Improving the coding and classification of ambulance data through the application of International Classification of Disease 10th revision
Kate Cantwell A B C H , Amee Morgans B D , Karen Smith B C E , Michael Livingston F G and Paul Dietze A CA Centre for Population Health, Burnet Institute, 85 Commercial Road, Melbourne, Vic. 3004, Australia.
B Ambulance Victoria, 375 Manningham Road, Doncaster, Vic. 3108, Australia.
C Department of Epidemiology and Preventive Medicine, Monash University, The Alfred Centre, Level 6, 99 Commercial Road, Melbourne, Vic. 3004, Australia.
D Department of Community Emergency Health and Paramedic Practice, Monash University, Peninsula Campus, PO Box 527, Frankston, Vic.3199, Australia.
E Emergency Medicine Department, University of Western Australia, 35 Stirling Hwy, Crawley, WA 6009, Australia.
F Drug Policy Modelling Program, National Drug and Alcohol Research Centre, University of New South Wales, 22–32 King Street, Randwick, NSW 2031, Australia.
G Centre for Alcohol Policy Research, Turning Point Alcohol and Drug Centre, 54 Gertrude Street, Fitzroy, Vic. 3065, Australia.
H Corresponding author. Email: kcantwell@burnet.edu.au
Australian Health Review 38(1) 70-79 https://doi.org/10.1071/AH13163
Submitted: 20 May 2013 Accepted: 15 November 2013 Published: 31 January 2014
Abstract
Objectives This paper aims to examine whether an adaptation of the International Classification of Disease (ICD) coding system can be applied retrospectively to final paramedic assessment data in an ambulance dataset with a view to developing more fine-grained, clinically relevant case definitions than are available through point-of-call data.
Methods Over 1.2 million case records were extracted from the Ambulance Victoria data warehouse. Data fields included dispatch code, cause (CN) and final primary assessment (FPA). Each FPA was converted to an ICD-10-AM code using word matching or best fit. ICD-10-AM codes were then converted into Major Diagnostic Categories (MDC). CN was aligned with the ICD-10-AM codes for external cause of morbidity and mortality.
Results The most accurate results were obtained when ICD-10-AM codes were assigned using information from both FPA and CN. Comparison of cases coded as unconscious at point-of-call with the associated paramedic assessment highlighted the extra clinical detail obtained when paramedic assessment data are used.
Conclusions Ambulance paramedic assessment data can be aligned with ICD-10-AM and MDC with relative ease, allowing retrospective coding of large datasets. Coding of ambulance data using ICD-10-AM allows for comparison of not only ambulance service users but also with other population groups.
What is known about the topic? There is no reliable and standard coding and categorising system for paramedic assessment data contained in ambulance service databases.
What does this paper add? This study demonstrates that ambulance paramedic assessment data can be aligned with ICD-10-AM and MDC with relative ease, allowing retrospective coding of large datasets. Representation of ambulance case types using ICD-10-AM-coded information obtained after paramedic assessment is more fine grained and clinically relevant than point-of-call data, which uses caller information before ambulance attendance.
What are the implications for practitioners? This paper describes a model of coding using an internationally recognised standard coding and categorising system to support analysis of paramedic assessment. Ambulance data coded using ICD-10-AM allows for reliable reporting and comparison within the prehospital setting and across the healthcare industry.
Additional keywords: ambulance, ICD-10-AM, major diagnostic categories, prehospital.
Introduction
Ambulance services provide life-saving care for a range of medical or traumatic conditions as well as transport to hospital. Research into ambulance services using health record datasets informs the development of the best treatment and transport options. Use of a reliable and standard coding and categorising system is essential to support analysis of paramedic assessment data contained in these datasets. No such system exists to date.
We reviewed the literature on ambulance data related to temporal patterns in ambulance demand and identified studies that have coded ambulance datasets for the purposes of research.1 The most common methods were either using a telephone triage-derived dispatch determinant (most commonly the Medical Priority Dispatch System (MPDS))2–5 or ‘a system devised by the authors’.6–11
Categorisation using MPDS occurs at the point-of-call receipt, before ambulance arrival. It is a structured electronic triage process allowing operators (typically laypeople) to prioritise ambulance cases, and is targeted at resource allocation and case prioritisation rather than clinical diagnosis. The system is based on information given by the caller (patient or bystander). Case information is often provided at a point of crisis, with the potential for inaccurate information, for example, cardiac arrest, the most time-critical condition, is correctly identified in only 76.7% of cases using this system.12 MPDS sorts calls into 36 broad chief complaint categories based on responses to key questions. Each chief complaint can contain a wide variety of possible illnesses or injuries, each requiring different clinical management.13 MPDS-coded data therefore do not provide clinically meaningful case classifications for research on ambulance demand. To support and facilitate clinically meaningful research, data derived from a more accurate and comprehensive understanding of ambulance deployment based on actual health conditions are needed. One way to collect such data is to develop systems that include the paramedic assessment of the patient.
Some previous research has used paramedic assessment to classify attendance. However, taken together, studies using what are described as ‘a system devised by the authors’ to categorise paramedic assessment fail to deliver a standard, validated, reliable method of classification. Each study method uses a different number of categories with different headings and there is very little detail about what cases were placed in each category.6–11 These systems lack methodological rigour, which precludes reliable comparison across studies.
The ICD-10-AM is the Australian modification of the internationally recognised standard diagnostic classification tool for epidemiological, health management and clinical purposes, the International Classification of Disease, 10th revision (ICD-10). The ICD-10-AM is widely used for analysis of the general health of population groups in Australia, including monitoring of incidence and prevalence of diseases and other health problems.15 Coding of ambulance data using ICD-10-AM would allow for comparison of not only ambulance service users but also other population groups. This data linkage would have broad potential use in the health and research communities.
ICD-10-AM-coded data can be sorted into one of 23 major diagnostic categories (MDC) and one pre-MDC.16 MDC is a complimentary categorisation system to ICD-10-AM. Each MDC corresponds to a body system or aetiology, generally associated with a particular medical speciality.16 This provides a standard, reproducible number of categories for analysis.
ICD-10-AM requires a diagnosis for accurate classification. When it comes to the classification for epidemiological analysis, ambulance patient care records are limited as they do not include a definitive ‘diagnosis’ because of lack of access to definitive testing such as laboratory testing and radiography. Instead only a ‘final assessment’ of the patient’s clinical presentation is typically recorded. Although it may be possible to obtain ICD-10-AM coding for ambulance cases from linked hospital data, only 80% of patients assessed and treated by paramedics are transported to hospital. Therefore, relying on hospital coding for patients attended by ambulance services would result in an incomplete ambulance dataset.
Ambulance services need a tool for retrospective coding of paramedic assessment data so that analysis of their databases can be used to provide an evidence base to inform ambulance practice. Coding from data available at the point-of-call (e.g. MPDS) might not accurately reflect ambulance demand or have the level of accuracy required for analysis due to the limitations discussed above.12,13 Better information might come from using data derived after paramedic assessment but no standardised system exists for coding and categorising this data for analysis. The ICD is internationally recognised, reliable and comprehensive. However, it relies on a definitive diagnosis not readily available in the prehospital setting. It is not known if it can be applied retrospectively to large datasets for research and quality-improvement purposes.
This paper aims to examine whether an adaptation of the ICD-10-AM system can be applied retrospectively to paramedic assessment data from an ambulance dataset, with a view to developing more fine-grained, clinically relevant case definitions than are available through MPDS-coded point-of-call data.
Methods
The study setting was Melbourne, Australia, which has an area of 10 000 km2 and a population of 4.16 million. The emergency medical service (EMS) for Melbourne is a two-tiered medical response system. There are >1000 ambulance paramedics authorised to practice some advanced life support as well as >400 mobile intensive care ambulance paramedics. Five steps were involved in applying ICD-10-AM codes to data obtained from Ambulance Victoria, the EMS covering metropolitan Melbourne, Australia.
Extraction of the data from the data warehouse
All patients attended by EMS in Melbourne, Australia have patient care data collected and recorded in an electronic patient care record, known as VACIS®, that was developed to capture clinical information on cases attended by ambulances in Victoria. All cases of EMS attendance in metropolitan Melbourne, Australia were obtained from the Ambulance Victoria data warehouse for the period 1 January 2008 to 31 December 2011. VACIS® includes a variety of case-related information, and is designed as a database for monitoring and improving practice. For the purposes of this study the data extracted included the age and gender of the patient, MPDS dispatch code, final primary assessment (FPA), cause (CN) and whether the patient was transported to hospital. The dataset comprised 1 203 803 cases.
The variables FPA and CN were selected from the records as they represent the paramedic assessment of the patient. FPA is defined as the final assessment of the patient after a full history and examination, CN is defined as the cause of the injury or illness. In the VACIS® system FPA is multiple choice with 205 choice categories. CN is multiple choice with 282 choice categories.
Converting FPA to an ICD-10-AM code
The FPA was aligned with ICD-10-AM codes using the ‘ICD-10’ coding system. Coding involved finding an exact word match for the FPA category or the closest possible meaning. The coding was completed by the first author and checked by a hospital- based coding and case-mix manager and using the ICD-10-AM coding program 3M™ Codefinder™. The FPA and associated ICD-10-AM codes are listed in Table 1.
Four out of the 205 FPA choices could not be converted to standard ICD-10-AM codes. These were ‘other’, ‘unknown’, ‘no problem identified’ and ‘asymptomatic’. The largest non-codable FPA was ‘other’. Cases are listed as ‘other’ in VACIS® when paramedics cannot find an accurate final assessment. The condition is then described in a free-text section of the electronic case sheet but the FPA is listed as ‘other’. This occurs with less-common diseases and conditions. Due to logistical constraints of working with a large dataset there was no searching of the free-text fields associated with the ‘other’ final assessment. The second FPA that could not be coded was ‘unknown’. This is assigned when the ambulance crew attends the patient but is unsure what the problem is, such as when the patient states they are ‘not quite right’ or ‘feel unwell’ and wish to go to hospital.
Sometimes an ambulance is requested and attends a scene where no-one requires medical attention. Preliminary analysis showed that 4.17% of ambulance requests were not for a medical or traumatic condition but for some other cause such as standing by with police or fire at a potential incident or siege, false alarms, hoax calls or being called to road incidents where all the people at the scene decline ambulance assistance and assessment. These cases have a FPA code of ‘no problem identified’ or ‘asymptomatic’. There was no corresponding ICD-10-AM code so four extra codes were added to classify these cases.
Grouping of ICD-10-AM codes into MDC
There are 23 MDC and one pre-MDC. These relate to single organ systems or aetiologies as well as an ‘unassignable’ category and a ‘factors affecting health status’ category.
ICD-10-AM codes were converted into MDC using the Australian Refined Diagnosis Related Groups Definitions manual.16 There were cases where the ICD-10-AM could be coded into multiple MDC, one being a body system and the other being an infectious cause. In these cases, as the infective causative agent was not known, the body system MDC was chosen.
Cases where the FPA was recorded as ‘other’ or ‘unknown problem’ were placed in the ‘unassignable’ MDC.
The two added categories of ‘no problem identified’ and ‘asymptomatic’ represent cases where there was no medical problem, so a MDC classification could not be given. These were placed in their own category. This resulted in 25 categories (24 MDC standard categories and one of ‘no problem identified’).
Addition of CN to ICD-10-AM code
The ICD-10-AM codebook includes a chapter that contains codes relating to symptoms, signs or ill-defined conditions that do not indicate a classifiable diagnosis. The absence of specific diagnostic aids such as X-ray and biochemistry means that symptom-only FPA are common in our dataset. These include back pain, abdominal pain, dizziness, nausea, vomiting, rash, cramps and fever. Once converted, symptom-only ICD-10-AM codes are categorised into general body system MDC. However, some codes are too vague to be coded into general body system MDC and are coded into the specific MDC ‘factors affecting health status’. These include pain, weakness, social problem and deceased. Minimising the number of cases assigned to symptom-only codes will lead to a more precise picture of ambulance demand.
We examined whether the addition of a cause classification to the FPA would alter the ICD-10-AM code from a symptom-only code to a more specific code. All symptom-only FPA were checked against the CN. Recoding was considered if there was a minimum of 1000 cases affected. The 1000-record threshold was chosen as, although this represented only 0.01% of the sample, it was considered a large enough sample of cases to warrant recoding.
The codes that were changed were:
-
Post-loss of consciousness/unconscious and altered conscious state were recoded to intracranial injury if CN was traumatic.
-
Post-loss of consciousness/unconscious, altered conscious state, psychiatric episode and nausea and vomiting were recoded to a mental and behavioural disorder due to alcohol/drugs if CN was overdose/exposure to alcohol or drugs.
-
Short of breath was recoded to cardiac failure if CN was cardiac.
Coding of trauma cases to the external causes of injury codes
ICD-10-AM external cause of injury codes are a supplementary set of codes for classifying injury cause. Trauma cases can be coded using these external cause codes as well as the standard ICD-10-AM codes based on FPA. CN was recoded into external cause of injury.
Categorisation of the dataset was performed using both external cause of injury and MDC. Trauma cases were categorised by the external cause code, medical cases were categorised by MDC.
Statistical analysis
All data were entered into a Stata datafile (Version 11.2; Stata Corporation, College Station, TX, USA). Variables were described in tabular form using frequencies, percentages and cumulative percentages.
Results
Table 2 shows the number and percentage of cases in each of the MDC. The highest number of cases was in the circulatory system MDC followed by injury, poisons and toxic effects of drugs. Symptom-only codes constituted 383 432 cases or 31.85% of the dataset, with most of these codes being categorised into a MDC aligned with a general body system. The symptom-only codes that were too vague to be coded into a general body system were categorised under the ‘factors affecting health status’ MDC and constituted 8.01% of the dataset. Unassignable codes (other, unknown problem) constituted 9.24% of the dataset and no problem/asymptomatic codes made up 2.38%.
Table 2 also shows the number and percentage of cases in each MDC after recoding due to CN. The addition of CN did reduce the percentage of symptom-only coded cases by 2.25% and changed the distribution of cases among the MDC, especially in the MDC of injury and alcohol and drug use. However, the number of cases in the MDC of ‘factors affecting health status’ did not change.
Table 3 shows the data coded using different methods for medical cases versus trauma cases. Trauma cases were categorised by the external cause code, medical cases were categorised by MDC. The percentage of cases coded to symptom-only codes was 25.73% due to the recoding of symptoms such as pain to the cause of the injury. This also led to a reduction in the most vague symptom-only codes, those in the MDC of ‘factors affecting health status’, which went from 8.01 to 5.91% of the total dataset. The MDC ‘unassignable’ and ‘no problem/asymptomatic’ also reduced in number because, even though the ICD-10-AM code was ‘other’ or ‘no problem’, the cause could be coded as an external cause of injury.
Although it might be tempting to just code trauma cases to an external cause of injury, it is important to code data into a primary ICD-10-AM code as well. This allows for the impact of the trauma to be analysed. This is demonstrated by an example in Table 4. This table shows that the two most common injuries after a bicycle collision are a fracture and graze/abrased skin.
Table 5 shows the calls prioritised to the MPDS version 11.3 category of ‘unconscious’ and subcategories ‘unconscious−unconscious’ and ‘unconscious−not alert’ with the associated final assessment by paramedics as an ICD-10-AM code. This table highlights the fine-grained, clinically relevant case definitions obtained by using paramedic assessment compared with data obtained from point-of-call. For example, the treatment and resources required for a patient suffering a hypoglycaemic episode are very different to those needed for a patient suffering a loss of consciousness due to an arrhythmia, stroke patients have different clinical needs to patients with a gastrointestinal problem, but these differences would be missed when examining point-of-call data alone.
Error: Incorrect filename or format (AH13163_T5.gif). Please check out
ICD-10-AM coding
Category 31 (%) n = 87 790
Subcategory 31D1 (%) n = 13 712
Subcategory 31D3 (%) n = 27 857
Unconscious
Unconscious − unconscious
Unconscious − not alert
Collapse/faint
26.23
12.95
25.75
Other
7.08
7.04
5.39
Dizzy/vertigo
4.85
0.79
2.79
Altered conscious state
4.15
10.25
6.26
Hypotension
3.75
1.93
4.18
Post loss of consciousness/unconscious
3.55
7.04
3.48
Gastrointestinal problem
2.78
0.74
2.28
No problem identified
2.63
4.13
3.16
Unknown problem
2.29
2.55
2.37
Arrythmia
2.11
0.83
1.73
Stroke
2.05
4.84
2.64
Pain
1.86
0.99
1.43
Nausea and vomiting
1.79
0.63
1.67
Post ictal
1.54
3.39
2.28
Drug intoxication
1.53
5.85
1.63
Abdominal pain
1.44
0.64
1.25
Anxiety
1.40
0.89
1.05
Stimulant use
1.37
4.62
1.72
Hypoglycaemia
1.22
2.07
1.22
Cardiac arrest
0.67
2.72
0.42
Other ICD-10-AM codes
25.71
25.11
27.30
Total
100
100
100
Discussion
Ambulance services have a wealth of data that could be analysed to inform development of the best treatment and transport options as well as public health service provision. There is no standard method of coding and classifying paramedic assessment data in ambulance datasets. ICD-10 is the worldwide standard for coding of disease and injury for epidemiological analysis. The aim of this paper was to develop a standardised method to adapt the ICD-10-AM coding system so that it can be reliably applied to paramedic assessment data in large ambulance datasets. The method used in this study is a reproducible method for sorting ambulance data into manageable categories for analysis allowing comparisons with other ambulance services and health providers. It is useful for the coding of large datasets where the logistical constraint of working with large numbers precludes the investigation of individual cases.
Some challenges were encountered when converting ambulance cases to ICD-10-AM. As the level of information became less specific, coding became more problematic in two ways. First, our dataset contained a substantial proportion of cases coded with symptom-only codes. The addition of ambulance ‘cause’ to certain ICD-10-AM symptom-only codes improved categorisation, especially those in the MDC of injury and alcohol and/or other drug use. Second, although most assessments could be converted into a diagnostic ICD-10-AM code, there were challenges when the data related to cases with an FPA of ‘other’ or ‘unknown’. These could not be coded into ICD-10-AM codes and extra codes had to be added.
Presenting the data in different ways for medical and trauma cases further reduced the number of cases that were symptom-only codes and cases that could not be properly coded or categorised. Using a combination of ICD-10-AM codes for medical cases and external cause of injury codes for trauma cases vastly reduced the number of cases categorised in non-specific categories (i.e. ‘factors affecting health status’, ‘unassignable’ and ‘no problem/asymptomatic’).
This study also compared point-of-call data with paramedic assessment data in relation to the ‘unconscious’ dispatch category. Point-of-call data is one of the most commonly used information sources for assessment of ambulance demand and performance. Point-of-call data are reliant on the lay person caller rather than trained paramedics. Further, the coding system (MPDS) used at the point-of-call is designed to target resource allocation and case prioritisation rather than provide any clinical diagnosis. Although point-of-call information is an easily attainable source of data, our study shows that final assessments by paramedics can be used to generate more fine-grained, clinically relevant case definitions that are relevant to resource allocation and service planning. Using paramedic assessment data that are coded and categorised using an internationally recognised standard method means that research using these data will not only inform practice at Ambulance Victoria but can also underpin comparisons with other ambulance services and population groups.
Study limitations
This study had some limitations. The translation of ambulance data into ICD-10-AM data was imperfect. There was no record review to determine the accuracy of the FPA or cause as recorded by paramedics; however, the size of the dataset would obscure single case errors, so this is not likely to have had a major impact on the results. A percentage of cases can’t be coded as they lack FPA or are coded as ‘other’ or ‘unknown’. This is a limitation of the dataset, and further work is required to determine an easy method for exploring and sorting information contained within free-text fields in the current VACIS® system, particularly the main free-text field ‘case description’. The proportion of cases coded as ‘other’ or ‘unknown’ should be monitored as they represent a lost data opportunity and may impact on demand-management analyses.
Conclusion
Ambulance paramedic assessment data can be aligned with ICD-10-AM and MDC categories with relative ease, allowing retrospective coding of large datasets. Coding of ambulance data using ICD-10-AM allows for comparison of not only ambulance service users but also other population groups. Representation of ambulance case types using ICD-10-AM-coded information obtained after paramedic assessment has more fine-grained, clinically relevant case definitions than point-of-call data using MPDS coding, which is based on caller information before ambulance attendance. Areas of further research include whether this adaptation of the ICD-10-AM coding system can be applied to data from other ambulance services, which would ensure the ease of applicability and reliability of the method and a determination of the accuracy of paramedic final assessment in relation to a more definite diagnosis.
Competing interests
KC, AM and KS were all employees of Ambulance Victoria at the time of manuscript preparation and submission. Ambulance Victoria had no direct input into the design, analysis and conduct of the project.
Acknowledgements
The authors would like to thank Tracy Burgess, Manager Coding and Casemix Services, Alfred Health for her assistance. The authors gratefully acknowledge the contribution to this work of the Victorian Operational Infrastructure Support Program. Paul Dietze is the recipient of an ARC Future Fellowship. Michael Livingston is a recipient of an NHMRC Early Career Research Fellowship.
References
[1] Cantwell K, Morgans A, Dietze P, Smith K. Ambulance demand: random events or predictable patterns? Emerg Med J 2013; 30 883–7.| Ambulance demand: random events or predictable patterns?Crossref | GoogleScholarGoogle Scholar | 23184922PubMed |
[2] Cusimano M, Marshall S, Rinner C, Jiang D, Chipman M. Patterns of urban violent injury: a spatio-temporal analysis. PLoS ONE 2010; 5 e8669
| Patterns of urban violent injury: a spatio-temporal analysis.Crossref | GoogleScholarGoogle Scholar | 20084271PubMed |
[3] Curry G, Damiani M, Davies G, Duncan E, Harding M, Jones K, et al. Tackling demand together: a framework for improving urgent and emergency care pathways by understanding increases in 999 demand. London: Department of Health; 2009.
[4] Deakin C, Thompson F, Gibson C, Green M. Effects of international football matches on ambulance call profiles and volumes during the 2006 World Cup. Emerg Med J 2007; 24 405–7.
| Effects of international football matches on ambulance call profiles and volumes during the 2006 World Cup.Crossref | GoogleScholarGoogle Scholar | 17513536PubMed |
[5] Dean S. Why the closest ambulance cannot be dispatched in an urban emergency medical services system. Prehosp Disaster Med 2008; 23 161–5.
| 18557296PubMed |
[6] Keskinoglu P, Sofuoglu T, Ozmen O, Gunduz M, Ozkan M. Older people’s use of pre-hospital emergency medical services in Izmir, Turkey. Arch Gerontol Geriatr 2010; 50 356–60.
| Older people’s use of pre-hospital emergency medical services in Izmir, Turkey.Crossref | GoogleScholarGoogle Scholar | 19573934PubMed |
[7] Manfredini R, La Cecilia O, Boari B, Steliu J, Michelini V, Carli P, et al Circadian pattern of emergency calls: implications for ED organisations. Am J Emerg Med 2002; 20 282–6.
| Circadian pattern of emergency calls: implications for ED organisations.Crossref | GoogleScholarGoogle Scholar | 12098172PubMed |
[8] Murdock T, Knapp J, Dowd D, Campbell J. Bridging the Emergency Medical Services for children information gap. Arch Pediatr Adolesc Med 1999; 153 281–5.
| Bridging the Emergency Medical Services for children information gap.Crossref | GoogleScholarGoogle Scholar | 1:STN:280:DyaK1M7osVaisg%3D%3D&md5=0f958af6e3f3a1a4d0289c78d8703b9eCAS | 10086406PubMed |
[9] Pandey A, Ranjan R. Emergency (108) calls to the ambulance service in the state of Gujarat (India) that do not result in the patient being transported to hospital: an epidemiological study. Internet J Rescue Disaster Med. 2010; 9
[10] Vargas Román M, de Miguel A, Garrido P, Alvarez J. Epidemiologic intervention framework of a prehospital emergency medical service. Prehosp Emerg Care 2005; 9 344–54.
| Epidemiologic intervention framework of a prehospital emergency medical service.Crossref | GoogleScholarGoogle Scholar |
[11] Victor C, Peacock J, Chazot C, Walsh S, Holmes D. Who calls 999 and why? A survey of the emergency workload of the London Ambulance Service. J Accid Emerg Med 1999; 16 174–8.
| Who calls 999 and why? A survey of the emergency workload of the London Ambulance Service.Crossref | GoogleScholarGoogle Scholar | 1:STN:280:DyaK1M3otFejtQ%3D%3D&md5=314aafa31aeb5dc61fe496c0753aa678CAS | 10353041PubMed |
[12] Flynn J, Archer F, Morgans A. Sensitivity and specificity of the Medical Priority Dispatch System in detecting cardiac arrest emergency calls in Melbourne. Prehosp Disaster Med 2006; 21 72–6.
| 16770995PubMed |
[13] Clawson J, Barron T, Scott G, Siriwardena A, Patterson B, Olola C. Medical Priority Dispatch Systems Breathing Problems Protocol Key Question Combinations are associated with patient acuity. Prehosp Disaster Med 2012; 27 375–80.
| Medical Priority Dispatch Systems Breathing Problems Protocol Key Question Combinations are associated with patient acuity.Crossref | GoogleScholarGoogle Scholar | 22824188PubMed |
[14] National Centre for Classification in Health. The international statistical classification of diseases and related health problems, 10th revision, Australian Modification (ICD-10-AM). 7th edn. Sydney: National Centre for Classification in Health, University of Sydney; 2009.
[15] World Health Organization. International Classification of Diseases (ICD). Geneva: World Health Organization; 2012; Available at http://www.who.int/classifications/icd/en/ [verified 8 October 2012]
[16] Department of Health and Aging. Australian refined diagnosis related groups definitions manual. Centre NCaC, editor. Wollongong: Department of Health and Aging; 2008.