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Wireless Personal Communications

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10-03-2023

Forecasting Future Monthly Patient Volume using Deep Learning and Statistical Models

Authors: Zeydin Pala, Ramazan Atıcı, Erkan Yaldız

Published in: Wireless Personal Communications | Issue 2/2023

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Abstract

The variety of diseases is increasing day by day, and the demand for hospitals, especially for emergency and radiology units, is also increasing. As in other units, it is necessary to prepare the radiology unit for the future, to take into account the needs and to plan for the future. Due to the radiation emitted by the devices in the radiology unit, minimizing the time spent by the patients for the radiological image is of vital importance both for the unit staff and the patient. In order to solve the aforementioned problem, in this study, it is desired to estimate the monthly number of images in the radiology unit by using deep learning models and statistical-based models, and thus to be prepared for the future in a more planned way. For prediction processes, both deep learning models such as LSTM, MLP, NNAR and ELM, as well as statistical based prediction models such as ARIMA, SES, TBATS, HOLT and THETAF were used. In order to evaluate the performance of the models, the symmetric mean absolute percentage error (sMAPE) and mean absolute scaled error (MASE) metrics, which have been in demand recently, were preferred. The results showed that the LSTM model outperformed the deep learning group in estimating the monthly number of radiological case images, while the AUTO.ARIMA model performed better in the statistical-based group. It is believed that the findings obtained will speed up the procedures of the patients who come to the hospital and are referred to the radiology unit, and will facilitate the hospital managers in managing the patient flow more efficiently, increasing both the service quality and patient satisfaction, and making important contributions to the future planning of the hospital.

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Assimakopoulos, V., & Nikolopoulos, K. (2000). The theta model: A decomposition approach to forecasting. International Journal of Forecasting, 16(4), 521–530.CrossRef

Atici, R., & Pala, Z. (2021). “Prediction of the ionospheric foF2 parameter using R language forecasthybrid model library convenient time. Wireless Personal Communications, 122(4), 1–20. https://doi.org/10.1007/s11277-021-09050-6CrossRef

J. A. Doornik., J. L. Castle., & Hendry D. F. (2020). Short-term forecasting of the coronavirus pandemic. International. Journal of Forecasting.

Gode, A. P., Tiwaskar, S., Lakhar, B. N., & Dhande, R. (2022). Artificial intelligence in the field of radiology. A Review Article, 13(8), 97–104.

Golmohammadi, D. (2016). Predicting hospital admissions to reduce emergency department boarding. International Journal of Production Economics, 182, 535–544.CrossRef

Harrou, F., Dairi, A., Kadri, F., & Sun, Y. (2020). Forecasting emergency department overcrowding: A deep learning framework. Chaos, Solitons and Fractals, 139, 110247.CrossRef

Harrou, F., Dairi, A., Kadri, F., & Sun, Y. (2022). Effective forecasting of key features in hospital emergency department: Hybrid deep learning-driven methods”. Machine Learning with Applications, 7, 100200.CrossRef

Hochreiter, S., & Schmidhuber, J. (1997). Long Short-Term Memory. Neural Computation, 9(8), 1735–1780.CrossRef

Holzinger, A. (2016). Machine learning for health informatics state-of-the-art and future challenges. Springer International Publishing.CrossRef

10.

Hyndman, R. J., Athanasopoulos G. (2018). Forecasting : Principles and Practice. In (2nd ed.). Monash University

11.

Hyndman, R. J., & Koehler, A. B. (2006). Another look at measures of forecast accuracy. International Journal of Forecasting, 22(4), 679–688.CrossRef

12.

Hyndman, R. J., Koehler, A. B., Snyder, R. D., & Grose, S. (2002). A state space framework for automatic forecasting using exponential smoothing methods. International Journal of Forecasting, 18(3), 439–454.CrossRef

13.

Jilani, T., Housley, G., Figueredo, G., Tang, P. S., Hatton, J., & Shaw, D. (2019). Short and Long term predictions of Hospital emergency department attendances. International Journal of Medical Informatics, 129, 167–174.CrossRef

14.

Jones, S. S., et al. (2009). A multivariate time series approach to modeling and forecasting demand in the emergency department. Journal of Biomedical Informatics, 42(1), 123–139.CrossRef

15.

Jones, S. S., Thomas, A., Evans, R. S., Welch, S. J., Haug, P. J., & Snow, G. L. (2019). Forecasting daily patient volumes in the emergency department. Academic Emergency Medicine, 15(2), 159–170.CrossRef

16.

Jones, S. S., Thomas, A., Evans, R. S., Welch, S. J., Haug, P. J., & Snow, G. L. (2008). Forecasting daily patient volumes in the emergency department. Academic Emergency Medicine, 15(2), 159–170.CrossRef

17.

Kim, S., & Kim, H. (2016). A new metric of absolute percentage error for intermittent demand forecasts. International Journal of Forecasting, 32(3), 669–679.CrossRef

18.

Koehler, A. B., Snyder, R. D., & Ord, J. K. (2001). Forecasting models and prediction intervals for the multiplicative Holt-Winters method. International Journal of Forecasting, 17(2), 269–286.CrossRef

19.

Kulkarni, S., Seneviratne, N., Baig, M. S., & Khan, A. H. A. (2020). Artificial intelligence in medicine: Where are we now? Academic Radiology, 27(1), 62–70.CrossRef

20.

Lecun, Y., Bengio, Y., & Hinton, G. (2015). Deep learning. Nature, 521(7553), 436–444.CrossRef

21.

Luo, L., Luo, L., Zhang, X., & He, X. (2017). Hospital daily outpatient visits forecasting using a combinatorial model based on ARIMA and SES models. BMC Health Services Research, 17(1), 1–13.CrossRef

22.

Makridakis, S., Spiliotis, E., & Assimakopoulos, V. (2020). The M4 Competition: 100,000 time series and 61 forecasting methods. International Journal of Forecasting, 36(1), 54–74.CrossRef

23.

Maleki, M., Mahmoudi, M. R., Heydari, M. H., & Pho, K. H. (2020). Modeling and forecasting the spread and death rate of coronavirus (COVID-19) in the world using time series models. Chaos, Solitons and Fractals, 140, 110151.MathSciNetMATHCrossRef

24.

Moghadas, S. M., Shoukat, A. S., Fitzpatrick, M. C., Wells, C. R., Sah, P. S., Pandey, A., Sanchs, J. D., Galvani, A. P., & Zheng Wang, L. A. (2020). Projecting hospital utilization during the COVID-19 outbreaks in the United States. Proceedings of the National Academy of Sciences, 117(16), 9122–9126.CrossRef

25.

Nuti, S., & Vainieri, M. (2012). Managing waiting times in diagnostic medical imaging. British Medical Journal Open, 2, 1255.

26.

Pala, Z. (2021). Examining EMF time series using prediction algorithms with R. IEEE Canadian Journal of Electrical and Computer Engineering, 44(2), 223–227.CrossRef

27.

Pala, Z. (2023). “Comparative study on monthly natural gas vehicle fuel consumption and industrial consumption using multi-hybrid forecast models. Energy, 263, 1–21.CrossRef

28.

Pala, Z., & Atici, R. (2019). Forecasting sunspot time series using deep learning methods. Solar Physics, 294(5), 50.CrossRef

29.

Pala, Z., & Özkan, O. (2020). Artificial Intelligence Helps Protect Smart Homes against Thieves. Dicle Üniversitesi Mühendislik Fakültesi Mühendislik Dergisi, 11(3), 945–952.

30.

Pala, Z., & Pala, A. F. (2020). Perform time-series predictions in the r development environment by combining statistical-based models with a decomposition-based approach. J. Muş Alparslan University Fac. Eng. Archit., 1(1), 1–13.

31.

Pala, Z., & Pala, A. F. (2021). Comparison of ongoing COVID-19 pandemic confirmed cases/deaths weekly forecasts on continental basis using R statistical models. Dicle University Journal Engineering, 4, 635–644.

32.

Pala, Z., & Şana, M. (2020). Attackdet: Combining web data parsing and real-time analysis with machine learning. Journal of Advances inTechnology and Engineering, 6(1), 37–45.

33.

Pala, Z., Ünlük, İH., & Yaldız, E. (2019). Forecasting of electromagnetic radiation time series: An empirical comparative approach. Applied Computational Electromagnetics Society Journal, 34(8), 1238–1241.

34.

Poyiadji, N., Klochko, C., LaForce, J., Brown, M. L., & Griffith, B. (2021). COVID-19 and radiology resident imaging volumes-differential impact by resident training year and imaging modality. Academic Radiology, 28(1), 106–111.CrossRef

35.

Rob, J. (2008). Hyndman and yeasmin khandakar, “automatic time series forecasting: The forecast package for R.” Journal of Statistical Software, 27(3), 22.

36.

Savin, L. V., & Wang, S. (2006). Managing Patient Service in a Diagnostic Medical Facility. Diagnostic Medical Facility Operations Research, 54(1), 11–25.MATH

37.

Shahid, K., Manzoor, T., Ibrahim, M., Ahmed, T., & Fiaz, M. (2016). Forecasting of monthly patient volume at radiology department coming for ultrasound: A time series approach. Journal of University Medical Dental Colleage JUMDC, 7(3), 22–27.

38.

S. Siami-Namini, N. Tavakoli, & A. Siami Namin (2019). A Comparison of ARIMA and LSTM in Forecasting Time Series. In: Proceedings-17th IEEE International Conference Machine Learning Applications. ICMLA 2018 (pp. 1394–1401).

39.

Srivastava, N., Hinton, G., Krizhevsky, A., Sutskever, I., & Salakhutdinov, R. (2014). Dropout: A simple way to prevent neural networks from overfitting. Journal of Machine Learning Research, 15, 1929–1958.MathSciNetMATH

40.

Sun, Y., Heng, B. H., Seow, Y. T., & Seow, E. (2009). “Forecasting daily attendances at an emergency department to aid resource planning. BMC Emergency Medicine, 9, 1–9.CrossRef

41.

Tavares Thomé, A. M., Cyrino Oliveira, F. L., & Carvalho Ferrer, A. L. (2018). Time series analysis with explanatory variables: A systematic literature review”. Environmental Modelling and Software, 107, 199–209.CrossRef

42.

van Assen, M., Muscogiuri, G., Caruso, D., Lee, S. J., Laghi, A., & De Cecco, C. N. (2020). Artificial intelligence in cardiac radiology. La Radiologia Medica, 1, 3.

43.

Van Lent, W. A. M., Deetman, J. W., Teertstra, H. J., Muller, S. H., Hans, E. W., & Van Harten, W. H. (2012). Reducing the throughput time of the diagnostic track involving CT scanning with computer simulation. European Journal of Radiology, 81(11), 3131–3140.CrossRef

44.

Wanluk, N., Pintavirooj, C., & Treebupachatsakul, T. (2019). Image Processing for X-ray calibration phantom. BMEiCON 2018–11th Biomedical Engineering International Conference, 2, 14–17.

45.

Xu, Q., Tsui, K. L., Jiang, W., & Guo, H. (2016). A Hybrid Approach for Forecasting Patient Visits in Emergency Department. Quality and Reliability Engineering International, 32(8), 2751–2759.CrossRef

46.

Yang, Y., Dong, J., Sun, X., Lima, E., Mu, Q., & Wang, X. (2018). A CFCC-LSTM Model for Sea Surface Temperature Prediction. IEEE Geoscience and Remote Sensing Letters, 15(2), 207–211.CrossRef

47.

Zhang, Y., et al. (2020). Emergency patient flow forecasting in the radiology department. Health Informatics Journal, 26(4), 2362–2374.CrossRef

48.

Zhu, T., Luo, L., Zhang, X., Shi, Y., & Shen, W. (2017). Time-Series Approaches for Forecasting the Number of Hospital Daily Discharged Inpatients. IEEE Journal Biomedical Health Informatics, 21(2), 515–526.CrossRef

Title: Forecasting Future Monthly Patient Volume using Deep Learning and Statistical Models
Authors: Zeydin Pala
Ramazan Atıcı
Erkan Yaldız
Publication date: 10-03-2023
Publisher: Springer US
Published in: Wireless Personal Communications / Issue 2/2023
Print ISSN: 0929-6212
Electronic ISSN: 1572-834X
DOI: https://doi.org/10.1007/s11277-023-10341-3

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