ABSTRACT
Aim:
This study aimed to assess the adequacy of knowledge among emergency residents (ERs) and determine the correlation between the knowledge and practice of capnography waveform (CW).
Materials and Methods:
This 6-month questionnaire-based cross-sectional study was conducted at the emergency department of a hospital. All ERs were included in this study. Respondents’ knowledge was evaluated by exploring their interpretation of CW according to clinical situations and their ability in making appropriate clinical decisions and management. Pearson correlation statistic was used to determine the correlation between knowledge and practice.
Results:
This study included 48 ERs. The mean scores for knowledge and practice (± standard deviation) were 5.69±1.82 and 4.40±1.8, respectively. No correlation was found between knowledge and practice (r=0.186, p=0.207).
Conclusion:
ERs’ ability to interpret CW was satisfactory. However, understanding the relevance of the CW findings and subsequent clinical management was poor.
Introduction
End-tidal carbon dioxide (EtCO2) is the concentration of carbon dioxide (CO2) at the end of expiration. It provides information on ventilation (CO2 elimination), perfusion (CO2 transport in blood circulation), and metabolism (cellular metabolism and production of CO2) (1-5).
Capnography Waveform (CW) is a useful, non-invasive, reliable, and real-time monitoring tool in emergency settings that can improve patient safety. It has been used extensively and became a standard of care to monitor the patient’s ventilation during procedural sedation and analgesia (6). Moreover, it allows the rapid detection of airway obstruction, hypoventilation, and apnea in real-time (7,8). Henceforth, immediate intervention can be instituted early to prevent catastrophic consequences (9).
For patients with acute respiratory distress manifestations, clinical status, and CW findings provide essential clinical information. Abnormal CW is associated with higher intubation rates, intensive care unit (ICU) admissions, and mortality (10).
International Liaison Committee on Resuscitation recommended the application of quantitative waveform capnography during cardiopulmonary resuscitation (CPR) to ensure effective chest compression and to detect the return of spontaneous circulation (11,12). Moreover, CW may provide an objective basis to determine patients’ prognosis, hence, terminating CPR (13). Continuous CW is also considered the gold standard for verifying proper endotracheal tube placement (1-4).
However, this monitoring technology is only as good as the user who analyses and interprets it. The ability to accurately interpret the CW is important but appropriately acting on the finding is important as well. The purposes of this study were to assess the knowledge of emergency residents (ERs) on CW who use it in their daily clinical practice and to determine the correlation coefficient between the ability of interpreting CW and the appropriateness of clinical intervention following the interpretation. We postulated that the mean score of knowledge and practice in CW and its application among ERs is 50% to 60%, and there is a significant positive correlation between knowledge and practice of CW.
We believe that knowledge and practice gap findings detected in this study can form a basis local education program development concerning the role of CW in clinical practice. The same questionnaire from this study can be utilized to evaluate the effectiveness of the education program.
Materials and Methods
Study Design and Setting
This questionnaire-based, cross-sectional study was conducted in the emergency department (ED), Hospital Melaka, Malaysia, over 6 months period that lasted from September 1st, 2019 to February 28th, 2020. Hospital Melaka is a tertiary hospital located in Melaka state, Malaysia, with multiple specialty disciplines and subspecialty service.
The number of ERs working in ED Hospital Melaka was inconsistent due to hospital administrative allocation, availability of new residents, and request from ERs to transfer to other departments. ED Hospital Melaka was staffed with 30 ERs in the year 2018, 35 ERs in the year 2019, and 45 in the year 2020. Their experience in ED varies, ranging from 0 months to 6 years, with the majority less than 3 years in ED. To ensure competency and up-to-date medical knowledge, continuing medical education (CME) sessions were held weekly to discuss various emergency topics, in a traditional pedagogy approach aided with simple technology, e.g. PowerPoint slides presentation or video demonstration. Inevitably ERs will miss part of the CME sessions due to working shifts. From the year 2019, capnography was available in ED Hospital Melaka (Oridion® sidestream device for the intubated patient only). Summary of CW in different clinical scenarios was printed and attached on the wall next to monitoring devices in the resuscitation zone to aid clinical judgment of clinicians when interpreting CW.
This study was conducted in compliance with the ethical principles outlined in the Declaration of Helsinki and Malaysia Good Clinical Practice (GCP) Guideline.
Population and Sample Size
ERs in ED Hospital Melaka were recruited through universal sampling. The ERs who were on leave during the study period and did not complete the questionnaire were excluded from the study.
The sample size was calculated using Power Analysis and Sample Size Software (PASS) version 11.0 (NCSS, LLC, Kaysvillie UT, USA). Sample size calculation followed Bujang and Baharum’s (14) recommendations to analyze the correlation between knowledge and practice. To achieve a significant result (p<0.05) with sufficient power (80%) and at least a correlation coefficient of 0.4, the below formula was applied (14,15).
Sample size = N = [(Zα + Zβ)/C]2
The standard normal deviate for α = Zα = 1.9600
The standard normal deviate for β = Zβ = 0.8416
C = 0.5 x ln[(1+r)/(1-r)] = 0.4236
N = [(Zα + Zβ)/C]2 = 42
A 10% dropout rate was added to the total sample to get the required sample size. As a result, the total number of 48 respondents was required for inferential analysis. Respondents were approached personally by the author to improve the engagement in this study to ensure the dropout rate not exceeding the estimation of 10%. Any confusion, doubts, and queries would be explained promptly, and the author would receive feedback directly after the questionnaire was answered.
Research Tool Development
We adapted The Association of Medical Education in Europe Guide no. 87 for educational research questionnaire development to formulate the questionnaire (16). The questionnaire construction process consists of five stages: item development, pretest, face validation, pilot study, and finalize questionnaire (16).
In the context of this study, knowledge is defined as the correct interpretation of CW tracing, and practice is defined as the correct management of patients based on the simulated clinical picture and end-tidal CW interpretation. The questionnaire was constructed with the concept of the minimally competent candidates (or “borderline candidates”) to discriminate between candidates with and without adequate theoretical and applicable knowledge (17).
Stage 1: Item Development
An extensive literature review was conducted using textbooks, PubMed, and Google Scholar. The term “end-tidal capnography waveform” is synonymous with “EtCO2”, “waveform capnography”, “end-tidal carbon dioxide”, “capnography”, “end-tidal capnography” and “EtCO2 waveform monitoring”. Existing questionnaires related to knowledge and practice towards end-tidal capnography waveforms were sought. Core topics in EtCO2 were listed after interviews with emergency physicians and readings from journals, international guidelines, or consensus.
The knowledge section’s core topics included normal waveform interpretations, indications of EtCO2 monitoring, and causes of flat line tracings. The practice section’s core topics included the application of EtCO2 during CPR, mechanical ventilation, and pattern recognition of abnormal waveforms in different clinical scenarios.
Stage 2: Pretest of the Draft Questionnaire
Selected items were drafted into a questionnaire and pretested among 15 ERs. Interviews were conducted to check for comprehensiveness, readability, relevance, and clarity of the draft questionnaire. Feedbacks were considered, and corrections were made to the draft questionnaire.
Stage 3: Face and Content Validation
For face validation, a panel consisting of 6 experts in the field of end-tidal CW in the emergency setting was invited to validate the questionnaire (18,19). They are emergency physicians or consultants who have clinical experience in end-tidal CW, education/training, or survey study.
The content validity index (CVI) was calculated for each item to decide its acceptability. Experts were asked to rate items for clarity, relevance, representativeness, and importance on a 4-point scale. For instance, to rate relevance of an item, experts are given four options: 1 = not relevant, 2 = somewhat relevant, 3 = quite relevant, 4 = highly relevant (20). The scale-level content validity index (S-CVI/Ave) was calculated using the averaging calculation method. Ratings of more than 0.9 are considered excellent content validity (21). In this study, S-CVI/Ave score for both knowledge and practice was 0.9 and above.
Stage 4: Pilot Study and Retest
A pilot test was carried out among 15 ERs, and a retest was conducted a week after. The intraclass correlation coefficient (ICC) was used to test the reliability of the questionnaire. ICC values of less than 0.5 indicate poor reliability, values between 0.5 and 0.75 indicate moderate reliability, values between 0.75 and 0.9 indicate good reliability, and values greater than 0.90 indicate excellent reliability (22,23). In this study, all the items achieved an ICC of more than 0.7.
Stage 5: Finalise Questionnaire
The final questionnaire consists of six items in the demographics section, 10 items in the knowledge section, and 10 items in the practice section (Appendix 1).
Data Collection
The questionnaire was distributed among respondents who fulfilled the criteria and consented from September 1st, 2019 to February 28th, 2020. Respondents who were involved in the pretest and pilot study were excluded. They were required to answer all the items within one hour, without discussing or refer to any resources.
Statistical Analysis
Statistical analysis was performed using Statistical Package for the Social Science version 20.0 (SPSS Inc. Cary, NC, USA). The distribution of the data set was determined by evaluating skewness and kurtosis results. The skewness and kurtosis value within -1 to +1 were considered normal distribution of the data set. Numerical data were reported either as mean [standard deviation (SD)] or median [interquartile range (IQR)]. Categorical data were reported as a percentage (%).
There were 10 items in the knowledge and practice section, respectively. One (1) mark would be given for the correct response in each item. The minimum score would be 0, and the maximum score would be 10 in each section. For each respondent, correct responses were summed up to give rise to a total knowledge and practice score. Then, the mean score for each section was analyzed with descriptive statistics function in SPSS.
To discriminate respondents with adequate theoretical and applicable knowledge and those without, a traditional passing mark of 60% in the professional medical examination was set in our study (24-26). Respondents who score 6.00 and above were considered “adequate”, and those who score 5.99 and below were considered “inadequate”. We have a similar understanding that there is no gold standard in standard-setting methods (24,27,28). Hence, the different methodology may yield different passing marks (17,28).
Correlation between knowledge and practice was analyzed using the Pearson correlation coefficient because the data was normally distributed. The correlation coefficient value of less than 0.2, 0.2 to 0.39, 0.4 to 0.59, 0.6 to 0.79, and 0.8 to 1.0 indicates very weak correlation, weak correlation, moderate correlation, strong correlation, and very strong correlation respectively.
Point estimation from the general population mean with a lower and upper bound of 95% confidence interval was calculated. Therefore, p<0.05 was considered to be statistically significant.
Results
Demographic Characteristics
Forty-eight ERs were enrolled in the study. The respondents’ age ranged from 26 to 32 years old (Table 1). The median (IQR) age of respondents was 27 (1) years old. The predominant gender of the respondents was female (70.8%). The duration of medical service among respondents ranged from 12 months to 52 months. The median (IQR) duration of respondents’ medical service was 21 (8.8) months. The respondents’ duration of ED service ranged from 14 days to 28 months. The median (IQR) years of experience in ED was 3 (3.5) months. Among 48 respondents, only one of them had formal training in CW application.
Capnography: Knowledge Score
The mean score of overall respondents’ knowledge (± SD) was 5.69±1.82. The number of respondents who scored above 60% was 62.5% (Table 2). Item K3a had the highest percentage of correct response (100%), while item K2a had the lowest correct response percentage (33.3%) (Figure 1).
Capnography: Practice Score
The mean score of respondent skill/practicing ability was 4.40±1.81. The number of respondents who scored above 60% was 29.2% (Table 2). Five out of 10 items had more than 50% correct responses (Figure 2). Item P2 had the highest percentage of correct responses (64.4%), while item P8 had the lowest correct response percentage (4.2%).
Correlation Between Knowledge and Practice Score
There was a weak and non-significant correlation between the two variables, r=0.19, p=0.20.
Discussion
This questionnaire’s objective was to assess the knowledge and practice of the ERs towards EtCO2 interpretation and application because capnography offers great opportunities to improve the quality of treatments and give rescuers feedback on the effectiveness of life-saving procedures, particularly during the management of critically ill patients. However, without adequate knowledge of CW interpretation and application, capnography is just a fancy gadget without purpose. It is necessary to prepare future ERs on the right path of patients’ safety and effective practice regarding the CW application.
In our study, the majority of the respondents were junior doctors. The most senior respondent in this study served 4 years in health service and 2 years in ED. There were a few identified reasons for lack of senior ERs. For instance, the diversity/complexity in patients’ clinical presentations (trauma, acute surgical, neuro-psychiatric, acute medical, domestic violence, child abuse), shift duty, challenges in leave management, and “not knowing what is coming through the doors next” (29). In Malaysia scenario, ERs with a great interest in pursuing their career in Emergency Medicine by joining the master program or fellowship program will serve longer in the ED.
Being a junior ER and working in the overcrowding and unpredictable environment with undifferentiated cases is indeed a great challenge, particularly in making appropriate clinical reasoning and decision making of undifferentiated illness from different genders and age groups. ED clinician’s responsibilities that exceed the junior ERs’ capabilities may lead to stress, hence providing substandard management to patients.
In most of ED in Malaysia, the severity of the patient’s condition was categorized into three zones, i.e., red zone (critical), yellow zone (semi-critical), and green zone (non-critical). Red zone and yellow zone patients suffered from life-threatening and potentially life-threatening conditions whereby the capnography evaluation is indicated in the measurement of adequacy of alveolar ventilation, airway integrity, cardiopulmonary function, and ventilator function. ED administrator tends to locate the junior ERs to the non-critical zones for them to familiarise with the new challenges, new workplace environment, and different type of cases. Therefore, it was not surprised if the respondents had inadequate knowledge of capnography and its application. Few studies revealed that despite the availability of capnography devices, there was a lack of knowledge and skills among emergency medical service providers (30,31).
This study revealed that most respondents (97.9%) did not receive any formal training in capnography during their undergraduate years and internship period. Probable reasons included EtCO2 is not an important vital sign in Malaysia, it is not widely available throughout the country, and PaCO2 level is available in arterial blood gases test (32-34).
The knowledge score distribution among the ERs of less than 6.0 and above 6.0 was 38% and 62%, respectively. Surprisingly, two-thirds of ERs had adequate knowledge of capnography. The mean (± SD) score of overall respondents’ knowledge was 5.69±1.82. All the respondents answered correctly regarding CW’s indication during the management of sudden cardiac arrest or CPR (Question K3a). However, three-quarters of them did not answer correctly on the normal range of EtCO2 (Question K2a).
Most ERs had achieved an adequate level in the knowledge section despite limited training, and previous exposure was an interesting finding. There are a few reasons to explain the above findings. In our opinion, the CW has a simple structure or shape, and the information is easily deduced if the respondents understood the respiratory system, carbon dioxide transport, and cellular metabolism. A study by Iyer et al. (35) in 2015 demonstrated after mild exposure and education, nearly all the respondents were able to achieve basic understandings and adequate knowledge in EtCO2 readings. Moreover, in our ED, CW in different clinical scenarios was printed and exhibited on the wall next to the resuscitation zone’s monitoring devices. The exhibited printed information provides interpretation assistance of the waveform and troubleshooting assistance to the doctors on duty. Interpretations and use of CW were discussed briefly during relevant topics in continuous medical education (CME) sessions, e.g., cardiac arrest, emergency intubation, and post-intubation care. ERs may also acquire knowledge on CW during attending relevant courses, e.g., advanced cardiac life support (ACLS) and mechanical ventilator workshop. And not to mention the role of emergency physicians who discussed the capnography’s advantages and disadvantages during their ward round or bedside teaching.
In this study, most ERs (71%) had a practical score of less than 6.0, which is considered insufficient practical skill regarding response to abnormal CW. The mean (± SD) score of overall respondents in the practice section was 4.40±1.81. Most of the questions in the practice section were answered incorrectly by the ERs. Only 64% of respondents answered correctly for re-intubation in the event of continuous flat waveform tracings post-intubation, and only 4% of respondents able to recognize the leaking endotracheal tube and choose to re-intubate patients.
In our hospital setting, CW only available in the form of sidestream device for monitoring intubated patients in the resuscitation zone. Limited working experience in the resuscitation zone, less exposure to the practical use of waveform, and it was not consistently applied to the patient may contribute to the low competency level in the practice section of our study (36-38). The inconsistent use of CW among clinical staff in acute care settings, despite emerging evidence of CW monitoring in improving patient safety, is a discouraging fact. Lack of awareness and specific knowledge deficits on the importance of CW in clinical practice contribute to capnography application failure (39). The planned organizational effort for implementation plays a role in promoting CW (40,41). In the UK, the 4th national audit project of the Royal College of Anaesthetists and Difficult Airway Society (NAP4) recommended CW monitoring during intubation in the ED setting (42).
Competence is the acquisition of knowledge, skills, and abilities at a level of expertise sufficient to perform in an appropriate work setting. In simple words, knowledge and practice should always go hand in hand (30). Our study demonstrated an extremely weak correlation between the interpretation knowledge of CW and its clinical application. In other words, the respondent’s knowledge was not reflected in their practice. Reasons for the insignificant correlation could be multifactorial. Lack of policy, lack of motivation, and inadequate training may be part of the reasons (43). We believe that the interpretation of CW is related to pre-existing theoretical knowledge but the clinical application requires practice and experience, hence the correlation was weak.
Interestingly, this finding was similar to a study conducted by Wylie et al. (31) in 2019, except the studied population were paramedics. The study demonstrated that pre-hospital care staff achieved high CW knowledge scores but low scores in CW applications. However, the attributing factors were not studied (31).
Recommendations
Our study showed different results from other studies (30,44). It was also contrary to common study findings that higher knowledge scores were associated with higher practice scores (45-47), and vice versa. Hence, different strategies are required to improve the competency of ERs in CW. The training program is of utmost importance: Czyż et al. (30) in 2018 demonstrated that emergency medical services providers who received training in CW achieved significantly higher scores than those who did not receive training.
CME sessions regarding basic and advanced usage of CW should be organized at the departmental level. The knowledge of CW should be incorporated into other related courses, e.g., ACLS. Bedside teaching should be encouraged and continued. In particular, a specific indication of CW can be discussed, e.g., during CPR, with the addition of current evidence, benefits, and data interpretations rather than a general overview. The discussions will then serve as a gateway to other applications with CW (41). Diagram, poster, or flip chart regarding CW should be made available in the resuscitation zone. The logbook should include CW applications as one of the core competencies in the emergency residency program.
At the organizational level, the standard operating procedure of positive ventilated patient care should include CW monitoring. EtCO2 level should be monitored in all positive ventilated patients and documented in medical records or charts (48,49). Stocks of capnography should be made available and easily accessible in the department (41).
Study Limitations
There are limitations to this study. The methodology and study design limit the sample, and the results cannot be generalized to other departments, e.g., ICU care settings, or different posts in emergency care settings, e.g., staff nurses. The closed-ended type instrument limits its ability to explore the reason for different competency levels in the knowledge and practice section. The difficulty level of each item and item discrimination were not analyzed in this study. The lack of respondents with previous training and experience in CW also makes studying the correlation between them and knowledge with practice difficult. We do not know whether senior ERs would have produced different outcomes in this study. Future studies should involve a different level of expertise or center and further validation of the instrument.
Conclusion
The knowledge in CW among ERs, particularly junior residents, was sufficient. However, the appropriate response towards the abnormal finding of CW was questionable. Strategies should be formulated to enhance their knowledge and training on the daily application of CW, with the ultimate goal of improving patient safety.