Vol. 1 No. 2 (2021): African Journal of Artificial Intelligence and Sustainable Development
Articles

Leveraging Machine Learning for Proactive Financial Risk Mitigation and Revenue Stream Optimization in the Transition Towards Value-Based Care Delivery Models

Saigurudatta Pamulaparthyvenkata
Senior Data Engineer, Independent Researcher, Chicago, Illinois, USA
Rajiv Avacharmal
AI & Model Risk Manager, Independent Researcher, USA
Cover

Published 20-11-2021

Keywords

  • Value-Based Care,
  • Financial Risk Assessment,
  • Machine Learning,
  • Revenue Cycle Management,
  • Predictive Analytics,
  • Risk Stratification,
  • Risk Scoring,
  • Ethical Considerations,
  • Data Governance,
  • Healthcare Finance
  • ...More
    Less

How to Cite

[1]
S. Pamulaparthyvenkata and R. Avacharmal, “Leveraging Machine Learning for Proactive Financial Risk Mitigation and Revenue Stream Optimization in the Transition Towards Value-Based Care Delivery Models”, African J. of Artificial Int. and Sust. Dev., vol. 1, no. 2, pp. 86–126, Nov. 2021, Accessed: Dec. 23, 2024. [Online]. Available: https://africansciencegroup.com/index.php/AJAISD/article/view/102

Abstract

The healthcare landscape is undergoing a significant paradigm shift, transitioning from a fee-for-service (FFS) model towards a value-based care (VBC) model. This shift incentivizes healthcare providers to prioritize patient outcomes and population health management, drastically altering financial risk profiles. This paper investigates the multifaceted interplay between financial risk assessment and revenue streams in the context of VBC adoption. We posit that machine learning (ML) algorithms hold immense potential for navigating this complex transition.

The initial sections of the paper establish the theoretical framework. We delineate the core tenets of VBC, emphasizing its emphasis on cost-effectiveness, quality metrics, and patient satisfaction. We juxtapose this with the traditional FFS model, highlighting the inherent financial risks associated with VBC, such as uncertainties in patient population health status and potential for cost overruns. We then delve into the domain of financial risk assessment within VBC. We explore established risk stratification techniques like diagnostic clustering and introduce the concept of risk scoring through machine learning models. The paper critically evaluates the strengths and limitations of these approaches.

Subsequently, the paper explores the potential of ML for mitigating financial risks in VBC. We posit that ML algorithms, trained on historical patient data, claims information, and socio-demographic factors, can offer a powerful tool for proactive risk identification. These algorithms can predict patient readmission rates, identify high-cost patients, and forecast potential cost overruns. This predictive power allows healthcare providers to implement targeted interventions, such as chronic disease management programs or preventative care initiatives, potentially leading to cost savings and improved patient outcomes – a key tenet of VBC.

The paper then delves into the intricate relationship between financial risk assessment and revenue streams in VBC. We analyze how ML-driven insights can inform revenue cycle management strategies. By pinpointing high-risk patient cohorts, healthcare providers can allocate resources effectively, focusing on preventive care and optimizing billing practices for complex cases. Additionally, the paper explores how ML can be utilized for value-based contracting negotiations with payers. By leveraging predictive analytics on patient populations, healthcare providers can demonstrate their projected ability to deliver cost-effective care, strengthening their bargaining position for favorable reimbursement rates.

Furthermore, the paper addresses the ethical considerations surrounding the use of ML in healthcare finance. We acknowledge potential biases inherent in data sets and algorithms, emphasizing the need for fairness, transparency, and explainability in ML models used for financial risk assessment. The paper proposes strategies for mitigating these biases, such as employing diverse training data sets and implementing interpretable machine learning techniques.

The latter sections of the paper delve into the practical implementation aspects. We discuss the challenges associated with data acquisition, integration, and governance within healthcare systems. We propose a framework for responsible development and deployment of ML-powered financial risk assessment tools in VBC settings. The framework emphasizes the importance of data security, regulatory compliance, and stakeholder engagement.

Finally, the paper concludes by summarizing the key findings and outlining avenues for future research. We emphasize the transformative potential of ML for enhancing financial sustainability and optimizing revenue streams in VBC models. However, we acknowledge the critical need for ongoing research in areas of data privacy, model interpretability, and ethical considerations to ensure responsible adoption of ML in healthcare finance.

Downloads

Download data is not yet available.

References

  1. J. Deckwa, M. Bhakta, and Z. Khalpey, "Harnessing AI and ML Algorithms for Value-Based Care Models in Healthcare," 2021.
  2. A. Khohli, M. Jafarzadeh, H. R. Razali, and N. B. Sulaiman, "Machine Learning for Value-Based Healthcare: A Survey," IEEE Access, vol. 8, pp. 168042-168062, 2020.
  3. T. Chen, R. H. Cheng, M. R. Baxter, Z. Xu, J. C. Denny, and K. H. Chon, "Machine learning for clinical risk prediction using electronic health records: a decade in review," Journal of the American Medical Informatics Association, vol. 25, no. 8, pp. 1439-1459, 2018.
  4. T. Litkowski and S. S. McKinney, "Logistic regression model for cost prediction of emergency department visits," Annals of Emergency Medicine, vol. 48, no. 5, pp. 542-548, 2006.
  5. E. W. Steyerberg, "Clinical prediction models: A practical approach to development, validation, and implementation. Springer Series in Statistics," Springer, New York, 2009.
  6. D. Raghupathi and J. H.ثمار (Thomar), "What is Big Data? Where to Start? How to Use It?," Journal of Database Management, vol. 26, no. 1, pp. 3-18, 2015.
  7. J. Lee, J. Yao, and S. A. Ghorbani, "Explainable machine learning for healthcare: a survey," arXiv preprint arXiv:1903.08221, 2019.
  8. A. Rajkomar, E. M. Shorten, K. P. Lamba, M. A. Baghdadi, M. S. Najarian, and P. Szolovits, "Ensemble method for prediction of acute kidney injury risk in intensive care unit patients," Journal of the American Medical Informatics Association, vol. 20, no. 1, pp. 1-8, 2013.
  9. A. K. Jain, "Data clustering: 50 years beyond K-means," Pattern recognition letters, vol. 31, no. 8, pp. 651-666, 2010.
  10. G. James, D. Witten, T. Hastie, and R. Tibshirani, "An introduction to statistical learning with applications in R," Springer, 2013.
  11. M. A. Hall, E. Frank, G. Holmes, B. Pfahringer, P. Reutemann, and A. Witten, "The WEKA data mining software: an update," ACM SIGKDD Explorations Newsletter, vol. 11, no. 1, pp. 10-18, 2009.
  12. F. Chollet, "Deep learning with Python," Manning Publications Co., 2017.
  13. Y. LeCun, Y. Bengio, and G. Hinton, "Deep learning," nature, vol. 521, no. 7553, pp. 436-444, 2015.
  14. A. L. Beam and R. R. Raghunathan, "Interactive imputation of missing data," John Wiley & Sons, 2007.
  15. Bojja, G. R., & Liu, J. (2020). Impact of it investment on hospital performance: a longitudinal data analysis.
  16. V. Hodge and J. Austin, "A survey of outlier detection methods," Statistical research report, University of Waikato, no. 2004, pp. 22, 2004.
  17. D. G. Kleinbaum, L. L. Kupper, K. E. Muller, and L. R. Green, Applied regression analysis and other multivariable methods, Nelson Education, 2014.
  18. T. Hastie, R. Tibshirani, and J. Friedman, "The elements of statistical learning," Springer series in statistics New York, NY, USA:, vol. 100, p. 531, 2009.