Scientific Reports (Apr 2024)

Identifying acute illness phenotypes via deep temporal interpolation and clustering network on physiologic signatures

  • Yuanfang Ren,
  • Yanjun Li,
  • Tyler J. Loftus,
  • Jeremy Balch,
  • Kenneth L. Abbott,
  • Matthew M. Ruppert,
  • Ziyuan Guan,
  • Benjamin Shickel,
  • Parisa Rashidi,
  • Tezcan Ozrazgat-Baslanti,
  • Azra Bihorac

DOI
https://doi.org/10.1038/s41598-024-59047-x
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 15

Abstract

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Abstract Using clustering analysis for early vital signs, unique patient phenotypes with distinct pathophysiological signatures and clinical outcomes may be revealed and support early clinical decision-making. Phenotyping using early vital signs has proven challenging, as vital signs are typically sampled sporadically. We proposed a novel, deep temporal interpolation and clustering network to simultaneously extract latent representations from irregularly sampled vital signs and derive phenotypes. Four distinct clusters were identified. Phenotype A (18%) had the greatest prevalence of comorbid disease with increased prevalence of prolonged respiratory insufficiency, acute kidney injury, sepsis, and long-term (3-year) mortality. Phenotypes B (33%) and C (31%) had a diffuse pattern of mild organ dysfunction. Phenotype B’s favorable short-term clinical outcomes were tempered by the second highest rate of long-term mortality. Phenotype C had favorable clinical outcomes. Phenotype D (17%) exhibited early and persistent hypotension, high incidence of early surgery, and substantial biomarker incidence of inflammation. Despite early and severe illness, phenotype D had the second lowest long-term mortality. After comparing the sequential organ failure assessment scores, the clustering results did not simply provide a recapitulation of previous acuity assessments. This tool may impact triage decisions and have significant implications for clinical decision-support under time constraints and uncertainty.