Predicting outcome of Morris water maze test in vascular dementia mouse model with deep learning.

Akinori Higaki,Masatsugu Horiuchi,Masayoshi Kukida,Masaki Mogi,Harumi Kan-No,Shuntaro Ikeda,Bao-Shuai Shan,Jun Iwanami,Jitsuo Higaki,Hui-Yu Bai,Li-Juan Min,Manabu Sakakibara

doi:10.1371/journal.pone.0191708

Akinori Higaki, Masatsugu Horiuchi + Show 10 more

Open Access

https://doi.org/10.1371/journal.pone.0191708

Copy DOI

Journal: PloS one	Publication Date: Feb 7, 2018
Citations: 19	License type: CC BY 4.0

Affiliation: Ehime University

Abstract

The Morris water maze test (MWM) is one of the most popular and established behavioral tests to evaluate rodents’ spatial learning ability. The conventional training period is around 5 days, but there is no clear evidence or guidelines about the appropriate duration. In many cases, the final outcome of the MWM seems predicable from previous data and their trend. So, we assumed that if we can predict the final result with high accuracy, the experimental period could be shortened and the burden on testers reduced. An artificial neural network (ANN) is a useful modeling method for datasets that enables us to obtain an accurate mathematical model. Therefore, we constructed an ANN system to estimate the final outcome in MWM from the previously obtained 4 days of data in both normal mice and vascular dementia model mice. Ten-week-old male C57B1/6 mice (wild type, WT) were subjected to bilateral common carotid artery stenosis (WT-BCAS) or sham-operation (WT-sham). At 6 weeks after surgery, we evaluated their cognitive function with MWM. Mean escape latency was significantly longer in WT-BCAS than in WT-sham. All data were collected and used as training data and test data for the ANN system. We defined a multiple layer perceptron (MLP) as a prediction model using an open source framework for deep learning, Chainer. After a certain number of updates, we compared the predicted values and actual measured values with test data. A significant correlation coefficient was derived form the updated ANN model in both WT-sham and WT-BCAS. Next, we analyzed the predictive capability of human testers with the same datasets. There was no significant difference in the prediction accuracy between human testers and ANN models in both WT-sham and WT-BCAS. In conclusion, deep learning method with ANN could predict the final outcome in MWM from 4 days of data with high predictive accuracy in a vascular dementia model.

Highlights

Dementia is becoming a serious health problem throughout the world, along with the aging of society
WT-bilateral common carotid artery stenosis (BCAS) mice showed significantly lower spatial learning ability compared to WT-sham from day 2 to day 5
Predictive accuracy of artificial neural network (ANN) system according to number of model updates

Summary

Introduction

Dementia is becoming a serious health problem throughout the world, along with the aging of society. Since the importance of dementia study increases, the use of experimental methods to evaluate cognitive function is increasing. Mice show floating and thigmotaxis more frequently than rats [2, 3] This test has some issues for testers. This method is a useful way to evaluate cognitive function, it requires a substantially longer experimental period. Considering the protocols used in recent studies, the standard training period in this test is about five days [4]. This period is not a fixed value and is left to the researcher’s discretion. We assumed that if the result on the final day can be estimated with high accuracy, it may be possible to shorten the experimental period and reduce physical and mental burden on testers

Methods

Results

Conclusion