Critical Care

Abstract

Background

Recent studies have implicated the differences in the ABO blood system as a potential risk for various diseases, including hemostatic disorders and hemorrhage. In this study, we evaluated the impact of the difference in the ABO blood type on mortality in patients with severe trauma.

Methods

A retrospective observational study was conducted in two tertiary emergency critical care medical centers in Japan. Patients with trauma with an Injury Severity Score (ISS) > 15 were included. The association between the different blood types (type O versus other blood types) and the outcomes of all-cause mortality, cause-specific mortalities (exsanguination, traumatic brain injury, and others), ventilator-free days (VFD), and total transfusion volume were evaluated using univariate and multivariate competing-risk regression models. Moreover, the impact of blood type O on the outcomes was assessed using regression coefficients in the multivariate analysis adjusted for age, ISS, and the Revised Trauma Score (RTS).

Results

A total of 901 patients were included in this study. The study population was divided based on the ABO blood type: type O, 284 (32%); type A, 285 (32%); type B, 209 (23%); and type AB, 123 (13%). Blood type O was associated with high mortality (28% in patients with blood type O versus 11% in patients with other blood types; p <  0.001). Moreover, this association was observed in a multivariate model (adjusted odds ratio = 2.86, 95% confidence interval 1.84–4.46; p <  0.001). The impact of blood type O on all-cause in-hospital mortality was comparable to 12 increases in the ISS, 1.5 decreases in the RTS, and 26 increases in age. Furthermore, blood type O was significantly associated with higher cause-specific mortalities and shorter VFD compared with the other blood types; however, a significant difference was not observed in the transfusion volume between the two groups.

Conclusions

Blood type O was significantly associated with high mortality in severe trauma patients and might have a great impact on outcomes. Further studies elucidating the mechanism underlying this association are warranted to develop the appropriate intervention.

© The Author(s): Wataru Takayama, Akira Endo, Hazuki Koguchi, Momoko Sugimoto, Kiyoshi Murata and Yasuhiro Otomo

Background

The ABO blood system determines the carbohydrate moieties that are expressed on red blood cells (RBCs) and vascular endothelium. Furthermore, ABO antigens are highly expressed on the surface of a variety of human cells and tissues.

At the beginning of the 20th century, from the time the system was discovered by Karl Landsteiner [1], the ABO blood type was studied widely in relation to diseases and blood transfusion complications. Recent studies have implicated that the ABO blood type is a potential risk for various diseases such as cancer, myocardial infarction, acute kidney injury, and venous thromboembolism [2, 3, 4, 5].

Furthermore, the ABO blood type has a profound influence on hemostasis. The occurrence of venous thromboembolism is relatively rare in individuals with blood type O compared with individuals with other blood types [4, 5]. In addition, the relationship between the difference in blood type and the risk of bleeding was reported in patients with several diseases such as upper gastrointestinal hemorrhage [6], hemorrhage during extracorporeal membrane oxygenation therapy [7], and obstetrical hemorrhage [8].

Hemorrhage is the leading cause of death in patients with trauma and could deteriorate the outcome of traumatic brain injury (TBI) due to the increase in intracranial hemorrhage. Therefore, we assessed the association between the difference in blood type and the outcomes of all-cause and cause-specific mortality in patients with severe trauma on the assumption that the outcomes of trauma are affected by the difference in blood type.

Methods

Study design and setting

This retrospective observational study aimed to evaluate the association between ABO blood type and mortality in patients with severe trauma who were transported between 1 April 2013 and 31 March 2016 to either of the two tertiary emergency critical care medical centers in Japan (Tokyo Medical and Dental University Hospital of Medicine or Matsudo City Hospital).

This study complied with the principles of the 1964 Declaration of Helsinki and its later amendments. This study was approved by the institutional review board of Tokyo Medical and Dental University and Matsudo City Hospital (#M2017–237 and #29–14, respectively). The requirement for informed consent from each patient was waived because the design of the study was retrospective in nature and because of the use of anonymized patient and hospital data.

Study populations

We included consecutive patients with trauma who suffered severe injury as defined by an Injury Severity Score (ISS) greater than 15 and who were directly transferred from the scene of injury. Patients who met at least one of the following criteria were excluded from the study: 1) patients younger than 15 years; 2) patients with cardiac arrest upon arrival at the emergency department (ED); 3) patients who suffered unsurvivable injury (Abbreviated Injury Scale (AIS) = 6); and 4) patients with a history of taking anticoagulants or antiplatelet agents. In addition, patients whose clinical data for analysis were missing or insufficient were excluded.

Data collection

The following information was retrospectively collected from the patients’ medical records: age; sex; blood type (A, B, AB, or O); Charlson Comorbidity Index [9]; the number of patients who received uncrossmatched type O RBC transfusions; AIS [10] of the head and neck, face, chest, abdomen, pelvis and extremities, and surface; ISS; Revised Trauma Score (RTS) calculated based on the Glasgow Coma Scale, systolic blood pressure, and respiratory rate upon arrival at the ED [11]; the total number of units of RBC transfusions administered within 24 h of ED admission; and status upon hospital discharge (i.e., dead or alive). The causes of death were categorized into three groups: exsanguination, TBI, and others (including multiple organ failure). We defined patients with isolated severe TBI as patients with a head AIS ≥ 3 and AIS for other parts of the body ≤ 2.

Outcomes and definition

The primary outcome was defined as all-cause in-hospital mortality. The secondary outcomes were defined as cause-specific in-hospital mortality (exsanguination, TBI, and others), ventilator-free days (VFD) [12], and total number of units of RBC transfusions administered within the first 24 h from arrival at the ED. One unit of transfusion is prepared from approximately 200 ml of whole blood in Japan, while it is prepared from approximately 450 ml in the USA. Therefore, we prepared transfusion units multiplied by 2.2 to convert to a US standard form and we present them in US units. As previously reported, multiple organ dysfunction syndrome was represented by an increase in the Sequential Organ Failure Assessment score of 2 points or more in more than one organ system [13].

Statistical analysis

The included population was divided into four groups according to blood type (i.e., A, B, O, and AB). We used a one-way analysis of variance to assess the differences among the four groups. We further evaluated the difference between blood type O and non-O blood type for the outcomes. In univariate analysis, continuous variables were compared using a Student’s t test or Mann-Whitney U test, and categorical variables were compared using the χ2 test or Fisher’s exact test as appropriate. A multivariate logistic or linear regression analysis was performed for the assessment of primary and secondary outcomes after simultaneously controlling for the potential confounders. Variables incorporated into the model were age, RTS, and ISS; these variables were selected based on the clinical perspective (subject matter knowledge) and the number of outcomes (the 10 events per variable rule). The calibration of the model was validated using a Hosmer–Lemeshow goodness-of-fit test; the discrimination of the model was assessed using an optimism-corrected concordance (c) statistic, which was calculated in 5000 bootstrap samples. The impact of the difference in blood type on the outcomes was assessed using the value of regression coefficients calculated using a logistic or linear regression analysis and compared with that of other variables.

All statistical analyses were performed using the R software (version 3.4.1; R Foundation for Statistical Computing, Vienna, Austria). A command was used to add statistical functions that were frequently used in the biostatistics. Two-sided p values < 0.05 were considered statistically significant.

Results

Of 1049 potentially eligible patients, 901 severe trauma patients were included in the analysis (Fig. 1). The study population was divided based on the ABO blood type: type O, 284 (32%); type A, 285 (32%); type B, 209 (23%); and type AB, 123 (13%). The baseline characteristics of patients and outcomes according to blood type are shown in Table 1. Statistically significant difference among the four groups was observed only for RTS (p = 0.019); all remaining characteristics were similarly distributed. There was a significant difference in all outcomes except for the number of units of RBC transfusions administered within 24 h. Table 2 provides the comparison of characteristics and the result of univariate analysis for the outcomes between blood type O and other blood types. While there was no significant difference in ISS and AIS in all body regions, patients with blood type O had significantly lower RTS than those with non-O blood type (mean 6.85 (standard deviation (SD) 1.43) in blood type O versus 7.13 (1.15) in other blood types; p = 0.003). Although the difference was not statistically significant, the number of units of RBC transfusions administered within 24 h tended to be more in patients with blood type O than those with other blood types (mean 3 (SD 9) units in blood type O versus 2 (7) units in other blood types; p = 0.112).

Figure 1

Fig. 1

Flow diagram of patient selection. AIS, Abbreviated Injury Scale; ISS, Injury Severity Score

Table 1

Baseline characteristics and outcomes in each blood group

Type O

n = 284

Type A

n = 285

Type B

n = 209

Type AB

n = 123

p value

Characteristics

 Age, years (SD)

57.3 (20.0)

56.3 (20.0)

57.6 (19.4)

53.6 (17.8)

0.284

 Female, n (%)

64 (22.5)

61 (21.4)

55 (26.3)

26 (21.1)

0.593

 Charlson Comorbidity Index, median (IQR)

0 (0–2)

0 (0–2)

0 (0–1)

0 (0–1)

0.380

 Uncrossmatched type O RBC transfusion, n (%)

28 (9.9)

17 (6)

16 (7.7)

4 (3.3)

0.086

 RTS, mean (SD)

6.85 (1.43)

7.12 (1.18)

7.08 (1.16)

7.23 (1.03)

0.019

 ISS, median (IQR)

18 (16–25)

18 (16–25)

19 (16–25)

20 (16–25)

0.133

 AIS head, median (IQR)

4 (3–4)

4 (3–4)

4 (3–4)

4 (3–4)

0.842

 AIS face, median (IQR)

0 (0–0)

0 (0–0)

0 (0–0)

0 (0–0)

0.983

 AIS chest, median (IQR)

0 (0–2)

0 (0–3)

0 (0–3)

0 (0–3)

0.612

 AIS abdomen, median (IQR)

0 (0–0)

0 (0–0)

0 (0–0)

0 (0–0)

0.781

 AIS extremities, median (IQR)

0 (0–2)

0 (0–2)

0 (0–2)

0 (0–2)

0.681

 AIS surface, median (IQR)

0 (0–0)

0 (0–0)

0 (0–0)

0 (0–0)

0.873

Outcomes

 In-hospital mortality, n (%)

80 (28.2)

30 (10.5)

30 (14.4)

11 (8.9)

< 0.001

 Death due to exsanguination, n (%)

23 (8.1)

5 (1.8)

5 (2.4)

4 (3.3)

< 0.001

 Death due to TBI, n (%)

43 (15.1)

22 (7.7)

19 (9.1)

3 (2.4)

< 0.001

 Death due to other causes, n (%)

14 (4.9)

3 (1.1)

6 (2.9)

4 (3.3)

0.062

 Ventilator-free days, mean (SD)

18.7 (12.2)

23.1 (9.3)

22.3 (10.2)

24.5 (8.2)

< 0.001

 Units of RBCs administered within 24 h, mean (SD)

3 (11)

2 (5)

2 (10)

2 (8)

0.231

Categorical variables are expressed as numbers (%); continuous variables are presented as medians (25–75 percentiles = interquartile range (IQR))

We used a one-way analysis of variance to assess the differences among the four blood groups

AIS Abbreviated Injury Scale; ISS Injury Severity Score; RBC red blood cell; RTS Revised Trauma Score; SD standard deviation; TBI traumatic brain injury

Table 2

The comparison of characteristics and outcomes between blood type O and other blood types

Type O

n = 284

Non-O type

n = 617

p value

Characteristics

 Age, years (SD)

57.3 (20.0)

56.2 (19.4)

0.442

 Female, n (%)

64 (22.5)

142 (23)

0.873

 Charlson Comorbidity Index, median (IQR)

0 (0–2)

0 (0–1)

0.829

 Uncrossmatched type O RBC transfusion, n (%)

28 (9.9)

37 (6)

0.051

 RTS, (SD)

6.85 (1.4)

7.13 (1.2)

0.003

 ISS, median (IQR)

18 (16–25)

19 (16–25)

0.160

 AIS head, median (IQR)

4 (3–4)

4 (3–4)

0.582

 AIS face, median (IQR)

0 (0–0)

0 (0–0)

0.783

 AIS chest, median (IQR)

0 (0–2)

0 (0–3)

0.342

 AIS abdomen, median (IQR)

0 (0–0)

0 (0–0)

0.561

 AIS extremities, median (IQR)

0 (0–2)

0 (0–2)

0.443

 AIS surface, median (IQR)

0 (0–0)

0 (0–0)

0.652

Outcomes

 In-hospital mortality, n (%)

80 (28.2)

71 (11.5)

< 0.001

 Death due to exsanguination, n (%)

23 (8.1)

15 (2.4)

< 0.001

 Death due to TBI, n (%)

43 (15.1)

44 (7.1)

< 0.001

 Death due to other causes, n (%)

15 (1.8)

11 (5.3)

0.005

 Ventilator-free days, mean (SD)

18.7 (12.2)

23.1 (9.4)

< 0.001

 Units of RBCs administered within 24 h, mean (SD)

3 (9)

2 (7)

0.112

Categorical variables are expressed as numbers (%); continuous variables are presented as medians (25–75 percentiles = interquartile range (IQR))

AIS Abbreviated Injury Scale; ISS Injury Severity Score; RBC red blood cell; RTS Revised Trauma Score; SD standard deviation; TBI traumatic brain injury

In the multivariate model, the p value of the Hosmer–Lemeshow goodness-of-fit test was 0.269, which suggested that our model had acceptable predictability. The calibration plot is presented in Additional file 1: Figure S1. Furthermore, the value of concordance (c) statistics (95% confidence interval (CI)) was 0.88 (0.85–0.91) for crude data, and the value of optimism-corrected c statistics calculated in 5000 bootstrapped samples was 0.88. These statistics indicated excellent discrimination for the model, and the issue of overfitting was eliminated in our model. The results of the multivariate analysis are presented in Table 3 and Additional file 2: Table S1. After controlling for age, ISS, and RTS, blood type O continued to be the independent risk factor for all-cause in-hospital mortality (adjusted odds ratio (OR) 2.86 (95% CI 1.84–4.46); p <  0.001), death due to exsanguination (adjusted OR 2.55 (95% CI 1.25–5.22); p = 0.009), death due to TBI (adjusted OR 1.80 (95% CI 1.08–3.01); p = 0.024), death due to other causes (adjusted OR 2.73 (95% CI 1.21–6.13); p = 0.015), and shorter VFD (adjusted differences −2.7 days (95% CI −3.9 to −1.6), p <  0.001). The impact of blood type O and other factors on respective outcome is shown in Fig. 2.

Table 3

Multivariate analysis of the impact of blood type O on outcomes

Adjusted odds ratio (95% CI)

Adjusted difference (95% CI)

p value

Primary outcome

 All-cause in-hospital mortality

2.86 (1.84–4.46)

< 0.001

Secondary outcomes

 Death due to exsanguination

2.55 (1.25–5.22)

0.009

 Death due to TBI

1.80 (1.08–3.01)

0.024

 Death due to others

2.73 (1.21–6.13)

0.015

 Ventilator-free days

−2.7 (−3.9 to −1.6)

< 0.001

 Units of RBCs administered within 24 h

1.23 [−0.94–1.36]

0.722

CI confidence interval; RBC red blood cell; TBI traumatic brain injury

Figure 2

Fig. 2

The impact of blood type O and other factors on respective outcome. The bar charts indicate each regression coefficient and the error bars indicate each standard error. ISS, Injury Severity Score; RBC, red blood cell; RTS, Revised Trauma Score; TBI, traumatic brain injury

The value of the regression coefficient of blood type O for all-cause in-hospital mortality was approximately 12-fold, −1.5-fold, and 26-fold compared with that for ISS, RTS, and age, respectively. This result indicated that the impact of blood type O on in-hospital mortality was comparable to 12 increases in ISS, 1.5 decreases in RTS, and 26 increases in age. For death due to exsanguination, the value of the regression coefficient of blood type O was approximately 12-fold, −2.5-fold, and 55-fold compared with that for ISS, RTS, and age, respectively.

Discussion

In this retrospective study, we evaluated the association between blood type O and the mortality in 901 patients with severe trauma. Findings indicated that blood type O was the independent risk factor for all-cause in-hospital mortality and death due to exsanguination, TBI, and other causes after adjusting for potential confounders. The number of units of RBC transfusions administered within 24 h upon admission to the ED tended to be more in patients with blood type O; however, there was no significant difference between blood type O and other blood types. To the best of our knowledge, this is the first study to report the association between ABO blood type and mortality in patients with severe trauma. Although we cannot alter the risk of blood type O itself, an adequate recognition of the risk enables us to control for the intensity of trauma critical care. Recognizing those patients requiring damage-control resuscitation is a crucial issue since damage-control resuscitation, including strategic multiple operation, sufficient amounts of available transfusions with adequate ratios, and perioperative critical care, requires a large amount of human and healthcare resources. Therefore, recognizing the additional risk of the difference in blood type would imply the potential to optimize the implementation or damage-control resuscitation and indirectly improve the outcome of patients with severe trauma.

Several studies have reported that patients with blood type O had 25–30% lower plasma von Willebrand factor (vWF) levels than the those with non-O blood, increasing their risk of hemorrhage [14, 15]. vWF plays a decisive role in primary hemostasis by mediating the adhesion of blood platelets to the subendothelium of the damaged vessel walls and promoting the aggregation of activated platelets. In addition, vWF acts as a carrier of factor VIII clotting activity and protects it from premature proteolysis [16, 17, 18]. Therefore, a lower vWF level is a possible explanation for the increase in mortality in patients with blood type O, as observed in this study. However, many of the differences in the mechanisms of hemostasis according to blood type remain unknown. Further basic study is warranted to reveal the role of blood type in maintaining hemostasis during critical situations.

Although the results of the multivariate analysis showed that blood type O was an independent risk factor for all-cause trauma-related mortality and death due to exsanguination, there was no significant difference in the number of units of RBC transfusions administered within 24 h of admission in patients with blood type O compared with those with other blood types. One possible explanation for this discrepancy is the issue of survivor bias. Patients who died shortly after ED arrival or who did not have a surgical indication due to too severe an injury were less likely to receive large amounts of transfusion. Another possible explanation was beta error. The number of patients who received a RBC transfusion was only 20% of the total patients included, and it prevented us from detecting the significant difference between the two groups.

In this study, although ISS was similar between the two groups, RTS observed in patients with blood type O was lower than that in patients with other blood types. The physiological status of patients with blood type O may deteriorate even if these patients suffered injuries of the same intensity. Because this was a retrospective cohort study with a limited sample size, patient background could not be similarly distributed, and it was uncertain whether the statistically significant difference observed in RTS was a clinically meaningful result. Although completely adjusting the difference using a statistical approach was generally insufficient, in this study the RTS value was incorporated into the model and the difference was accounted for. Our results demonstrated that the impact of blood type O on trauma death was extremely high. The impact of blood type O on all-cause mortality was comparable to 12 increases in ISS, 1.5 decrease in RTS, and 26 increases in age. Furthermore, the impact of blood type O seemed to be higher for the outcome of death due to exsanguination than the all-cause trauma-related mortality. It would be of great significance for clinicians to recognize the potential risk of blood type O.

Several limitations should be considered in the interpretation of our findings. First, because this was a retrospective study with a limited sample size, the risk of residual confounding and the risk of type I error remain. Additional work is necessary to provide more definitive data, including large-scale multicenter studies. Second, we only evaluated the phenotype and not the genotype of the ABO blood group or Rh system. The highest levels of clotting vVIII and vWF were observed in the A1A/A1B/BB genotype, intermediate levels in the A1O/BO genotype, and lowest levels in the OO genotype [19]. Possibly, by comparing type O to non-O blood type instead of A1A/A1B/BB to OO, the effect of ABO on prognosis was diluted. In addition, in this study, only two patients had Rh-negative blood, and this prevented us from assessing the statistical difference between Rh-positive and Rh-negative patients. Third, all the patients analyzed in this study were Japanese; therefore, it is unclear whether our findings apply to other ethnic groups. Finally, patients who had received anticoagulant and/or antiplatelet therapy were excluded from this study because these agents could largely influence the mortality and hemorrhage in severe trauma patients; this process could cause a selection bias—if the difference in blood type is related to thrombotic diseases, patients with the blood type that were less likely to suffer from thrombotic diseases were less likely to receive those therapies. However, in this study, the excluded patients due to anticoagulant and/or antiplatelet therapy was similarly distributed among each blood type (type O, 12; type A, 15; type B, 10; and type AB, 8); therefore, this process would not largely affect the results. Despite these limitations, we initially show a significant association between blood type O and mortality in patients with severe trauma. Furthermore, the impact of blood type O on trauma-related death was found to be high. Further research beyond this epidemiological study that evaluates where and how ABO antigens work (through blood, endothelial, or vWF, and the mechanisms, respectively) are warranted to assess the effects of emergency uncrossmatched type O RBC transfusion and the possibility of novel therapeutic interventions.

Conclusion

The results of this study suggest that blood type O is associated with mortality and exsanguination in patients with severe trauma. Further basic or translational research is necessary to investigate the cause of this result and may lead to the development of a therapeutic intervention.

Abbreviations

AIS: Abbreviated Injury Scale
CI: Confidence interval
ED: Emergency department
ISS: Injury Severity Score
OR: Odds ratio
RBC: Red blood cell
RTS: Revised Trauma Score
SD: Standard deviation
TBI: Traumatic brain injury
VFD: Ventilator-free days
vWF: Von Willebrand factor

Declarations

Acknowledgements

We thank all the included patients and their families, physicians, nurses, paramedics, and all staff. In addition, we thank Dr. Raira Nakamoto and Dr. Nao Urushibata for their direct patient care and their review and feedback on the manuscript. We also acknowledge Dr. Atsushi Shiraishi for guidance on the statistical analysis.

Availability of data and materials

The datasets analyzed in this study are not publicly available due to privacy issues, but are available from the corresponding author upon reasonable request.

Authors’ contributions

WT participated in the study design, data collection, drafting of the manuscript, and the statistical analysis. AE participated in the statistical analysis and helped draft the manuscript. HK and MS participated in the study design and helped draft the manuscript. KM and YO participated in the study conception and design, data collection, and drafting of the manuscript. All the authors have read the manuscript, discussed the results, and approved this submission.

Ethics approval and consent to participate

This study was approved by the institutional review boards of Tokyo Medical and Dental University and Matsudo City Hospital (#M2017–237 and #29–14, respectively). This study complies with the principles of the 1964 Declaration of Helsinki in reviewing and publishing information from the patient’s medical records. The requirement for informed consent from each patient was waived because the design of study was retrospective in nature and because of the use of anonymized patient and hospital data.

Competing interests

The authors declare that they have no competing interests.

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References

  1. Kruskall MS, AuBuchon JP. Making Landsteiner’s discovery superfluous: safety and economic implications of a universal group O red blood cell supply. Transfus Sci. 2010;18:613–20.View ArticleGoogle Scholar
  2. Sun W, Wen CP, Lin J, Wen C, Pu X, Huang M, et al. ABO blood types and cancer risk—a cohort study of 339,432 subjects in Taiwan. Cancer Epidemiol. 2015;39:150–6.View ArticlePubMedPubMed CentralGoogle Scholar
  3. Reilly JP, Anderson BJ, Mangalmurti NS, Nguyen TD, Holena DN, Wu Q, et al. The ABO histo-blood group and AKI in critically ill patients with trauma or sepsis. Clin J Am Soc Nephrol. 2015;10:1911–20.View ArticlePubMedPubMed CentralGoogle Scholar
  4. Wu O, Bayoumi N, Vickers MA, Clark P. ABO (H) blood groups and vascular disease: a systematic review and meta-analysis. J Thromb Haemost. 2008;6:62–9.View ArticlePubMedGoogle Scholar
  5. Dentali F, Sironi AP, Ageno W, Turato S, Bonfanti C, Frattini F, et al. Non-O blood type is the commonest genetic risk factor for VTE: results from a meta-analysis of the literature. Semin Thromb Hemost. 2012;38:535–48.View ArticlePubMedGoogle Scholar
  6. Bayan K, Tuzun Y, Yilmaz S, Dursun M, Canoruc F. Clarifying the relationship between ABO/Rhesus blood group antigens and upper gastrointestinal bleeding. Dig Dis Sci. 2009;54:1029–34.View ArticlePubMedGoogle Scholar
  7. Mazzeffi M, Gupta R, Lonergan T, Pasrija C, Kon Z, Tanaka K. ABO type and bleeding during adult ECMO. Intensive Care Med. 2017;43:275–6.View ArticlePubMedGoogle Scholar
  8. Chauleur C, Cochery-Nouvellon E, Mercier E, Aya G, Fabbro-Peray P, Mismetti P, et al. Some hemostasis variables at the end of the population distributions are risk factors for severe postpartum hemorrhages. J Thromb Haemost. 2008;6:2067–74.View ArticlePubMedGoogle Scholar
  9. Charlson ME, Pompei P, Ales KL, MacKenzie CR. A new method of classifying prognostic comorbidity in longitudinal studies: development and validation. J Chronic Dis. 1987;40:373–83.View ArticlePubMedGoogle Scholar
  10. Keller WK for the AMA Committee on Medical Aspects of Automotive Safety. Rating the severity of tissue damage. I. The abbreviated scale. JAMA. 1971;215:277–80.Google Scholar
  11. Champion HR, Sacco WJ, Copes WS, Gann DS, Gennarelli TA, Flanagan ME. A revision of the trauma score. J Trauma. 1989;29:623–9.View ArticlePubMedGoogle Scholar
  12. Schoenfeld DA, Bernard GR, Network ARDS. Statistical evaluation of ventilator-free days as an efficacy measure in clinical trials of treatments for acute respiratory distress syndrome. Crit Care Med. 2002;30:1772–7.View ArticlePubMedGoogle Scholar
  13. Marshall JC, Cook DJ, Christou NV, Bernard GR, Sprung CL, Sibbald WJ. Multiple organ dysfunction score: a reliable descriptor of a complex clinical outcome. Crit Care Med. 1995;23:1638–52.View ArticlePubMedGoogle Scholar
  14. Gill JC, Endres-Brooks J, Bauer PJ, Marks WJ Jr, Montgomery RR. The effect of ABO blood group on the diagnosis of von Willebrand disease. Blood. 1987;69:1691–5.PubMedGoogle Scholar
  15. Dentali F, Sironi AP, Ageno W, Bonfanti C, Crestani S, Frattini F, et al. Relationship between ABO blood group and hemorrhage: a systemic literature review and meta-analysis. Semin Thromb Hemost. 2013;39:72–82.View ArticlePubMedGoogle Scholar
  16. Ruggeri ZM, Zimmerman TS. von Willebrand factor and von Willebrand disease. Blood. 1987;70:895–904.PubMedGoogle Scholar
  17. Moeller A, Weippert-Kretschmer M, Prinz H, Kretschmer V. Influence of ABO blood groups on primary hemostasis. Transfusion. 2001;41:56–60.View ArticlePubMedGoogle Scholar
  18. O’Donnell J, Laffan MA. The relationship between ABO histo-blood group, factor VIII and von Willebrand factor. Trransfus Med. 2001;11:343–51.View ArticleGoogle Scholar
  19. Jenkins PV, O’Donnell JS. ABO blood group determines plasma von Willebrand factor levels: a biologic function after all? Transfusion. 2006;46:1836–44.View ArticlePubMedGoogle Scholar