Convolutional Networks (GCNs) are recently getting much attention in bioinformatics and chemoinformatics as a state-of-the-art machine learning approach with high accuracy. GCNs process convolutional operations along with graph structures, and GPUs are used to process enormous operations including sparse-dense matrix multiplication (SpMM) when the graph structure is expressed as an adjacency matrix with sparse matrix format. However, the SpMM operation on small graph, where the number of nodes is tens or hundreds, hardly exploits high parallelism or compute power of GPU. Therefore, SpMM becomes a bottleneck of training and inference in GCNs applications. In order to improve the performance of GCNs applications, we propose new SpMM algorithm especially for small sparse matrix and Batched SpMM, which exploits high parallelism of GPU by processing multiple SpMM operations with single CUDA kernel. To the best of our knowledge, this is the first work of batched approach for SpMM. We evaluated the performance of the GCNs application on TSUBAME3.0 implementing NVIDIA Tesla P100 GPU, and our batched approach shows significant speedups of up to 1.59x and 1.37x in training and inference, respectively., Comment: 10 pages, 19th IEEE/ACM International Symposium on Cluster, Cloud and Grid Computing (CCGRID)

Published
2019

18. A tensorized logic programming language for large-scale data

Author

Kojima, Ryosuke and Sato, Taisuke

Subjects
Computer Science - Machine Learning, Computer Science - Logic in Computer Science
Abstract

We introduce a new logic programming language T-PRISM based on tensor embeddings. Our embedding scheme is a modification of the distribution semantics in PRISM, one of the state-of-the-art probabilistic logic programming languages, by replacing distribution functions with multidimensional arrays, i.e., tensors. T-PRISM consists of two parts: logic programming part and numerical computation part. The former provides flexible and interpretable modeling at the level of first order logic, and the latter part provides scalable computation utilizing parallelization and hardware acceleration with GPUs. Combing these two parts provides a remarkably wide range of high-level declarative modeling from symbolic reasoning to deep learning. To embody this programming language, we also introduce a new semantics, termed tensorized semantics, which combines the traditional least model semantics in logic programming with the embeddings of tensors. In T-PRISM, we first derive a set of equations related to tensors from a given program using logical inference, i.e., Prolog execution in a symbolic space and then solve the derived equations in a continuous space by TensorFlow. Using our preliminary implementation of T-PRISM, we have successfully dealt with a wide range of modeling. We have succeeded in dealing with real large-scale data in the declarative modeling. This paper presents a DistMult model for knowledge graphs using the FB15k and WN18 datasets., Comment: In AAAI-19 Workshop on Network Interpretability for Deep Learning

Published
2019

19. Pericentromeric noncoding RNA changes DNA binding of CTCF and inflammatory gene expression in senescence and cancer

Author

Miyata, Kenichi, Imai, Yoshinori, Satoshi Hori, Mika Nishio, Loo, Tze Mun, Okada, Ryo, Yang, Liying, Nakadai, Tomoyoshi, Maruyama, Reo, Fujii, Risa, Ueda, Koji, Jiang, Li, Zheng, Hao, Toyokuni, Shinya, Sakata, Toyonori, Shirahige, Katsuhiko, Kojima, Ryosuke, Nakayama, Mizuho, Oshima, Masanobu, Nagayama, Satoshi, Seimiya, Hiroyuki, Hirota, Toru, Saya, Hideyuki, Hara, Eiji, and Takahashi, Akiko

Published
2021

20. Computer-aided diagnosis of lung nodule using gradient tree boosting and Bayesian optimization

Author

Nishio, Mizuho, Nishizawa, Mitsuo, Sugiyama, Osamu, Kojima, Ryosuke, Yakami, Masahiro, Kuroda, Tomohiro, and Togashi, Kaori

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

We aimed to evaluate computer-aided diagnosis (CADx) system for lung nodule classification focusing on (i) usefulness of gradient tree boosting (XGBoost) and (ii) effectiveness of parameter optimization using Bayesian optimization (Tree Parzen Estimator, TPE) and random search. 99 lung nodules (62 lung cancers and 37 benign lung nodules) were included from public databases of CT images. A variant of local binary pattern was used for calculating feature vectors. Support vector machine (SVM) or XGBoost was trained using the feature vectors and their labels. TPE or random search was used for parameter optimization of SVM and XGBoost. Leave-one-out cross-validation was used for optimizing and evaluating the performance of our CADx system. Performance was evaluated using area under the curve (AUC) of receiver operating characteristic analysis. AUC was calculated 10 times, and its average was obtained. The best averaged AUC of SVM and XGBoost were 0.850 and 0.896, respectively; both were obtained using TPE. XGBoost was generally superior to SVM. Optimal parameters for achieving high AUC were obtained with fewer numbers of trials when using TPE, compared with random search. In conclusion, XGBoost was better than SVM for classifying lung nodules. TPE was more efficient than random search for parameter optimization., Comment: 29 pages, 4 figures

Published
2017
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31. Super-resolution vibrational imaging based on photoswitchable Raman probe

Author

Shou, Jingwen, primary, Komazawa, Ayumi, additional, Wachi, Yuusaku, additional, Kawatani, Minoru, additional, Fujioka, Hiroyoshi, additional, Spratt, Spencer John, additional, Mizuguchi, Takaha, additional, Oguchi, Kenichi, additional, Akaboshi, Hikaru, additional, Obata, Fumiaki, additional, Tachibana, Ryo, additional, Yasunaga, Shun, additional, Mita, Yoshio, additional, Misawa, Yoshihiro, additional, Kojima, Ryosuke, additional, Urano, Yasuteru, additional, Kamiya, Mako, additional, and Ozeki, Yasuyuki, additional

Published
2023
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32. Improving Compound–Protein Interaction Prediction by Self-Training with Augmenting Negative Samples

Author

00753906, 40613328, 70807651, Koyama, Takuto, Matsumoto, Shigeyuki, Iwata, Hiroaki, Kojima, Ryosuke, Okuno, Yasushi, 00753906, 40613328, 70807651, Koyama, Takuto, Matsumoto, Shigeyuki, Iwata, Hiroaki, Kojima, Ryosuke, and Okuno, Yasushi

Abstract

Identifying compound-protein interactions (CPIs) is crucial for drug discovery. Since experimentally validating CPIs is often time-consuming and costly, computational approaches are expected to facilitate the process. Rapid growths of available CPI databases have accelerated the development of many machine-learning methods for CPI predictions. However, their performance, particularly their generalizability against external data, often suffers from a data imbalance attributed to the lack of experimentally validated inactive (negative) samples. In this study, we developed a self-training method for augmenting both credible and informative negative samples to improve the performance of models impaired by data imbalances. The constructed model demonstrated higher performance than those constructed with other conventional methods for solving data imbalances, and the improvement was prominent for external datasets. Moreover, examination of the prediction score thresholds for pseudo-labeling during self-training revealed that augmenting the samples with ambiguous prediction scores is beneficial for constructing a model with high generalizability. The present study provides guidelines for improving CPI predictions on real-world data, thus facilitating drug discovery.

Published
2023

38. AI-Driven Synthetic Route Design Incorporated with Retrosynthesis Knowledge

Author

70807651, 10302168, Ishida, Shoichi, Terayama, Kei, Kojima, Ryosuke, Takasu, Kiyosei, Okuno, Yasushi, 70807651, 10302168, Ishida, Shoichi, Terayama, Kei, Kojima, Ryosuke, Takasu, Kiyosei, and Okuno, Yasushi

Abstract

Computer-aided synthesis planning (CASP) aims to assist chemists in performing retrosynthetic analysis for which they utilize their experiments, intuition, and knowledge. Recent breakthroughs in machine learning (ML) techniques, including deep neural networks, have significantly improved data-driven synthetic route designs without human intervention. However, learning chemical knowledge by ML for practical synthesis planning has not yet been adequately achieved and remains a challenging problem. In this study, we developed a data-driven CASP application integrated with various portions of retrosynthesis knowledge called “ReTReK” that introduces the knowledge as adjustable parameters into the evaluation of promising search directions. The experimental results showed that ReTReK successfully searched synthetic routes based on the specified retrosynthesis knowledge, indicating that the synthetic routes searched with the knowledge were preferred to those without the knowledge. The concept of integrating retrosynthesis knowledge as adjustable parameters into a data-driven CASP application is expected to enhance the performance of both existing data-driven CASP applications and those under development.

Published
2022

40. Predictive Diagnostic Approach to Dementia and Dementia Subtypes Using Wireless and Mobile Electroencephalography: A Pilot Study

Author

Li, Fangzhou, primary, Matsumori, Shoya, additional, Egawa, Naohiro, additional, Yoshimoto, Shusuke, additional, Yamashiro, Kotaro, additional, Mizutani, Haruo, additional, Uchida, Noriko, additional, Kokuryu, Atsuko, additional, Kuzuya, Akira, additional, Kojima, Ryosuke, additional, Hayashi, Yu, additional, and Takahashi, Ryosuke, additional

Published
2022
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41. Development of a fluorescent probe library enabling efficient screening of tumour-imaging probes based on discovery of biomarker enzymatic activities

Author

Kuriki, Yugo, primary, Yoshioka, Takafusa, additional, Kamiya, Mako, additional, Komatsu, Toru, additional, Takamaru, Hiroyuki, additional, Fujita, Kyohhei, additional, Iwaki, Hirohisa, additional, Nanjo, Aika, additional, Akagi, Yuki, additional, Takeshita, Kohei, additional, Hino, Haruaki, additional, Hino, Rumi, additional, Kojima, Ryosuke, additional, Ueno, Tasuku, additional, Hanaoka, Kenjiro, additional, Abe, Seiichiro, additional, Saito, Yutaka, additional, Nakajima, Jun, additional, and Urano, Yasuteru, additional

Published
2022
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42. Health improvement framework for actionable treatment planning using a surrogate Bayesian model

Author

70807651, 70378769, 20283666, Nakamura, Kazuki, Kojima, Ryosuke, Uchino, Eiichiro, Ono, Koh, Yanagita, Motoko, Murashita, Koichi, Itoh, Ken, Nakaji, Shigeyuki, Okuno, Yasushi, 70807651, 70378769, 20283666, Nakamura, Kazuki, Kojima, Ryosuke, Uchino, Eiichiro, Ono, Koh, Yanagita, Motoko, Murashita, Koichi, Itoh, Ken, Nakaji, Shigeyuki, and Okuno, Yasushi

Abstract

Clinical decision-making regarding treatments based on personal characteristics leads to effective health improvements. Machine learning (ML) has been the primary concern of diagnosis support according to comprehensive patient information. A prominent issue is the development of objective treatment processes in clinical situations. This study proposes a framework to plan treatment processes in a data-driven manner. A key point of the framework is the evaluation of the actionability for personal health improvements by using a surrogate Bayesian model in addition to a high-performance nonlinear ML model. We first evaluate the framework from the viewpoint of its methodology using a synthetic dataset. Subsequently, the framework is applied to an actual health checkup dataset comprising data from 3132 participants, to lower systolic blood pressure and risk of chronic kidney disease at the individual level. We confirm that the computed treatment processes are actionable and consistent with clinical knowledge for improving these values. We also show that the improvement processes presented by the framework can be clinically informative. These results demonstrate that our framework can contribute toward decision-making in the medical field, providing clinicians with deeper insights.

Published
2021

43. Evaluation of Kidney Histological Images Using Unsupervised Deep Learning

Author

70807651, 00335283, 10252462, 90378779, 70378769, Sato, Noriaki, Uchino, Eiichiro, Kojima, Ryosuke, Sakuragi, Minoru, Hiragi, Shusuke, Minamiguchi, Sachiko, Haga, Hironori, Yokoi, Hideki, Yanagita, Motoko, Okuno, Yasushi, 70807651, 00335283, 10252462, 90378779, 70378769, Sato, Noriaki, Uchino, Eiichiro, Kojima, Ryosuke, Sakuragi, Minoru, Hiragi, Shusuke, Minamiguchi, Sachiko, Haga, Hironori, Yokoi, Hideki, Yanagita, Motoko, and Okuno, Yasushi

Abstract

[Introduction] Evaluating histopathology via machine learning has gained research and clinical interest, and the performance of supervised learning tasks has been described in various areas of medicine. Unsupervised learning of histological images has the advantage of reproducibility for labeling; however, the relationship between unsupervised evaluation and clinical information remains unclear in nephrology. [Methods] We propose an unsupervised approach combining convolutional neural networks (CNNs) and a visualization algorithm to cluster the histological images and calculate the score for patients. We applied the approach to the entire images or patched images of the glomerulus of kidney biopsy samples stained with hematoxylin and eosin obtained from 68 patients with immunoglobulin A nephropathy. We assessed the relationship between the obtained scores and clinical variables of urinary occult blood, urinary protein, serum creatinine (SCr), systolic blood pressure, and age. [Results] The glomeruli of the patients were classified into 12 distinct classes and 10 patches. The output of the fine-tuned CNN, which we defined as the histological scores, had significant relationships with assessed clinical variables. In addition, the clustering and visualization results suggested that the defined clusters captured important findings when evaluating renal histopathology. For the score of the patch-based cluster containing crescentic glomeruli, SCr (coefficient = 0.09, P = 0.019) had a significant relationship. [Conclusion] The proposed approach could successfully extract features that were related to the clinical variables from the kidney biopsy images along with the visualization for interpretability. The approach could aid in the quantified evaluation of renal histopathology.

Published
2021

44. Prediction and visualization of acute kidney injury in intensive care unit using one-dimensional convolutional neural networks based on routinely collected data

Author

70807651, 70378769, 20283666, Sato, Noriaki, Uchino, Eiichiro, Kojima, Ryosuke, Hiragi, Shusuke, Yanagita, Motoko, Okuno, Yasushi, 70807651, 70378769, 20283666, Sato, Noriaki, Uchino, Eiichiro, Kojima, Ryosuke, Hiragi, Shusuke, Yanagita, Motoko, and Okuno, Yasushi

Abstract

Background: Acute kidney injury (AKI) occurs frequently in in-hospital patients, especially in the intensive care unit (ICU), due to various etiologies including septic shock. It is clinically important to identify high-risk patients at an early stage and perform the appropriate intervention. Methods: We proposed a system to predict AKI using one-dimensional convolutional neural networks (1D-CNN) with the real-time calculation of the probability of developing AKI, along with the visualization of the rationale behind prediction using score-weighted class activation mapping and guided backpropagation. The system was applied to predicting developing AKI based on the KDIGO guideline in time windows of 24 to 48 h using data of 0 to 24 h after admission to ICU. Results: The comparison result of multiple algorithms modeling time series data indicated that the proposed 1D-CNN model achieved higher performance compared to the other models, with the mean area under the receiver operating characteristic curve of 0.742 ± 0.010 for predicting stage 1, and 0.844 ± 0.029 for stage 2 AKI using the input of the vital signs, the demographic information, and serum creatinine values. The visualization results suggested the reasonable interpretation that time points with higher respiratory rate, lower blood pressure, as well as lower SpO2, had higher attention in terms of predicting AKI, and thus important for prediction. Conclusions: We presumed the proposed system's potential usefulness as it could be applied and transferred to almost any ICU setting that stored the time series data corresponding to vital signs.

Published
2021

45. kGCN: a graph-based deep learning framework for chemical structures

Author

70807651, 40613328, 20283666, Kojima, Ryosuke, Ishida, Shoichi, Ohta, Masateru, Iwata, Hiroaki, Honma, Teruki, Okuno, Yasushi, 70807651, 40613328, 20283666, Kojima, Ryosuke, Ishida, Shoichi, Ohta, Masateru, Iwata, Hiroaki, Honma, Teruki, and Okuno, Yasushi

Abstract

Deep learning is developing as an important technology to perform various tasks in cheminformatics. In particular, graph convolutional neural networks (GCNs) have been reported to perform well in many types of prediction tasks related to molecules. Although GCN exhibits considerable potential in various applications, appropriate utilization of this resource for obtaining reasonable and reliable prediction results requires thorough understanding of GCN and programming. To leverage the power of GCN to benefit various users from chemists to cheminformaticians, an open-source GCN tool, kGCN, is introduced. To support the users with various levels of programming skills, kGCN includes three interfaces: a graphical user interface (GUI) employing KNIME for users with limited programming skills such as chemists, as well as command-line and Python library interfaces for users with advanced programming skills such as cheminformaticians. To support the three steps required for building a prediction model, i.e., pre-processing, model tuning, and interpretation of results, kGCN includes functions of typical pre-processing, Bayesian optimization for automatic model tuning, and visualization of the atomic contribution to prediction for interpretation of results. kGCN supports three types of approaches, single-task, multi-task, and multi-modal predictions. The prediction of compound-protein interaction for four matrixmetalloproteases, MMP-3, -9, -12 and -13, in the inhibition assays is performed as a representative case study using kGCN. Additionally, kGCN provides the visualization of atomic contributions to the prediction. Such visualization is useful for the validation of the prediction models and the design of molecules based on the prediction model, realizing “explainable AI” for understanding the factors affecting AI prediction. kGCN is available at https://github.com/clinfo.

Published
2020

46. Prediction of blood pressure variability using deep neural networks

Author

70807651, 20283666, Koshimizu, Hiroshi, Kojima, Ryosuke, Kario, Kazuomi, Okuno, Yasushi, 70807651, 20283666, Koshimizu, Hiroshi, Kojima, Ryosuke, Kario, Kazuomi, and Okuno, Yasushi

Abstract

[Purpose]The purpose of our study was to predict blood pressure variability from time-series data of blood pressure measured at home and data obtained through medical examination at a hospital. Previous studies have reported the blood pressure variability is a significant independent risk factor for cardiovascular disease. [Methods]We adopted standard deviation for a certain period and predicted variabilities and mean values of blood pressure for 4 weeks using multi-input multi-output deep neural networks. In designing the prediction model, we prepared a dataset from a clinical study. The dataset included past time-series data for blood pressure and medical examination data such as gender, age, and others. As evaluation metrics, we used the standard deviation ratio (SR) and the root-mean-square error (RMSE). Moreover, we used cross-validation as the evaluation method. [Results]The prediction performances of blood pressure variability and mean value after 1–4 weeks showed the SRs were “0.67” to “0.70”, the RMSEs were “5.04” to “6.65” mmHg, respectively. Additionally, our models were able to work for a participant with high variability in blood pressure values due to its multi-output nature. [Conclusion]The results of this study show that our models can predict blood pressure over 4 weeks. Our models work for an individual with high variability of blood pressure. Therefore, we consider that our prediction models are valuable for blood pressure management., Kojima, Ryosuke, Kario, Kazuomi, Okuno, Yasushi

Published
2020

47. Alkylated alkali lignin for compatibilizing agents of carbon fiber reinforced plastics with polypropylene

Author

Sakai, Hiroki, Kuroda, Kosuke, Muroyama, Shiori, Tsukegi, Takayuki, Kakuchi, Ryohei, Takada, Kenji, Hata, Ayano, Kojima, Ryosuke, Ogoshi, Tomoki, Omichi, Masaaki, Ninomiya, Kazuaki, and Takahashi, Kenji

Subjects
Interfacial shear strength, Compatibilizing agent, Microbond test, Polypropylene, Carbon fiber reinforced plastic, Lignin
Abstract

金沢大学ナノマテリアル研究所 / 金沢大学理工研究域生命理工学系, As an alternative to petroleum-based compatibilizing agents, we developed lignin derivatives for compatibilizing agents of carbon fiber-reinforced plastics that have thermoplasticity. In this study, alkyl chains were introduced into alkali lignin at various ratios to optimize the compatibility of the lignin derivatives with both polypropylene and carbon fiber. The interfacial shear strength between the two materials was improved from 8.2 to 17.2 MPa by mixing with the optimized lignin derivative. The value is comparable to that achieved with a typical petroleum-based compatibilizing agent (18.3 MPa)., Embargo Period 6 months, This paper has supplementary information.

Published
2018

49. The relationship between cigarette smoking and the tongue microbiome in an East Asian population

Author

Sato, Noriaki, primary, Kakuta, Masanori, additional, Uchino, Eiichiro, additional, Hasegawa, Takanori, additional, Kojima, Ryosuke, additional, Kobayashi, Wataru, additional, Sawada, Kaori, additional, Tamura, Yoshihiro, additional, Tokuda, Itoyo, additional, Imoto, Seiya, additional, Nakaji, Shigeyuki, additional, Murashita, Koichi, additional, Yanagita, Motoko, additional, and Okuno, Yasushi, additional

Published
2020
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