Research ArticleOriginal Article
Open Access

Effect of cortisol and glycosylated-hemoglobin levels on mortality in intensive care unit

Oznur Sen, Ugur Uzun, Nurdan Aydin and Isil Guldogan
Saudi Medical Journal May 2024, 45 (5) 476-480; DOI: https://doi.org/10.15537/smj.2024.45.5.20240076

Abstract

Objectives: To research the effects of blood cortisol and hemoglobinA1c (HBA1C) levels on mortality in patients admitted to the intensive care unit (ICU) and whether these factors could be used as reliable indicators for mortality risk assessment in these patients.

Methods: After receiving approval from the ethics committee, 79 patients admitted to ICU were included in the study. From patient files, we collected data on demographics (age, gender), presence of diabetes mellitus, and levels of cortisol, HbA1C, glucose, and lactate measured during hospitalization, along with acute physiology and chronic health evaluation (APACHE) II scores calculated within the first 24 hours. In our study, we planned to investigate the relationship between patients’ cortisol and HbA1C levels and mortality.

Results: A total of 79 patients were included in the study. The mortality rate of the patients included in the study was 65.8%. In the model established with all variables, only cortisol level (p=0.017) and APACHE II score (p=0.005) were defined to affect mortality.

Conclusion: Cortisol levels at the time of admission to the ICU were found to affect mortality and can be considered a predictive factor, while HBA1C levels showed no such effect. Our findings indicate that neither cortisol nor HBA1C levels had an impact on the duration of mechanical ventilation or length of stay in the ICU.

Keywords:

Cortisol is secreted from the adrenal cortex under the influence of adrenocorticotropic hormone (ACTH) diurnally or in response to stress. It increases the risk of hyperglycemia by stimulating gluconeogenesis in the liver, reducing glucose uptake in adipose tissue and skeletal muscles, suppressing insulin secretion, and causing insulin resistance and inflammation.1 Effective control of hyperglycemia directly reduce mortality and morbidity.2 Many studies have examined the effect of cortisol levels and blood sugar regulation on intensive care mortality and morbidity in patients followed up in the intensive care unit (ICU).3,4 However, studies examining the effects of blood cortisol levels before admission to the ICU and glycosylated hemoglobin (HBA1C) levels, which reflect blood sugar regulation over the last 2-3 months, on morbidity and mortality in the ICU are scarce.

This study aim to research how HBA1C and cortisol levels affect the mortality of patients admitted to the ICU and their potential as predictors of mortality.

Methods

A total of 79 adult patients, 42 women and 37 men, who were admitted to ICU between January 2022 and February 2023 were included in our study. We excluded patients under the age of 18, those admitted for postoperative care, and steroid users from the study, as these factors could distort HBA1C and cortisol levels. We recorded demographic information (age and gender) and the presence of diabetes from patient files. Patients whose cortisol, HBA1C, glucose, and lactate levels were checked within the first hour of admission to the ICU and whose APACHE II scores were calculated within the first 24 hours were included in the study. We conducted high liquid chromatography using a Bio-Rad Variant II (Bio-Rad Laboratories, Hercules, CA, USA) device to measure HBA1C levels, and cortisol levels were assessed with a DxI immunoanalyzer (Beckman Coulter Inc., CA, USA). HBA1C levels were expressed as percentages (%), and cortisol levels were given in g/dl.

The primary endpoint of the study was the patient’s mortality in the ICU, and the secondary endpoint measure was the number of days spent on mechanical ventilation and in the ICU. The APACHE II score, computed in the first 24 hours for the included patients, was used as an indicator of disease severity.

To identify prior research related to the impact of cortisol and glycosylated-hemoglobin levels on mortality in ICU settings, Several electronic databases, including Web of Science, Scopus, and PubMed were used for a comprehensive literature search. The search plan used a combination of keywords and MeSH terms tailored to capture the broadest spectrum of relevant studies. These terms included “cortisol,” “glycosylated hemoglobin,” “HbA1c,” “mortality,” “intensive care unit,” and “critical care” among others, both singly and in various combinations. Both observational and interventional studies were considered for inclusion. Ethics committee approval numbered 216/2023 was received from Health Sciences University Haseki Training and Research Hospital. This is retrospective cross-sectional clinical trial. The study was conducted in accordance with the tenets of the Declaration of Helsinki.

Statistical analysis

Normality control of numerical variables in the study was checked with the Kolmogorov-Smirnov test. As descriptive statistics, since the distribution of data for numerical variables was not normal, frequency (n) and percentage (%) were given for median (minimum-maximum) categorical variables. To determine whether there was a significant difference between patient mortality and discharge, the Mann-Whitney U test was used. Binary logistic regression analysis was used to examine the factors affecting mortality of the patient, and odds ratio and confidence intervals were given. Linear regression analysis was performed to examine the factors affecting the number of days spent in mechanical ventilator and ICU. The probability of type 1 error was taken as 0.05 in all analyses. The Statistical Package for the Social Sciences for Windows Version 22 (IBM Corp., Armonk, N.Y., USA) program was used in all analyses.

Results

A total of 79 patients were included in the study (Table 1). Of these, 29 patients were previously diagnosed with diabetes. The number of patients discharged from the ICU was 27, and that of patients who died was 52. Blood samples revealed a median HBA1C of 5.7% (4.30-11.60) and a median cortisol level of 20.49 (0.88-62.20) g/dl for all patients, while for the deceased patients, the mean HBA1C was 5.8 (4.80-11.50) and the mean cortisol level was 26.69 g/dl (7.98-62.20) (Table 2).

View this table:
Table 1

- Demographic data of the patients included in the study

View this table:
Table 2

- Laboratory data according to mortality status.

The mortality rate of the patients was 65.8%. In the model incorporating all variables, only the cortisol level (p=0.017) and APACHE II score (p=0.005) were defined as affecting mortality. It was seen that a one point increase in the APACHE II score enhanced the mortality risk 1.17 times (1.048-1.308), and a 1 g/dl increase in cortisol level increased mortality 1.08 times (1.014-1.147). HBA1C levels had no effect on mortality (p=0.166) (Table 3).

View this table:
Table 3

- Effect of variables on mortality.

Using logistic regression analysis, we tested the impact of diabetes on mortality in 29 patients and found no significant effect of HBA1C on mortality in these patients (p=0.729). Additionally, diabetes did not significantly affect mortality in this group (p=0.156). To determine the effect of all variables (cortisol, HBA1C, APACHE II score, entry blood glucose level, lactate, age, and gender) on time spent on mechanical ventilation and ICU stay, a comprehensive model was established, which did not yield statistically significant results (p=0.090 for the number of days spent on mechanical ventilation and p=0.081 for the number of days spent in the ICU). In other words, none of the variables were found to affect the duration of stay on mechanical ventilation or in the ICU. The variables in the model explained 20.4% of the variation in mechanical ventilation days and 20.7% of the ICU duration.

Discussion

Sepsis, trauma, burns, and any other acute illness are perceived as stress because they threaten the body’s normal homeostatic processes.5 As a protective response to stress, the adrenal cortex secretes cortisol in amounts up to 20 times higher than usual.6 It has been argued that cortisol levels rise in correlation with the severity of acute stress. It has also been reported that cortisol values are higher in patients with lung insufficiency and sepsis than in those with gastrointestinal bleeding.7 Furthermore, diseases that prompt rapid admission to the ICU may lead to high cortisol values, which could independently predict patient outcomes.8-10 De Castro et al8 shown that basal cortisol levels, measured upon admission of patients with septic shock and severe sepsis to the ICU, are the best prognostic factor for 28-day mortality. Consistent with many other studies, our research shows that mortality is associated with increased cortisol levels in patients admitted to the ICU, indicating that these levels could serve as predictive markers for high mortality.8,11,12

Increased cortisol due to stress stimulates hepatic gluconeogenesis and glycogenolysis. In addition, gluconeogenesis is enhanced by amino acids released from non-carbohydrate sources, such as lactate, resulting from increased protein catabolism.13 As a result, temporary stress-induced hyperglycemia occurs as an adaptive immune–neurohormonal response to stress.14,15 Hyperglycemia affects all major components of immunity and impairs the host’s ability to fight infection, especially in hyperglycemic conditions.16 It is well known that high blood glucose levels are associated with poor outcomes in both diabetics and non-diabetics, and is a biomarker of critical illness in patients admitted to the ICU.17-20 Farooq et al19 shown that hyperglycemia diagnosed during hospitalization is indicative of poor clinical outcomes and is associated with high mortality and morbidity. We found that the glucose value measured during admission to the ICU did not affect mortality. We hypothesize that this might be attributed to the low median glucose blood level at hospitalization (143 mg/dl).

Glycosylated hemoglobin (HBA1C) is the most common marker of long-term glycoregulation, reflecting glucose levels 90 days before measurement.21 HbA1C is said to be relatively unaffected by the acute stress response.14 Farah et al22 shown that HbA1C may also show changes in the inflammatory response induced by hyperglycemia, and therefore may affect morbidity and mortality in patients admitted to the ICU. In our study, we found that the HbA1C level upon admission to the ICU had no statistically significant effect on mortality and morbidity. The low and narrow range of the HbA1C values (median 5.7%) limits the ability to conclusively determine that HbA1C has no effect on mortality and morbidity. When the effect of HbA1C levels on mortality in patients with diagnosed diabetes was examined, it was not found to be substantial (p=0.729). The small number of people with diabetes included in the study may explain this (n=29).

The APACHE II score is a scoring system used to estimate the mortality risks of patients by evaluating the acute physiological and chronic health status of critically hospitalized patients. An increase of one point in this score is linked to a heightened mortality risk in hospital.23 Consistent with the literature, in our study, an raise in the APACHE II score—which determines the severity of the disease—increased mortality.23,24 Each point increase directly increases the risk of mortality. In our study, we found that the APACHE II score affects mortality (p=0.005) and an increase in the score by one point increases the mortality risk by 1.14. However, we found that the APACHE II score had no statistically significant effect on morbidity.

Serum lactate increases in many critical diseases due to anaerobic glycolysis.25,26 Numerous researches have demonstrated that a high lactate level is linked to poor prognosis, emphasizing the importance of early detection in mitigating the risk of potentially poor outcomes with aggressive treatment.27 Noparatkailas et al28 conducted to predict 28-day mortality among patients with septic shock and severe sepsis, lactate levels higher than 2.0 mmol/L were identified as the most indicative threshold. In our study, the median lactate value of our patients was 1.5 (0.40–8.40) mmol/L. We thought that a low lactate level did not affect mortality or morbidity.

None of the variables in our study (cortisol, HBA1C, APACHE II score, entry blood glucose level, lactate, age, and gender) affected the number of days of stay on mechanical ventilation or in the ICU. This is due to the lack of significance of the model made incorporating all these variables.

Study limitations

Although the present study provides important evidences into the predictive value of cortisol and HbA1C levels for ICU mortality, several limitations should be acknowledged. First, the retrospective design restricts our capacity to determine causality between the observed biochemical markers and patient outcomes. Second, the sample size of 79 patients, although sufficient for preliminary analysis, may not capture the full variability in the population or allow robust subgroup analyses. Thirdly, the exclusion of patients on steroids or admitted for postoperative care may omit a segment of the ICU population for whom cortisol and HbA1C levels may have different implications. In addition, this study did not account for all potential confounding variables, such as variations in treatment protocols between ICUs or the presence of other comorbidities, which could influence both cortisol/HbA1C levels and patient outcomes. Future research should address these limitations by using prospective study designs, larger sample sizes, and more comprehensive assessments of biochemical markers and confounders to further elucidate the role of these biomarkers in critical care.

In conclusion, despite the limitation of a small patient cohort, our study suggests that the cortisol level at admission in intensive care could have predictive value for mortality. The HBA1C level does not affect mortality and is not accepted as a predictive value. More studies are needed to further explore and substantiate these preliminary findings.

Acknowledgment

The authors gratefully acknowledge Scribendi (https://www.scribendi.com) for the English language editing.

Footnotes

  • Disclosure. Authors have no conflict of interests, and the work was not supported or funded by any drug company.

  • Received January 31, 2024.
  • Accepted April 21, 2024.

This is an Open Access journal and articles published are distributed under the terms of the Creative Commons Attribution-NonCommercial License (CC BY-NC). Readers may copy, distribute, and display the work for non-commercial purposes with the proper citation of the original work.

References

  1. 1.
    1. Sharma VK,
    2. Singh TG.
    Chronic stress and diabetes mellitus: interwoven pathologies. Curr Diabetes Rev 2020; 16: 546556.
    OpenUrl
  2. 2.
    1. Becker CD,
    2. Sabang RL,
    3. Nogueira Cordeiro MF,
    4. Hassan IF,
    5. Goldberg MD,
    6. Scurlock CS.
    Hyperglycemia in medically critically ill patients: risk factors and clinical outcomes. Am J Med 2020; 133: e568e574.
    OpenUrl
  3. 3.
    1. Stoudt K,
    2. Chawla S.
    Don’t Sugar Coat It: Glycemic Control in the Intensive Care Unit. J Intensive Care Med 2019; 34: 889896.
    OpenUrl
  4. 4.
    1. Tian Y,
    2. Wang R,
    3. Zhang M,
    4. Li T,
    5. He Y,
    6. Wang R.
    Stress-induced hyperglycemia ratio as an independent risk factor of in-hospital mortality in nonresuscitation intensive care units: a retrospective study. Clin Ther 2023; 45: 3139.
    OpenUrl
  5. 5.
    1. Melis MJ,
    2. Miller M,
    3. Peters VBM,
    4. Singer M.
    The role of hormones in sepsis: an integrated overview with a focus on mitochondrial and immune cell dysfunction. Clin Sci (Lond). 2023; 137: 707725.
    OpenUrl
  6. 6.
    1. Stamou MI,
    2. Colling C,
    3. Dichtel LE.
    Adrenal aging and its effects on the stress response and immunosenescence. Maturitas 2023; 168: 1319.
    OpenUrl
  7. 7.
    1. Fowler C,
    2. Raoof N,
    3. Pastores SM.
    Sepsis and adrenal insufficiency. J Intensive Care Med 2023; 38: 987996.
    OpenUrl
  8. 8.
    1. De Castro R,
    2. Ruiz D,
    3. Lavín BA,
    4. Lamsfus JA,
    5. Vazquez L,
    6. Montalban C. et al.
    Cortisol and adrenal androgens as independent predictors of mortality in septic patients. PLoS One 2019;14: e0214312.
    OpenUrlPubMed
  9. 9.
    1. Xu W,
    2. Qiu Y,
    3. Qiu H,
    4. Zhong M,
    5. Li L.
    Serum ACTH and cortisol level is associated with the acute gastrointestinal injury grade in ICU patients. Int J Gen Med 2024; 17: 127134.
    OpenUrl
  10. 10.
    1. Bekhit OE,
    2. Mohamed SA,
    3. Yousef RM
    , AbdelRasol HA, Khalaf NA, Salah F. Relation between baseline total serum cortisol level and outcome in pediatric intensive care unit. Sci Rep 2019; 9: 6008.
    OpenUrlCrossRefPubMed
  11. 11.
    1. Rivas M,
    2. Motes A,
    3. Ismail A,
    4. Yang S,
    5. Sotello D,
    6. Arevalo M. et al.
    Characteristics and outcomes of patients with sepsis who had cortisol level measurements or received hydrocortisone during their intensive care unit management: A retrospective single center study. SAGE Open Med 2023; 11: 20503121221146907.
    OpenUrl
  12. 12.
    1. Güven M,
    2. Gültekin H.
    Could serum total cortisol level at admission predict mortality due to coronavirus disease 2019 in the intensive care unit? A prospective study. Sao Paulo Med J 2021; 139: 398404.
    OpenUrl
  13. 13.
    1. Holeček M.
    Roles of malate and aspartate in gluconeogenesis in various physiological and pathological states. Metabolism 2023; 145: 155614.
    OpenUrl
  14. 14.
    1. Furlan JC.
    Effects on outcomes of hyperglycemia in the hyperacute stage after acute traumatic spinal cord injury. Neurotrauma Rep 2021; 2: 1424.
    OpenUrlCrossRef
  15. 15.
    1. Zhang Z,
    2. Zhao Y,
    3. Liu Y,
    4. Wang X,
    5. Xu H,
    6. Fang Y, et al.
    Effect of stress-induced hyperglycemia after non-traumatic non-aneurysmal subarachnoid hemorrhage on clinical complications and functional outcomes. CNS Neurosci Ther 2022; 28: 942952.
    OpenUrl
  16. 16.
    1. Chávez-Reyes J,
    2. Escárcega-González CE,
    3. Chavira-Suárez E,
    4. León-Buitimea A,
    5. Vázquez-León P,
    6. Morones-Ramírez J, et al.
    Susceptibility for some infectious diseases in patients with diabetes: the key role of glycemia. Front Public Health 2021; 9: 559595.
    OpenUrl
  17. 17.
    1. Pratiwi C,
    2. Zulkifly S,
    3. Dahlan TF,
    4. Hafidzati A,
    5. Oktavia N,
    6. Mokoagov MI, et al.
    Hospital related hyperglycemia as a predictor of mortality in non-diabetes patients: A systematic review. Diabetes Metab Syndr 2021; 15: 102309.
    OpenUrl
  18. 18.
    1. Zohar Y,
    2. Zilberman Itskovich S,
    3. Koren S,
    4. Zaidenstein R,
    5. Marchaim D,
    6. Koren R.
    The association of diabetes and hyperglycemia with sepsis outcomes: a population-based cohort analysis. Intern Emerg Med 2021; 16: 719728.
    OpenUrl
  19. 19.
    1. Farooq N,
    2. Chuan B,
    3. Mahmud H,
    4. El Khoudary SR,
    5. Nouraie SM,
    6. Evankovich J, et al.
    Association of the systemic host immune response with acute hyperglycemia in mechanically ventilated septic patients. PLoS One 2021; 16: e0248853.
    OpenUrl
  20. 20.
    1. Shen H,
    2. Wang S,
    3. Zhang C,
    4. Gao W,
    5. Cui X,
    6. Zhang Q, et al.
    Association of hyperglycemia ratio and ventricular arrhythmia in critically ill patients admitted to the intensive care unit [published correction appears in BMC Cardiovasc Disord. 2023 May 19;23(1):260]. BMC Cardiovasc Disord 2023; 23: 215.
    OpenUrl
  21. 21.
    1. Costantini E,
    2. Carlin M,
    3. Porta M,
    4. Brizzi MF.
    Type 2 diabetes mellitus and sepsis: state of the art, certainties and missing evidence. Acta Diabetol 2021; 58: 11391151.
    OpenUrl
  22. 22.
    1. Farah R,
    2. Makhoul N,
    3. Samohvalov A,
    4. Nseir W.
    Plasma glycated hemoglobin a1c could predict 30-day all-cause mortality of intensive care unit patients with hyperglycemia. Isr Med Assoc J 2022; 24: 708712.
    OpenUrl
  23. 23.
    1. Sungono V,
    2. Hariyanto H,
    3. Soesilo TEB,
    4. Adisasmita AC,
    5. Syarif S,
    6. Lukito AA, et al.
    Cohort study of the APACHE II score and mortality for different types of intensive care unit patients. Postgrad Med J 2022; 98: 914918.
    OpenUrlAbstract/FREE Full Text
  24. 24.
    1. Czajka S,
    2. Ziębińska K,
    3. Marczenko K,
    4. Posmyk B,
    5. Szczepańska AJ,
    6. Krzych L.
    Validation of APACHE II, APACHE III and SAPS II scores in in-hospital and one year mortality prediction in a mixed intensive care unit in Poland: a cohort study. BMC Anesthesiol 2020; 20: 296.
    OpenUrl
  25. 25.
    1. Gupta GS.
    The lactate and the lactate dehydrogenase in inflammatory diseases and major risk factors in COVID-19 Patients. Inflammation 2022; 45: 20912123.
    OpenUrl
  26. 26.
    1. Rabinowitz JD,
    2. Enerbäck S.
    Lactate: the ugly duckling of energy metabolism. Nat Metab 2020; 2: 566571.
    OpenUrl
  27. 27.
    1. Liu Z,
    2. Meng Z,
    3. Li Y,
    4. Zhao J,
    5. Wu S,
    6. Gou S, et al.
    Prognostic accuracy of the serum lactate level, the SOFA score and the qSOFA score for mortality among adults with Sepsis. Scand J Trauma Resusc Emerg Med 2019; 27: 51.
    OpenUrlPubMed
  28. 28.
    1. Noparatkailas N,
    2. Inchai J,
    3. Deesomchok A.
    Blood lactate level and the predictor of death in non-shock septic patients. Indian J Crit Care Med 2023; 27: 93100.
    OpenUrl
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