Analysis of a Blood-Saving Intervention during Blood Collection in Critical Patients ()
1. Background
Phlebotomy is a routine test performed in hospitals. In critically ill patients, the number of daily collections is usually higher than the standard average, due to the severity of the illnesses causing their admission, resulting in greater blood loss than other patients and the need for blood transfusion [1] [2]. These blood losses can be associated with the pathological process itself, therapeutic support and continuous blood collections for diagnostic purposes, and may contribute to the appearance of hospital-acquired anaemia (HAA) [3]. Severe intra-hospital anaemia occurs in 1.4% of hospitalised patients and is associated with higher morbidity and mortality [4].
Blood losses related to phlebotomy in Intensive Care Units (ICU) can range between 25 mL and 377 mL/day in patients during admission [2] [5] [6]. In previous studies, we carried out a situation analysis in which we examined the blood volume collected from critically ill patients in the first 24 hours of admission, and we concluded that the average blood loss was 80.7 mL [7] and that the volume of blood collected depended on the number of analytical prescriptions and sampling technique [8]. Routine inpatient laboratory testing reflects wasteful clinical practice that threatens the value of healthcare.
The World Health Organization (WHO) recommends the implementation of programmes that improve clinical practices related to the rational use of allogenic blood products and the implementation of alternatives to blood transfusions [9]. The Patient Blood Management (PBM) programme aims to minimise the risk of transfusion to the patient from a multidisciplinary approach, focused on evidence-based interventions designed to preserve patients’ blood volume. They are based on 3 fundamental pillars: comprehensive management of anaemia, optimising the physiological tolerance of the patient’s anaemia and minimising iatrogenic blood losses [10].
The evidence-based guideline describes different strategies to reduce blood loss secondary to phlebotomy, some related to the request for laboratory tests: how to rationalise the number of prescriptions and avoid duplicating diagnostic tests [11]. Others are related to reducing the volume of blood for analysis, by using paediatric tubes, or adjusting the amount of blood required in each phlebotomy to the technique to be performed [12] [13] [14]. In ICUs, blood is collected using vascular catheters; some recommendations are aimed at reducing the volume of waste blood through specific systems, or at recording waste volumes [10] [15].
These strategies require a proactive approach, multidisciplinary collaboration, patient-centred care, and adaptation to the local context. The critical care nurse must have resources and protocols that help to minimise iatrogenic blood loss since they are responsible for managing the volume collected in each phlebotomy.
Our theory is that the implementation of these strategies will reduce the blood volume collected from the patient. The objective of this study was to analyse the impact of 3 blood-saving strategies implemented to reduce the blood volume collected in analyses performed on critically ill patients.
2. Methods
This is a pre-post quasi-experimental study design with a non-equivalent control group.
This study was carried out in the ICU of a tertiary hospital, which has 32 beds in 4 units, including neurotrauma, medical-surgical, coronary and cardiac surgery. Data collection in the pre-intervention phase was from 1 February to April 2017. Implementation phase was carried during 2018, and post-intervention phase, data was collected between 1 February to April 2019.
1) Inclusion criteria: All the patients admitted to any of the ICU units, older than 18 years old, with a stay of at least 24 h. Exclusion criteria: Patients with active bleeding (those who presented detectable or diagnosed blood losses), after cardiac surgery with a blood loss greater than 1.5 mL/kg/h during six consecutive hours within the first 24 h, patients with coagulation pathologies or ones that had received haemoderivatives during the study period.
2) Population and sample: all patients over 18 years of age admitted for 24 hours or more in an ICU were included. Patients with diagnosed blood loss, post-cardiac surgery with blood loss greater than 1.5 mL/kg/h during the first 6 hours after surgery, patients with coagulopathies or those undergoing transfusions during the study period were excluded. Calculation of sample size and selection: the design and calculation of the sample size is based on the assumption that the population standard deviation of the total volume of blood collected on a routine day is ±10 mL. A difference of at least 5 mL between the pre and post group can be detected by assuming that 100 patients are required in the first group and 100 in the second. An alpha risk of 0.05 and a beta risk of 0.2 have been accepted in a two-sided contrast.
3) Variables: age, sex, medical diagnosis, unit of admission, weight balance at 24 hours, Acute Physiology and Chronic Health Evaluation (APACHE) severity indices, Simplified Acute Physiologic Score (SAPS), number of tests performed in 24 hours, volume of waste blood before specimen collection, usable blood volume for analyses, total blood volume in 24 hours (usable volume for sample analysis plus waste volume) in 24 hours, haemoglobin (Hb) on admission and at 24 hours, sampling technique, catheter used and work experience.
4) Data collection: The same collection and recording model as in the first phase was used. Annex 1: The forms were completed by the nurses responsible for performing each phlebotomy. The researchers entered data on age, sex, diagnosis, haemoglobin, severity indices, and weight balance.
5) Intervention: After a review of the literature, 3 strategies best adapted to the local context were selected to reduce blood volume:
a) Rationalisation of analytical performance specifications:
i) Adjust each analysis to every patient’s needs.
ii) The troponin collection protocol was modified in the patient with acute myocardial infarction: troponin levels were measured every 4 hours instead of every 2 hours, and it was established that the troponin curve would be suspended when detecting the first decreasing value.
b) Blood volume reduction to analyse:
i) Using smaller volume tubes for clinical analysis (Biochemistry tubes with 8.5 mL separator gel were replaced by 3.5 mL ones; 4 mL lithium heparin biochemistry tubes by 2 mL ones; 3 mL EDTA tubes by 2 mL ones; 2.7 mL by 1.8 mL citrate ones). Prior to replacing the tubes, analyses were carried out using higher and lower volumes and the same results were obtained.
ii) Standardisation of the volume collected in blood gas to 1 mL. We use 3 mL syringes and comparisons of the blood gas results were made with 3 mL and 1 mL ones, the results being within the ranges considered optimal by the GEM Premier 4000® gasometer; the minimum volume required is 0.1 mL of blood for each analysis.
c) Reduction of the waste volume:
i) Use of the closed system technique to obtain samples through catheters (pressurised systems were used to monitor invasive blood pressure or central venous pressure). A syringe is attached to the patient's distal tap to mix the waste blood with the purging solution. Blood for testing is obtained from the patient’s proximal tap. The waste blood is subsequently reintroduced in a sterile manner into the bloodstream.) If this was not possible, the volume of blood collected per catheter used was standardised to twice the volume of the dead space.
ii) Subsequently, a strategy was developed to implement these approaches through information sessions for nurses and doctors, infographics were designed and placed in visible places in the different units of the ICU, an animated video was created explaining the benefits of each strategy, and disseminated through clinical sessions and the mobile network.
d) Data analysis: a descriptive exploratory analysis of the categorical and quantitative variables was performed. Categoric variables were expressed in absolute and relative frequencies. Normally distributed continuous variables were represented by mean and standard deviation and median and interquartile range when normality was not fulfilled. The Kruskall-Wallis variance analysis and the Mann-Whitney U test were used for variables with non-normal distribution and the Student’s t-test for those that did meet normality criteria. Associations between variables took place using a Rho de Spearman correlation coefficient. Significant values of p < 0.05 were considered. We used the IBM SPSS Statistics 20.0.
e) Ethical considerations. The study was presented and subsequently approved by the Research Committee of the hospital. No modifications were made to the care or experimental procedures, according to the international standards stipulated in the Helsinki Act (1964). I know guaranteed the confidentiality of the data (Data Confidentiality Law LOPD 15/99).
3. Results
3.1. Socio-Demographic Data
During the months of data collection in the post-intervention phase, a total of 574 admissions in ICU, and 130 patients were registered, 18 of which were excluded because they did not meet the inclusion criteria. A sample of 112 patients was used (Figure 1).
A 72.3% (81) were men, with an average age of 57.8 (±17.6) and 27.7% (31) were women, with an average age of 67 (±12.4). The groups were significantly different in terms of age, sex, diagnosis, unit of admission and SAPS severity index (p < 0.05). There was a higher percentage of men in the post-intervention phase. The number of records of post-intervention patients who had undergone cardiac surgery and suffered from subarachnoid haemorrhaging increased with respect to the pre-intervention phase. Table 1 shows details of the variables studied in the pre and post-intervention phases. Variables expressed as median ± standard deviation, percentages (%), * <0.05.
3.2. Results of the Number of Samples Collected
A total of 656 samples were collected, in comparison with 865 in the pre study.
Table 1. Variables studied in the pre and post-intervention phases. Subarachnoid haemorrhage (SAH), acute respiratory failure (ARF), post abdominal surgery (Post. Abd). Acute Physiology and Chronic Health Evaluation (APACHE) severity indices, Simplified Acute Physiologic Score (SAPS). *p < 0.05.
The average number of laboratory tests per patient 24 hours after admission in the post-intervention phase was 5.8 (±1.9), compared to 7.2 (±2.6) in the pre-intervention phase (p < 0.001). A comparison of the number of analyses performed per pathology causing admission shows a reduction in the post phase (Figure 2).
3.3. Results of the Volume of Blood Collected
The average volume of waste in 24 h was 14 mL (±10.2) in the post phase vs. 31.6 mL (±15.8) in the pre phase, with p < 0.001. The average volume of usable blood for the analyses was 22.9 mL (±10) in the post phase vs. 48.1 mL (±16.7) in the pre phase, p < 0.001. The total average volume of usable blood in the post phase was 38.6 mL (±17.6) vs. 80.7 mL (±26.8) in the pre phase, p < 0.001. A decrease in blood volumes was registered in the post phase of: 55.69% blood waste, 52.39% usable blood and 52.16% total volume (Figure 3).
A greater number of laboratory tests and blood volume collected from patients after cardiac surgery, acute myocardial infarction (AMI), cardiorespiratory arrest (CRA) and septic shock were recorded compared to patients diagnosed with acute respiratory failure (ARF), polytrauma, head trauma (head injury) and abdominal surgery (Table 2).
Figure 2. Number of analyses according to pathology causing admission.
Figure 3. The a1verage volume of waste, average volume of usable and total average volume in 24 h, acording ICU units.
3.4. Results of the Correlation of Hb and the Sex, Balance, Severity Index and Collected Blood Volume Variables
No significant statistical differences were found between the haemoglobin variable
Table 2. Number of analyses according to pathology causing admission. Heartfailure included Acute myocardialinfarction (AMI) and cardiorespiratory arrest (CRA). Subarachnoid haemorrhage (SAH), acute respiratory failure (ARF), post abdominal surgery Post. Abd). *p < 0.05.
and the sex, severity index and collected blood volume variables. There is a small negative correlation between the Hb at 24 hours, the difference in haemoglobin and the ponderal balance. Greater differences in Hb at 24 hours were found in patients with a positive balance in comparison with those with a negative balance (r = −0.24, p = 0.008) (Figure 4).
The difference in Hb 24 h after admission was higher in patients admitted to cardiac surgery (X: −0.81 g/dL), coronary (X: −0.8 g/dL) and neurotrauma units (X: −1.1 g/dL), this difference was only significant in postoperative cardiac surgery patients (p < 0.05).
38.1% of professionals used conservative techniques with zero waste for specimen collection, versus 11.6% in the pre-intervention phase. The catheters most often used for the collection of samples in the post phase were arterial cannulas and PICC, and the least used were PVC. The average waste volumes per catheter were: 3.5 mL of arterial cannula, 2 mL PVC, 2.5 mL PICC and 5 mL CVC (p = 0.170).
44.9% of professionals in the post-intervention phase had between <1 and 1 - 5 years’ work experience. These were the ones who discarded the most blood - 5 mL (p < 0.001) (Table 3). In the post-intervention phase, the waste volume in professionals with more experience was significantly lower than in pre-intervention phase (p < 0.001).
Figure 4. Correlation between haemoglobin on admission (Hb1) and at 24 hours (Hb2), and difference Hb1-Hb2.). *p < 0.05.
Table 3. Wastevolumebased on professional experience. *<0.001.
4. Discussion
The blood volume collected in the post intervention phase was lower than that collected in the pre intervention phase. Promoting valuable clinical practices and benefits for patients. Some scientific societies promote initiatives recommending non-performance of certain medical or nursing practices (“Do not do”), or reduction in their frequency, such as unnecessary and repetitive laboratory tests [16] [17].
The first of the strategies implemented in this study was to reduce the number of routine tests and adjust them to the needs of each patient, which meant a 24% reduction in samples collected. Other hospital centres have designed and implemented similar interventions in hospitalised patients, obtaining a 26% reduction in laboratory tests in the post-intervention phase [18]. Sadowsky [19] et al. eliminated automated orders from the institutional programme, managing to change the pattern of analytical prescriptions which led to reducing routine tests by 15% - 20%. Eaton [11] describes three strategies consisting of education, auditing and feedback on healthcare practice in relation to laboratory tests and concludes that he has obtained satisfactory results in terms of reducing the number of tests, costs, and patient and professional satisfaction. In the Coronary unit, a decrease in admissions of patients with acute myocardial infarction (AMI) was observed. Acute cardiovascular disease focused on cardiorespiratory arrest (CRA) and cardiogenic shock [20]. Although this involved more seriously ill patients, a decrease in the number of samples collected compared to the pre-intervention phase was observed, however, patients diagnosed with CRA were those who underwent more blood tests. It should be noted that the number of venous procedures in patients with uncomplicated AMI are lower than those in patients with severe cardiovascular disease (CRA, cardiogenic shock), which is why the number of tests and easy blood collection also increases in patients with more serious pathologies. Chant states that small increases in blood loss associated with phlebotomy (3.5 mL/day) in critically ill patients are associated with a greater probability of blood transfusions in prolonged admissions of more than 21 days.
The second of the implemented strategies involved the use of smaller volume tubes for laboratory collections in adult patients. The usable blood volume was reduced by 50% compared to the pre-intervention phase, and the same parameters were studied. Previous studies have observed the impact of the use of paediatric tubes in adult patients, calculating rates of blood volume reduction similar to those of this study. They conclude that the amount of blood in these tubes is sufficient to obtain reliable analytical results and a significant reduction in blood volume loss [21] [22] [23]. Whitehead [15] states that the use of small volume tubes mitigates the development of anaemia, but they are insufficient to evaluate the effect on blood loss or the decrease in haemoglobin levels. Salysbury [24] relates blood loss from phlebotomy to the appearance of HAA, stressing that the use of smaller volume tubes limits the severity of anaemia. Literature is controversial regarding the claim that blood loss associated with laboratory tests significantly contributes to the development of HAA, and some studies attribute it to critically ill patients having impaired erythropoietic functions [25].
Another strategy implemented to reduce blood loss involved standardising the volume collected for blood gas analysis at 1 mL. Jensen [14] compared the reliability of the results of blood gases with 1 mL and 3 mL syringes and concluded that they were reliable, and that the volume of blood collected was reduced by 60%. We agree with Jensen [14] that it would be possible to obtain greater blood savings with this strategy by reducing the volume of blood for blood gases to 0.5 mL.
The third strategy involved the implementation of closed systems, aimed at returning the blood waste. An increased number of professionals used conservative techniques, especially those with greater work experience. The disposal technique continued to be the most widely used, however, the average volumes decreased in the post-intervention phase in professionals with more than five years of experience. In the intervention phase, use of the zero waste technique and/or discarding the bare minimum was encouraged.
Arterial catheters were most often used for specimen collection in the post-intervention phase, which facilitated specimen collection; unlike the pre-intervention phase, in which peripheral catheters were the most used, since there were a greater number of admissions with AMI. Low states that having artery access increases the number of blood tests and the volume of blood collected from the patient by 44%, compared to patients with no arterial lines [26]. A clinical trial stated that the use of blood-saving devices has a positive impact on the patient, reducing the blood loss associated with this procedure [27]. Literature supports the use of blood-saving systems with both arterial and venous catheters, but the evidence is not sufficient to determine the impact of these devices on the decrease in haemoglobin and the need for transfusion during ICU admission.
Another option to reduce waste volumes is to standardise them according to the type of catheter. Coene [28] calculates that, by standardising the volume collected with catheters, the daily blood collected per patient decreases by 25%. Whitehead compares the use of closed and conventional systems for blood collection, concluding that using blood-saving devices can reduce volume loss by 25%.
With regard to haemoglobin, it has been described that the mean haemoglobin level of the critically ill patient upon admission to the ICU is approximately 11 g/dl, with a prevalence of anaemia of 65% [29] [30]. In our study, the average Hb at admission was 12 g/dl. The strategies implemented have been effective in reducing blood volumes related to phlebotomy, but they have not been sufficient to prevent the appearance of iatrogenic anaemia or to relate it to the decrease in haemoglobin. This issue is controversial, and Makam [31] states that it is unlikely that blood loss due to phlebotomy is the main cause of HAA. Institutional support and interdisciplinary collaboration are required to disseminate, implement, evaluate and provide feedback on “care bundles” to reduce the appearance of iatrogenic anaemia [32].
5. Limitations
The study was carried out in two phases, the control group being different to the post-intervention group, which may condition the variability in the decrease in haemoglobin at 24 hours. The data collection period was only 24 hours, and in future studies long-term data should be collected to be able to establish possible causes associated with the decrease in haemoglobin. The costs of these strategies have not been evaluated. In future studies it would be interesting to measure the saving costs after the implementation of the strategies.
6. Conclusions
In summary, individualising the analytical needs of the patients made it possible to reduce the number of blood samples collected. Greater effort should be invested in limiting analytical testing and eliminating routine orders to improve the results of this strategy.
The use of smaller volume tubes and the standardisation of filling blood gas syringes have reduced the usable blood volume collected from critically ill patients by 50% in the first 24 hours of admission.
There has been an increase in the use of conservative techniques to enable nurses to obtain samples. Using blood-conserving devices to collect blood samples with a catheter would reduce the clinical variability of the technique and the volume of blood waste.
All strategies implemented reduced the phlebotomy blood volume to a greater or lesser extent, especially the use of smaller volume tubes. The other strategies have room for improvement. In future research, professionals involved should be made aware of the importance of minimising blood loss secondary to routine collections to mitigate AAI as much as possible.
Acknowledgements
We send our thanks to all our colleagues from ICU HUSE for the collaboration and participation in the collection of data, and to Aina Millán Pons for your support in statistical analysis.
The Institution at Which the Work Was Performed
Son Espases University Hospital, Spain.