Comparative assessment of methods for short-term forecasts of COVID-19 hospital admissions in England at the local level

  1. Sophie Meakin
  2. Sam Abbott
  3. Nikos Bosse
  4. James Munday
  5. Hugo Gruson
  6. Joel Hellewell
  7. Katharine Sherratt
  8. CMMID COVID-19 Working Group
  9. Lloyd A. C. Chapman
  10. Kiesha Prem
  11. Petra Klepac
  12. Thibaut Jombart
  13. Gwenan M. Knight
  14. Yalda Jafari
  15. Stefan Flasche
  16. William Waites
  17. Mark Jit
  18. Rosalind M. Eggo
  19. C. Julian Villabona-Arenas
  20. Timothy W. Russell
  21. Graham Medley
  22. W. John Edmunds
  23. Nicholas G. Davies
  24. Yang Liu
  25. Stéphane Hué
  26. Oliver Brady
  27. Rachael Pung
  28. Kaja Abbas
  29. Amy Gimma
  30. Paul Mee
  31. Akira Endo
  32. Samuel Clifford
  33. Fiona Yueqian Sun
  34. Ciara V. McCarthy
  35. Billy J. Quilty
  36. Alicia Rosello
  37. Frank G. Sandmann
  38. Rosanna C. Barnard
  39. Adam J. Kucharski
  40. Simon R. Procter
  41. Christopher I. Jarvis
  42. Hamish P. Gibbs
  43. David Hodgson
  44. Rachel Lowe
  45. Katherine E. Atkins
  46. Mihaly Koltai
  47. Carl A. B. Pearson
  48. Emilie Finch
  49. Kerry L. M. Wong
  50. Matthew Quaife
  51. Kathleen O’Reilly
  52. Damien C. Tully
  53. Sebastian Funk

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Abstract

Background

Forecasting healthcare demand is essential in epidemic settings, both to inform situational awareness and facilitate resource planning. Ideally, forecasts should be robust across time and locations. During the COVID-19 pandemic in England, it is an ongoing concern that demand for hospital care for COVID-19 patients in England will exceed available resources.

Methods

We made weekly forecasts of daily COVID-19 hospital admissions for National Health Service (NHS) Trusts in England between August 2020 and April 2021 using three disease-agnostic forecasting models: a mean ensemble of autoregressive time series models, a linear regression model with 7-day-lagged local cases as a predictor, and a scaled convolution of local cases and a delay distribution. We compared their point and probabilistic accuracy to a mean-ensemble of them all and to a simple baseline model of no change from the last day of admissions. We measured predictive performance using the weighted interval score (WIS) and considered how this changed in different scenarios (the length of the predictive horizon, the date on which the forecast was made, and by location), as well as how much admissions forecasts improved when future cases were known.

Results

All models outperformed the baseline in the majority of scenarios. Forecasting accuracy varied by forecast date and location, depending on the trajectory of the outbreak, and all individual models had instances where they were the top- or bottom-ranked model. Forecasts produced by the mean-ensemble were both the most accurate and most consistently accurate forecasts amongst all the models considered. Forecasting accuracy was improved when using future observed, rather than forecast, cases, especially at longer forecast horizons.

Conclusions

Assuming no change in current admissions is rarely better than including at least a trend. Using confirmed COVID-19 cases as a predictor can improve admissions forecasts in some scenarios, but this is variable and depends on the ability to make consistently good case forecasts. However, ensemble forecasts can make forecasts that make consistently more accurate forecasts across time and locations. Given minimal requirements on data and computation, our admissions forecasting ensemble could be used to anticipate healthcare needs in future epidemic or pandemic settings.

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  1. Version published to 10.1186/s12916-022-02271-x
  2. Version published to 10.1101/2021.10.18.21265046v3 on medRxiv
  3. Version published to 10.1101/2021.10.18.21265046v2 on medRxiv
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    Please note, not all rigor criteria are appropriate for all manuscripts.

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    Software and Algorithms
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    In short, the complete-linkage algorithm initially assigns each Trust to its own cluster, then at each step combines the two most similar clusters (as determined by the pairwise correlation), until the desired number of clusters is reached [31]; this is implemented in the hclust algorithm in stats 4.1.1.
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    suggested: (HCLUST, RRID:SCR_009154)

    Results from OddPub: Thank you for sharing your code and data.

    Results from LimitationRecognizer: An explicit section about the limitations of the techniques employed in this study was not found. We encourage authors to address study limitations.

    Results from TrialIdentifier: No clinical trial numbers were referenced.

    Results from Barzooka: We did not find any issues relating to the usage of bar graphs.

    Results from JetFighter: We did not find any issues relating to colormaps.

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    Results from scite Reference Check: We found no unreliable references.

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  5. Version published to 10.1101/2021.10.18.21265046v1 on medRxiv