Abstract
Background
Major abdominal surgery is associated with considerable mortality in the elderly. Anemia has been linked to increased mortality in other types of surgery, such as hip and cardiac surgery. This study aimed to assess the impact of preoperative anemia on mortality in the elderly undergoing major abdominal surgery, and how allogeneic red cell blood transfusion influences mortality in these patients.
Materials and methods
We conducted a single-center, register-based retrospective study on patients, who were aged beyond 60 years and underwent one of 81 open abdominal surgical procedures. Patients operated on during the period from January 1, 2000, to May 31, 2013, were consecutively identified in the Danish National Patient Registry. Plasma hemoglobin was measured within 30 days prior to surgery and the primary endpoint was 30-day postoperative mortality. Information about patient transfusions from the hospital blood bank was available from 1998 to 2010.
Results
A total of 3199 patients were included of whom 85% underwent emergency surgery. The total mortality after 30 days was 20%. The median preoperative hemoglobin value of survivors was 7.7 mmol/L vs 6.9 mmol/L in those who died. The difference in hemoglobin values, between those who survived or died, decreased from the pre- to the post-operative phase. The 30-day postoperative mortality was 28%, 20%, and 12% in patients with a preoperative hemoglobin level in the lower, median, and upper quartile respectively. Transfusion therapy was associated with higher postoperative mortality, except in patients with very low hemoglobin values.
Conclusion
Preoperative anemia has a clear association with surgically related mortality. The distribution of hemoglobin values in patients with a fatal outcome differs significantly from that of survivors. Red cell transfusion is associated with increased mortality, except in patients with very low hemoglobin values which supports recent guidelines suggesting a restrictive transfusion strategy.
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Introduction
The incidence of open emergency abdominal surgery has been reported to 30.4 cases per 100,000 person-years with a 30-day postoperative mortality of 19% [1]. To lower mortality related to open abdominal surgery, it is necessary to understand both patient characteristics and treatments which contribute to the risk of dying. Multiple risk score models have been developed for surgery, but the impact of underlying conditions such as preoperative anemia on mortality has only been scarcely studied excluding anemia as a parameter from many risk models [2].
Our focus was to investigate the effects of preoperative hemoglobin levels on the outcomes of open abdominal surgery. Anemia is a frequent abnormality in the surgical population occurring in up to 29% of patients before surgery[3]. In a study on general non-cardiac surgery, anemia was associated with a 42% increased odds ratio of dying within the first 30 postoperative days [3]. The impact of preoperative hemoglobin levels on mortality after hip and heart surgery is well-studied [4]. A meta-analysis on hip surgery found anemia associated with a pooled mortality odds ratio of 2.78 [5].
The poor prognosis associated with preoperative anemia would make it logical to consider blood transfusion but three trials involving a total of 1965 patients presenting with acute upper gastrointestinal bleeding reported lower mortality following a restrictive transfusion threshold compared with a liberal transfusion threshold [6]. A randomized controlled study of 2016 patients at increased cardiovascular risk found no benefits of liberal postoperative transfusions [7]. Likewise, a study on blood transfusion in emergency abdominal surgery in Denmark found that transfusions were associated with poorer clinical outcomes [8]. Furthermore, several studies have documented that allogeneic transfusion is associated with circulatory overload, immunosuppression, postoperative infection, thromboembolic complications, increased length of hospital stay, recurrence of colorectal cancer, and consequently cost increase [9,10,11].
The aim of this study was to assess and discuss the impact of anemia and blood transfusions on mortality in open abdominal surgery. We also aimed to develop a model to compare the mortality risk in these patients across different preoperative hemoglobin levels in blood.
Methods
Patients
The Danish National Patient Registry collects data on all major surgical interventions performed in Denmark. From this registry, we extracted data on all patients who were aged more than 60 years and underwent open abdominal surgery at the Digestive Disease Center, Bispebjerg Hospital, Denmark, from January 1, 2000, to May 31, 2013, n = 4177. A total of 81 different types of surgery according to the NOMESCO Classification of Surgical Procedures[12] were included. Only the primary (most important) surgical procedure of an intervention and the first surgical intervention during the inclusion period were assessed. In Denmark, all citizens are registered with a unique civil registration number, enabling person-level linkage across nationwide registers. This enables virtually complete long-term follow-up as regards mortality and emigration. Patients with a temporary civil registration number, missing information regarding surgical priority, or lacking concomitant measurements of hemoglobin were excluded.
The algorithm for patient selection is depicted in Fig. 1.
In the top of the figure, the included surgical patients in the period of January 1, 2000, to May 31, 2013, can be seen. Below that, the number of patients who received transfusion is shown. We have data on transfusions from beginning of January 1998 to the end of December 2010. The final patients left for analysis were those from January 2000 until the end of December 2010 for whom we have complete data on surgical procedures, hemoglobin assessments, and transfusion therapy (Fig. 2).
Hemoglobin level
Minimum and maximum hemoglobin values were obtained pre-, peri-, and post-operatively. Preoperative hemoglobin referred to the period within 30 days preceding the operation. Intraoperative was defined as sampling on the day of operation. The term postoperative covered the first 30 postoperative days. In cases with more than one measurement of hemoglobin either within 30 days prior or after the operation, the minimum and maximum values were recorded. Measurements were obtained from the local laboratory system. The normal range for plasma hemoglobin was 7.3–9.5 mmol/L for women and 8.3–10.5 mmol/L for men. The data obtained besides biochemical markers were time of hospital admission and discharge, priority of admission/surgery (elective vs emergency), type of operation, sex, and 30-day mortality.
Transfusion data
Transfusion was defined as allogeneic transfusion of at least one unit of packed red cells. Red cell units were checked out of the hospital blood bank by scanning a bar code on the unit, which simultaneously recorded the date, the recipient identity, and the ISBT-128 identity code of the blood component type in the blood bank database. By national law, the handling of every issued blood component was recorded in the database, resulting in at least 99% traceability from donor to patient. The red blood cell transfusions were categorized as pre-, peri-, or post-operative according to the period of administration.
Statistical analysis
The primary endpoint was 30-day mortality. Data analysis was performed using R statistical software [13]. The data was analyzed to create smoothed curves of mortality by fitting a locally estimated scatterplot smoothing curve (LOESS) to the data. The span parameter of the LOESS function was left at the default 0.75. Differences between baseline values in the cohort were analyzed using parametric or categorical statistical methods as appropriate. Continuous and categorical data were compared using unpaired t-test and chi-square test, respectively.
The prediction model was built using logistic regression, outputting the probability of death within 30 days. The parameters for the model were chosen using the stepwise procedure of R; using Akaike information criterion values to select parameters, all parameters had a P-value of < 0.05 with respect to predicting 30-day mortality postoperatively. After selection of parameters, receiver operating characteristics (ROC) were used to analyze the sensitivity and specificity of each component of the final model. The visualization was done using the ggplot2 package [14].
Approvals
Permission for this study was granted by the Danish Data Protection Agency (ID: 2007–58-0015). No permission from the regional Ethical Committee was needed because the study was registry-based.
Results
The cohort
The basic characteristics of the 3199 included patients with a mean age of 76.6 years. The 30-day postoperative mortality was 655/3199 (20.5%). The characteristics of the groups differed between survivors and those who died. The mean preoperative hemoglobin was 7.5 mmol/L in survivors and 7.0 mmol/L in those who died (P < 0.001). The corresponding rates of emergency surgery were 61% and 92% (P < 0.001) (Table 1).
Mortality status depending on preoperative hemoglobin level
The median preoperative minimum hemoglobin value of survivors was 7.7 mmol/L vs 6.9 mmol/L in those who died. The corresponding median minimum hemoglobin levels in the intraoperative phase was 7.6 mmol/L and 7.2 mmol/L, respectively. In the postoperative phase, the median minimum hemoglobin value was 6.3 mmol/L in both groups.
The 30-day mortality correlated negatively with minimum preoperative hemoglobin levels (Fig. 3), the Pearson coefficient was − 0.15 (P < 0.001). Patients with a preoperative hemoglobin measurement in the lowest quarter progressing through to the highest quarter had a 30-day mortality of 28%, 19%, 15%, and 12% respectively.
Transfusion rates
In total, 45% of women and 38% of men were transfused (P < 0.002). There was no significant difference in the amount of blood transfused between genders. Patients received an average of 1.3 portions of blood.
Figure 4 A displays the rate of patients receiving a blood transfusion with a given minimum hemoglobin measurement. Figure 4 B shows that the 228 patients (7%) that received preoperative blood transfusions have received them at lower hemoglobin levels following a more restrictive strategy than for the peri- or post-operative phase (Fig. 4C and D respectively). The median minimum hemoglobin level preoperatively of those receiving blood was 5.2 mmol/L (interquartile range [IQR], 4.6–5.5). A total of 952 patients (30%) received blood transfusions intraoperatively. The median minimum hemoglobin level intraoperatively for receiving blood was 6.5 mmol/L (IQR, 5.7–7.5). The median minimum hemoglobin level postoperatively was 5.5 mmol/L (IQR, 5.1–5.9) in the 629 patients (20%) who received blood transfusion postoperatively. A total of 145 (23%) of the patients who received blood postoperatively had a postoperative hemoglobin level of 6 mmol/L or above. A total of 104, 17% of postoperatively transfused patients, had not had a single hemoglobin measurement below 6.0 mmol/L either pre- or intra-operatively.
Impact of blood transfusions
There was a lower rate of mortality in the patients who did not receive transfusions in the intra- or postoperative phase with hemoglobin levels above 7 mmol/L and 6 mmol/L respectively.
Postoperatively, in the non-transfused patients, there is an approximately constant flat rate of mortality, despite having a low hemoglobin level postoperatively. The mortality of the patients who received transfusions increased and was significantly higher compared to the patients with the same hemoglobin level who were not transfused (Fig. 5C).
Logistic regression prediction
The logistic regression model was constructed using four variables: operation group (categorized into 7 subtypes), age (continuous), the distinction between acute and elective surgery (binary), and preoperative hemoglobin levels (continuous). The performance of the model in predicting the 30-day survival status was 77% using the area under the receiver operating curve (AUC) (Fig. 6). Notably, preoperative hemoglobin was identified as a significant predictor (P < 0.05) after adjusting for all other variables. The odds ratios for the factors in the model along with confidence intervals and P-values can be seen from Table 2.
Discussion
This study demonstrated that a low preoperative hemoglobin level was significantly associated with increased mortality of patients undergoing open abdominal surgery. This association was linear, as mortality correlated negatively with the preoperative hemoglobin level. The logistical regression model performed demonstrated that the preoperative hemoglobin level independently added accuracy in determining those at risk of dying in relation to open abdominal surgery, on top of other risk factors like age and type of surgery.
These results are consistent with findings in other studies [5, 15, 16]. Duron et al. studied risk factors for elderly patients undergoing major abdominal surgery and found anemic patients to have an increased odds ratio of death of 1.80. They also find that within categories of people with the same disease, such as colon cancer, those with anemia had worse outcomes. A higher mortality was also found in those with only moderate anemia [15]. Mussalam et al., in a study on effects of preoperative anemia in non-cardiac surgery, found that 30% of patients had preoperative anemia, with an elevated odds ratio of 1.42 of dying. This was consistent across mild and moderate-to-severe anemia. Importantly, the study also found that the influence of anemia was additional to other risk factors [16]. Hemoglobin is a readily available biomarker for patients admitted for surgery.
Conflicting reports exist as to the benefits of restrictive transfusion practices. A meta-analysis from Roman et al. including a wide variety of surgery types reported that patient blood management interventions reduce bleeding and transfusion requirement in patients undergoing major surgery, but postoperative morbidity and mortality were not significantly reduced [17]. Acheson et al. reported that allogeneic blood transfusion (ABT) to patients operated on for colorectal cancer was associated with adverse clinical outcomes, including increased mortality, warranting measures aimed at limiting the use of ABT [11].
Our study showed a significant proportion of blood transfusions were given to patients with hemoglobin levels above what guidelines recommend. Figure 4 A shows that patients are most likely to be transfused intraoperatively, followed by the postoperative phase, whereas the preoperative phase had one fourth of the transfusions seen in the intraoperative phase.
The patients who received blood transfusions at close to normal hemoglobin levels contrary to a restrictive strategy showed increased mortality when compared to those not receiving blood transfusion, supporting reports such as Acheson et al. [11] that blood transfusion was associated with increased morality. This difference, or gap, in mortality between the transfused and non-transfused patients increased the closer to normal the patients’ hemoglobin levels were. Transfused patients had higher mortality, which is unsurprising, as transfusion may be confounded by intraoperative blood loss. The finding that the difference in mortality increased, the closer to normal, patient hemoglobin values were, could indicate an excess risk of mortality when these patients are subject to blood transfusion compared to the patients at low hemoglobin levels, one possible explanation being the benefits of blood transfusion are diminished as hemoglobin approaches normal levels, and the downsides, such as fluid overload, remain. Thus, blood transfusions, despite restrictive guidelines stating the hemoglobin level does not justify it, carry at best no benefit, and indeed from our data the patients seem to do worse than expected.
The strengths of this study included the large number of patients and data completeness, including hemoglobin level assessments and blood transfusion therapy across each patient’s perioperative course. Also, due to the unique civil registration number, no patients were lost to follow-up resulting in accurate reporting of 30-day mortality. A limitation was the lack of data on patient comorbidity that precluded a statistical adjustment for this important confounder. Details on comorbidity, ASA stage, and history leading up to the surgery has an effect on the mortality and thus the results should be interpreted with caution. The cohort study was retrospective and inherently, this makes causality unprovable. Moreover, as the study took place in a single center, the findings might not be generalizable to other surgical settings.
In conclusion, the preoperative hemoglobin level is significantly different preoperatively among those who survive compared to those who die within 30 days undergoing open abdominal surgery. There is a significant and linear association of lower values being associated with a higher mortality. A considerable fraction of patients received blood transfusions at hemoglobin levels above guideline recommendations. These patients have a higher mortality than patients who avoided transfusion.
Data Availability
The data that support the findings of this study are available from the corresponding author, H. Buhl, upon reasonable request.
References
Liljendahl MS, Gögenur I, Thygesen LC (2020) Emergency laparotomy in Denmark: a nationwide descriptive study. World J Surg 44:2976–2981. https://doi.org/10.1007/s00268-020-05580-5
Havens JM, Columbus AB, Seshadri AJ et al (2018) Risk stratification tools in emergency general surgery. Trauma Surg Acute Care Open 3:e000160. https://doi.org/10.1136/tsaco-2017-000160
Desai N, Schofield N, Richards T (2018) Perioperative Patient blood management to improve outcomes. Anesth Analg 127:1211–1220. https://doi.org/10.1213/ANE.0000000000002549
Loor G, Rajeswaran J, Li L et al (2013) The least of 3 evils: exposure to red blood cell transfusion, anemia, or both? J Thorac Cardiovasc Surg 146:1480-1487.e6. https://doi.org/10.1016/j.jtcvs.2013.06.033
Laulund AS, Lauritzen JB, Duus BR et al (2012) Routine blood tests as predictors of mortality in hip fracture patients. Injury 43:1014–1020. https://doi.org/10.1016/j.injury.2011.12.008
Odutayo A, Desborough MJR, Trivella M et al (2017) Restrictive versus liberal blood transfusion for gastrointestinal bleeding: a systematic review and meta-analysis of randomised controlled trials. Lancet Gastroenterol Hepatol 2:354–360. https://doi.org/10.1016/S2468-1253(17)30054-7
Carson JL, Terrin ML, Noveck H et al (2011) Liberal or restrictive transfusion in high-risk patients after hip surgery. N Engl J Med 365:2453–2462. https://doi.org/10.1056/NEJMoa1012452
Schack A, Ekeloef S, Ostrowski SR et al (2022) Blood transfusion in major emergency abdominal surgery. Eur J Trauma Emerg Surg 48:121–131. https://doi.org/10.1007/s00068-020-01562-3
Gosmann F, Nørgaard A, Rasmussen M-B et al (2018) Transfusion-associated circulatory overload in adult, medical emergency patients with perspectives on early warning practice: a single-centre, clinical study. Blood Transfus 16:137–144. https://doi.org/10.2450/2017.0228-16
Piccin A, Spizzo G, Popovski MA et al (2021) Transfusion-associated circulatory overload in gastroenterology. Blood Transfus 19:197–204. https://doi.org/10.2450/2020.0025-20
Acheson AG, Brookes MJ, Spahn DR (2012) Effects of allogeneic red blood cell transfusions on clinical outcomes in patients undergoing colorectal cancer surgery: a systematic review and meta-analysis. Ann Surg 256:235–244. https://doi.org/10.1097/SLA.0b013e31825b35d5
Nomesco N (2011) NOMESCO Classification of Surgical Procedures (NCSP), version 1.16, Available from: https://norden.diva-portal.org/smash/get/diva2:970547/FULLTEXT01.pdf
R Core Team (2020) R: a language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. https://www.R-project.org/. Accessed 10 Sept 2021
Wickham H (2016) ggplot2: elegant graphics for data analysis [Internet]. Springer-Verlag New York; Available from: https://ggplot2.tidyverse.org. Accessed 10 Sept 2021
Duron J-J, Duron E, Dugue T et al (2011) Risk factors for mortality in major digestive surgery in the elderly: a multicenter prospective study. Ann Surg 254:375–382. https://doi.org/10.1097/SLA.0b013e318226a959
Musallam KM, Tamim HM, Richards T et al (2011) Preoperative anaemia and postoperative outcomes in non-cardiac surgery: a retrospective cohort study. The Lancet 378:1396–1407. https://doi.org/10.1016/S0140-6736(11)61381-0
Roman MA, Abbasciano RG, Pathak S et al (2021) Patient blood management interventions do not lead to important clinical benefits or cost-effectiveness for major surgery: a network meta-analysis. Br J Anaesth 126:149–156. https://doi.org/10.1016/j.bja.2020.04.087
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Henrik Buhl participated in the study design, wrote the manuscript, and performed the statistical calculations; Astrid Nørgaard participated in the study design and critical review of the manuscript; Astrid Otkjaer participated in the study design and critical review of the manuscript; Lars Nannestad Jørgensen participated in the study design and critical review of the manuscript; Henrik Løvendahl Jørgensen participated in the study design and critical review of the manuscript.
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Buhl, H., Nørgaard, A., Otkjaer, A. et al. The impact of anemia and blood transfusion on mortality after open abdominal surgery in the elderly. Langenbecks Arch Surg 408, 421 (2023). https://doi.org/10.1007/s00423-023-03122-w
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DOI: https://doi.org/10.1007/s00423-023-03122-w