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Sustainability of Cardiac Imaging

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Abstract

Medical imaging is the largest controllable source of radiation exposure in the population of industrialised countries – totalling around 150 chest X-rays per head per year. Of these exposures, one half comes from cardiovascular testing (cardio-computed tomography [CT], nuclear cardiology and interventional cardiology). The high level of radiation exposure provides immense benefits when appropriate, but may result in an increased incidence of radiation-induced cancer in the not-too-distant future. Current estimates suggest that about five to 10 % of all cancers may be due to medical radiation exposure. Of every three examinations, one is inappropriately prescribed (lack of justification) and another is performed with inappropriately high radiation doses (lack of optimisation). Cardiologists are often unaware of the radiological dose of the examination they prescribe or practice, but they should make every effort so that “each patient should get the right imaging exam, at the right time, with the right radiation dose”, as suggested by US Food and Drug Administration (FDA) in the 2010 initiative to reduce unnecessary radiation exposure from medical imaging. This is best obtained through a systematic implementation of the ‘3A’s strategy’ proposed by the International Atomic Energy Agency in 2011: audit (of true delivered dose); appropriateness (since at least one-third of examinations are inappropriate); awareness (since the knowledge of doses and risks is largely suboptimal in doctors and patients). A good cardiologist cannot be scared of radiation, but must always remain aware of the risks.

Keywords

Appropriateness, cancer, radiation, risk,

Disclosure:The author has no conflicts of interest to declare.

Received:

Accepted:

DOI:https://doi.org/10.15420/ecr.2011.7.3.167

Correspondence Details:Eugenio Picano, Director, Institute of Clinical Physiology, National Research Council, Via Moruzzi, 1, 56124 Pisa, Italy. E: picano@ifc.cnr.it

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Sources of Radiation Exposure

Radiation used in medical examinations and tests is the largest man-made source of radiation exposure. The biological effects of the radiation dose received is expressed in milliSievert (mSv), with the effective dose of 1 mSv corresponding to the radiation dose of 50 chest X-rays. An average of 2.4 mSv per head per year comes from natural sources (see Figure 1).1 The medical sources of radiation were about one-fifth of the natural radiation in 1987, exceeded natural background in the radiological year 2006 and are still rising at a rate of 10 % per year.2 Computed tomography (CT) and interventional cardiology/radiology accounted for 24 and 7 % of overall (6.2 mSv per year) exposure (summing up natural, medical and industrial or military exposure).3 In absolute terms, the contribution per capita per year of interventional cardiology alone was 0.44 mSv (24 chest X-rays) in 2006. Radiation is a proven carcinogen4 and medical exposure to ionising radiation may elevate a person’s lifetime risk for developing cancer.5 Of all nuclear medicine diagnostic exposures (yellow part of the bar in Figure 1), 83 % come from nuclear cardiology. The attributable cancer risk of contracting cancer from medical radiation is estimated to be around 5–10 %,6,7 with approximately 29,000 future cancers (2 % of all cancers) in the US related to CT scans.8 A balanced public health approach seeks to upport the benefits of these often life-saving medical imaging exams while minimising risk.9

The Contribution of Cardiology to Global Radiological Exposure

In adult cardiology, patients, interventional cardiology procedures account for 12 % of examinations and 48 % of the total collective dose (see Figure 2).10 In patients with acute myocardial infarction, diagnostic cardiac catheterisation and percutaneous coronary interventions contribute for 67 % of average cumulative radiation exposure for acute myocardial infarction.11

In children with congenital heart disease, invasive radiology (with diagnostic and interventional catheterisation) accounts for 6 % of all radiological examinations and 84 % of the collective dose, in a study carried out in an Italian paediatric hospital.12 In both adult and paediatric heart patients, the cumulative cardiological exposure is significant, in the range of 60 mSv (3,000 chest X-rays) per hospital admission in adults.10

The number of professionally exposed subjects in the catheter laboratory also continues to rise. According to 2008 United Nations Scientific Committee of the Effects of Anatomic Radiation (UNSCEAR) estimates, the number of occupationally exposed workers totals 22.8 million (plus military personnel) and 7.35 million of these are medical workers.13 Cardiac catheter laboratory staff (physicians, nurses and technicians) are progressively more represented, with higher values of exposure: 10 % of monitored population, 31 % of those with exposure >1 mSv and 67 % of workers with yearly exposure >6 mSv in the Tuscany region of Italy.14

Recommendations of Regulatory Bodies and Scientific Societies on Unnecessary Radiation Exposure

Advances in imaging technology have led to an explosive growth of the performance of cardiovascular imaging and interventional fluoroscopy. This growth is challenging since it may lead to overuse or inappropriate use of new technologies. This implies potential harm for patients undergoing imaging (who take the risks of an imaging study without a commensurate benefit), excessive delay in the waiting lists for other patients needing the examination and an exorbitant cost for society, with no improvement and possibly with poorer care quality.15 As recommended in April 2010 by the US President’s Cancer Panel, all possible action should be taken by healthcare providers to minimise radiation exposure from medical sources, recognised as one of the six major causes of environmental cancer. These principles should be applied universally in clinical practice and more strictly in the medical environment, where the dose and the risk are highest – such as in cardiac imaging and interventional cardiology. Cardiologists have considerable power to abate the concentration of X-ray carcinogens that pollute the catheterisation laboratory and “needlessly increase healthcare costs, cripple our nation’s productivity and devastate our lives.”16

The risk of cancer, more so than the far smaller risk of severe hereditary disorders, is at the core of the radiation protection system for staff and patients. At low levels of radiation exposure, radiation damage is stochastic or statistical in nature; it is possible to predict the proportion of a given population of exposed patients who will be affected, but impossible to predict beforehand which particular individuals will succumb. The likelihood of inducing the effect, but not the severity, increases in relation to dose and may differ among individuals.17,18

The current risk estimates are based on several authoritative reports: International Commission on Radiographical Protection-103 (ICRP-103), UNSCEAR 2008 and the Seventh Report of the committee to Assess Health Risks from Exposure to Low Levels of Ionizing Radiation (Biological Effects of Ionizing Radiation [BEIR] VII report).1,4,19 These are estimates – not fears – and are based on more than 100,000 studies, including studies of 87,000 Hiroshima and Nagasaki atomic bomb survivors and 407,000 nuclear power industry workers. The epidemiological evidence linking increased cancer risk to radiation exposure is now considered conclusive for a dose level above 100 mSv (which is sometimes reached by a patient in a single hospital admission and possibly even with a single test, such as multiphase abdominal computed tomography). ICRP and BEIR VII endorsed the linear no-threshold model, accepting therefore that there is no safe dose and the greater the dose, the higher the risk. For any given radiation exposure, the cancer risk is higher in females (+38 %) than males at all ages, three- to four-fold higher in children than adults and 50 % lower in an 80-year-old compared with a 50-year-old person (see Figure 3).20 The radiation-induced cancer is clinically undistinguishable from a spontaneously occurring cancer. The risk is low, and certainly outweighed by the benefit if the procedure is appropriate, but not negligible. If 100 subjects are exposed to 100 mSv (corresponding to 5,000 chest X-rays), 42 will have a spontaneous cancer (independently of radiation exposure) and one will have a radiation-induced cancer (Figure 4). These estimates still have a considerable margin of uncertainty, with a 2–3 confidence interval (CI) of attributable risk estimates. The mostly accepted range of uncertainty is one in 30 to one in 300.

Several genetic, environmental and dietary variables can affect the variability of damage observed to any given level of radiation and current research is targeting shifting epidemiology estimates to personalised measures of DNA and chromosomal damage21,22 focused on identifying inter-individual differences that could modulate radiation risks in order to obtain better estimates of the extent of the differences.23,24 Radiation-associated chromosomal damage in interventional cardiologists is amplified by smoking and by genetic polymorphisms of genes involved in DNA repair.18 If the risk is personalised, it will be possible to implement tailored preventive and chemopreventive strategies.

Doses of Common Procedures

The effective dose for a radiological investigation provides a rough estimate related to the total radiation risk, no matter how the radiation dose is distributed around the body, provided that the representative patients or patient populations for which the effective doses are derived are similar with regard to age and sex. Typical effective doses for common cardiological testing are reported in Table 1.15,25–27

Typical effective doses for some common diagnostic radiology procedures range from a factor of about 1,000 from the equivalent of one to two days of natural background radiation (e.g. 0.02 mSv for a chest radiography) to the equivalent of several years (e.g. for abdominal CT). Within the same procedure, for instance, percutaneous coronary intervention or cardiac CT, the dose ranges over a factor of 10 for patients28,29 and – for interventional cardiology – for staff.30 Physicians should be made aware of the exposures they deliver to their patients and how they compare to established norms.17

How to Improve the Radiological Climate in Cardiology

The International Atomic Energy Agency recently launched a campaign to increase justification of radiological examination using the ‘3A’s strategy’: awareness, appropriateness and audit.31 This strategy deployed in the cardiac imaging or catheterisation laboratory has the potential to yield surprising safety dividends. In the US, the issue of radiological responsibility was addressed with the ‘Image Gently, Step Lightly’ campaign, which focused on the risks of unnecessary and excessive medical radiation from CT imaging and interventional radiology administered to our paediatric patients32 – in whom radiation damage is most severe.

Extensive data show substantial unawareness of radiological doses and risks, not only of patients but also of prescribing and practicing doctors. Results of recent surveys show that most doctors grossly underestimate the radiation doses (usually by up to 500 times) and the corresponding cancer risks for most commonly requested tests.33,34 About 80 % of interventional cardiology fellows did not know their own radiation exposure.35 However, radioprotection knowledge is the best shield against unnecessary radiation exposure for both doctors and patients.

Some of the potential damage in patients and professionally exposed staff is obviously unavoidable due to the high radiation burden of the procedures, with the operator close to the radiation source and, not infrequently, with the patient in clinically critical condition. However, another part of the exposure is avoidable and is due to exposure deriving from inappropriate instructions and lack of implementation of safety principles in the catheterisation or cardiac imaging laboratory.

Audit Doses (of Laboratory and Operators)

As dose is determined both by physician-operator behaviour and by variables outside the operator’s control, it is impossible to identify a value that denotes a boundary between appropriate and inappropriate practices. Few data are available that permit benchmarking for these parameters. However, we know that for the same procedure in the same laboratory dose variations can occur that are up to 10 times the median value. This means that the use of ‘reference value’ for dose reconstruction doses is not appropriate for individual patients or procedures. Each laboratory and each operator should very carefully assess his/her standing for a given examination compared with benchmark values. Only if you know what you are doing, and what your values are compared with your peers, can you improve your radioprotection performance.

Appropriateness of Procedures – The Justification Principle

Various professional organisations, including the American College of Cardiology (ACC) and the European Society of Cardiology (ECS), have developed and are working to disseminate imaging referral criteria called ‘appropriateness criteria’.38 Existing criteria for appropriate ordering of medical imaging exams have not yet been broadly adopted by the practicing medical community and according to recent estimates, 30–50 % of all examinations are partially or totally inappropriate, i.e. risks and costs outweigh benefits. The acute and long-term risks of a cardiac imaging or of an interventional procedure are the same, whether it is appropriately or inappropriately performed. In 2010, the US Food and Drug Administration (FDA) recommended supporting various professional organisations, including the American College of Radiology (ACR) and the American College of Cardiology (ACC), in their effort to develop and adopt appropriate use criteria for interventional fluoroscopy. They suggested that an electronic FDA decision support tool for ordering imaging procedures could incorporate these criteria to improve quality and consistency in clinical decision-making.

This crucial aspect remains an important field for a proactive role in scientific societies. At least in Europe, this striving for appropriateness is also propelled by the law, which clearly states that “if an exposure cannot be justified, it should be prohibited” (articles 3 of Euratom 97/43 directive) and (article 5) that “both the prescriber and the practitioner are responsible for the justification of the test exposing the patient to ionizing radiation”. Any responsible prescription of ionising tests should strictly adhere to the principle of justification.

Technological Advances

Following the principle of keeping radiation dose as low as reasonably achievable (ALARA), recently the imaging industry focused on the ‘dose war’, which involves attempts to maintain the same diagnostic power with the lowest possible dose (see Figure 5). For instance, in nuclear medicine the high (20–40 mSv) dose of Thallium perfusion imaging was substantially reduced with technetium tracers such as Sestamibi (9–11 mSv), more recently coupled with new reconstruction algorithms, by introducing stress-only protocols and by implementing semiconductor detectors into latest generation gamma cameras allowing massive scan shortening or dose reduction. Even more substantial reduction (up to 2–3 mSv) can be achieved with N-13 ammonia stress/rest with PET imaging.39 Similar striking dose reduction has been achieved in CT coronary angiography, with several strategies such as automated exposure control, electrocardiographically controlled tube modulation and reduced tube voltage (from 120 to 100 KV) in non-obese patients. Very recent introduction of high-pitch spiral scanning has enabled to lower radiation dose to <1 mSv.39 In interventional cardiology, the cultural aspect of radioprotection is as equally important as technological advances. A reduction of 90 % of occupational doses has been achieved simply by a training programme in radioprotection.36–37 In cardiac radiofrequency ablation, the dose exposure fell from 15 mSv to near zero radiation exposure with non-fluoroscopic navigation techniques.

Conclusions

One of the most important ethics of practicing medicine is primum non nocere, and so it is incumbent upon us to strive for better ways to minimise radiation and its consequent risks. The cultural approach of ignoring or minimising long-term cancer risks linked to the use of ionising radiation has led to serious, avoidable health damage for patients, invasive cardiologists and staff. Now it is becoming increasingly clear that the long-term radiation-induced cancer risk should be included in the ‘risk’ side of the risk–benefit balance of our medical acts and therefore a clear perception of the radiation issue is vital for both patients and doctors. Effective radiation exposure per episode of care represents a potential safety metric for patients with common clinical conditions. A good cardiologist – and even more so, a good imaging or interventional cardiologist – cannot be scared of radiation, but must be very wary of radiation’s risks.

References

  1. UNSCEAR 2008 Report: Sources and effects of ionizing radiation. Volume I, 2008. Available at: www.unscear.org/docs/reports/2008/09- 86753_Report_2008_Annex_A.pdf (accessed 4 July 2011).
    Crossref | PubMed
  2. Picano E, Sustainability of medical imaging. Education and Debate, BMJ, 2004;328:578–80.
    Crossref | PubMed
  3. Mettler FA Jr, Bhargavan M, Faulkner K, et al., Radiologic and nuclear medicine studies in the United States and worldwide: frequency, radiation dose, and comparison with other radiation sources – 1950–2007, Radiology, 2009;253:520–31.
    Crossref | PubMed
  4. Committee to Assess Health Risks from Exposure to Low Levels of Ionizing Radiation. Health risks from exposure to low levels of ionizing radiation: BEIR VII Phase 2. Washington, DC: The National Academies Press; 2006. Available at: www.nap.edu/openbook.php?isbn=030909156X (accessed 27 November 2010).
  5. White Paper: Initiative to Reduce Unnecessary Radiation Exposure from Medical Imaging. Food and Drug Administration. Initiative to reduce unnecessary radiation exposure. Available at: www.fda.gov/RadiationEmittingProducts/RadiationSafety/Rad iationDoseReduction/ucm199904.htm (accessed 4 July 2011).
  6. Berrington de González A, Darby S, Risk of cancer from diagnostic X-rays: estimates for the UK and 14 other countries, Lancet, 2004;363:345–51.
    Crossref | PubMed
  7. Picano E, Risk of cancer from diagnostic X-rays, Lancet, 2004;363:1909–10.
    Crossref | PubMed
  8. Berrington de González A, Mahesh M, Kim KP, et al., Projected cancer risks from computed tomographic scans performed in the US in 2007, Arch Intern Med, 2009;169:2071–7.
    Crossref | PubMed
  9. Food and Drug Administration. 2010. Available at: www.fda.gov/Radiation-EmittingProducts/RadiationSafety /RadiationDoseReduction/ucm199994.htm (accessed 4 July 2011).
  10. Bedetti G, Botto N, Andreassi MG, Traino C, et al., Cumulative patient effective dose in cardiology, Br J Radiol, 2008;81:699–705.
    Crossref | PubMed
  11. Kaul P, Medvedev S, Hohmann SF, et al., Ionizing radiation exposure to patients admitted with acute myocardial infarction in the United States, Circulation, 2010;122:2160–9.
    Crossref | PubMed
  12. Ait-Ali L, Andreassi MG, Foffa I, et al., Cumulative patient effective dose and acute radiation-induced chromosomal DNA damage in children with congenital heart disease, Heart, 2010;96:269–74.
    Crossref | PubMed
  13. UNSCEAR Report 2008 – Volume I. Sources and Effects of Ionizing Radiation, Report to the General Assembly with Scientific Annexes. Available at: www.unscear.org/docs/ reports/2008/09-86753_Report_2008_Annex_B.pdf (accessed 27 November 2010).
  14. Venneri L, Rossi F, Botto N, et al., Cancer risk from professional exposure in staff working in cardiac catheterization laboratory: insights from the National Research Council's Biological Effects of Ionizing Radiation VII Report, Am Heart J, 2009;157:118–24
    Crossref | PubMed
  15. European Commission on Radiation Protection 118: Referral guidelines for imaging. Available at: http://ec.europa.eu /energy/nuclear/radioprotection/publication/doc/118_en.pdf (accessed 27 November 2010).
  16. President's Cancer Panel: Environmentally caused cancers are “grossly underestimated” and “needlessly devastate American lives”. Available at: www.environmentalhealthnews.org/ehs/news/presidentscancer- panel (accessed 4 July 2011).
  17. Hirshfeld, Jr, JW, Balter S, Brinker JA, et al., ACCF/AHA/HRS/SCAI Clinical Competence Statement on Physician Knowledge to Optimize Patient Safety and Image Quality in Fluoroscopically Guided Invasive Cardiovascular Procedures: A Report of the American College of Cardiology Foundation/American Heart Association/American College of Physicians Task Force on Clinical Competence and Training, Circulation, 2005;111:511–32.
    Crossref | PubMed
  18. Andreassi MG, Radiation risk from pediatric cardiac catheterization: friendly fire on children with congenital heart disease, Circulation, 2009;120:1847–9.
    Crossref | PubMed
  19. The 2007 Recommendations of the International Commission on Radiological Protection. Publication 103, Ann ICRP, 2007;37(2-4):1–332.
    PubMed
  20. Picano E, Informed consent and communication of risk from radiological and nuclear medicine examinations: how to escape from a communication inferno. Education and debate, BMJ, 2004;329:849–51.
    Crossref | PubMed
  21. Adams FH, Norman A, Bass D, Oku G, Chromosome damage in infants and children after cardiac catheterization and angiocardiography, Pediatrics, 1978;2:312–6.
    PubMed
  22. Andreassi MG, Ait-Ali L, Botto N, et al., Cardiac catheterization and long-term chromosomal damage in children with congenital heart disease, Eur Heart J, 2006;27:2703–8.
    Crossref | PubMed
  23. Beels L, Bacher K, De Wolf D, et al., gamma-H2AX foci as a biomarker for patient X-ray exposure in pediatric cardiac catheterization: are we underestimating radiation risks?, Circulation, 2009;120:1903–9.
    Crossref | PubMed
  24. Andreassi MG, Cioppa A, Botto N, et al., Somatic DNA damage in interventional cardiologists: a case-control study, FASEB J, 2005;19:998–9.
    PubMed
  25. Gerber TC, Carr JJ, Arai AE, et al., Ionizing radiation in cardiac imaging: a science advisory from the American Heart Association Committee on Cardiac Imaging of the Council on Clinical Cardiology and Committee on Cardiovascular Imaging and Intervention of the Council on Cardiovascular Radiology and Intervention, Circulation, 2009;119:1056–65.
    Crossref | PubMed
  26. Mettler FA Jr, Huda W, Yoshizumi TT, Mahesh M, Effective doses in radiology and diagnostic nuclear medicine: a catalog, Radiology, 2008;248:254–63.
    Crossref | PubMed
  27. Suzuki S, Furui S, Issiki T, et al., Patients' skin dose during percutaneous intervention for chronic total occlusion, Cath Cardiov Interv, 2008;71:160–4.
    Crossref | PubMed
  28. Kocinaj D, Cioppa A, Ambrosini G, et al., Radiation dose exposure during cardiac and peripheral arteries catheterisation, Int J Cardiol, 2006;113:283–4.
    Crossref | PubMed
  29. Smith-Bindman R, Is computed tomography safe?, N Engl J Med, 2010;363:1–4.
    Crossref | PubMed
  30. Vañó E, González L, Guibelalde E, et al., Radiation exposure to medical staff in interventional and cardiac radiology, Br J Radiol, 1998;71:954–60.
    Crossref | PubMed
  31. Malone J, Craven C, Guliera R, et al., Justification of diagnostic medical exposures, some practical issues. Report of an International Atomic Energy Agency (IAEA) Consultation, Br J Radiol, 2011; (Epub ahead of print).
    Crossref | PubMed
  32. Sidhu M, Goske MJ, Connolly B, et al., Image Gently, Step Lightly: promoting radiation safety in pediatric interventional radiology, AJR Am J Roentgenol, 2010;195:W299–301.
    Crossref | PubMed
  33. Lee CI, Haims AH, Monico EP, et al., Diagnostic CT scans: assessment of patient, physician, and radiologist awareness of radiation dose and possible risks, Radiology, 2004;231:39–8.
    Crossref | PubMed
  34. Correia MJ, Hellies A, Andreassi MG, et al., Lack of radiological awareness among physicians working in a tertiary-care cardiological centre, Int J Cardiol, 2005;103:307.
    Crossref | PubMed
  35. Kim C, Vasaiwala S, Haque F, et al., Radiation safety among cardiology fellows, Am J Cardiol, 2010;106:125–8.
    Crossref | PubMed
  36. Vaño E, Gonzalez L, Fernandez JM, et al., Occupational radiation doses in interventional cardiology: a 15-year follow-up, Br J Radiol, 2006;79:383–8.
    Crossref | PubMed
  37. Vano E, Radiation exposure to cardiologists: how it could be reduced, Heart, 2003;89:1123–4.
    Crossref | PubMed
  38. Brindis R, Douglas PS, President's page: The ACC encourages multi-pronged approach to radiation safety, J Am Coll Cardiol, 2010;56:522–4.
    Crossref | PubMed
  39. Kaufmann PA, Knuuti J, Ionizing radiation risks of cardiac imaging: estimates of the immeasurable, Eur Heart J, 2011;32:269–71.
    Crossref | PubMed
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