Editorial

BJC Open article

British Journal of Cancer (2013) 108, 2202–2204. doi:10.1038/bjc.2013.257 www.bjcancer.com
Published online 6 June 2013

Breast cancer screening: time to target women at risk

P Hall1 and D Easton2,3

  1. 1Department of Medical Epidemiology and Biostatistics, Karolinska Institutet, Nobels väg 12A, P.O. Box 281, SE-171 77 Stockholm, Sweden
  2. 2Strangeways Research Laboratory, Department of Oncology, University of Cambridge, Worts Causeway, Cambridge CB1 8RN, UK
  3. 3Strangeways Research Laboratory, Department of Public Health and Primary Care, University of Cambridge, Worts Causeway, Cambridge CB1 8RN, UK

Correspondence: Professor P Hall, E-mail: per.hall@ki.se

A short version of the Marmot et al (2013) report published in full in this issue of British Journal of Cancer was previously published in The Lancet (Independent UK Panel on Breast Cancer Screening, 2012) and criticised by authors of 10 letters published in The Lancet on 9th March 2013 (The Lancet, 2013). The authors of the letters argued that some studies in the meta-analyses were better than others, that advances in treatment reduces the effect of screening substantially, that cause of death was not correctly registered, that the report panel did not take background rates of breast cancer mortality into consideration, that they used an inappropriate follow-up period, that effect of mammography screening is an area of uncertainty, that many assumptions are needed, that estimates of overdiagnosis were too high or too low, that data were presented in favour of screening, that screening actually increases breast cancer mortality and many more remarks of similar kind. The authors of the report politely and correctly addressed each comment.

The surprising fact is not that a report on the pros and cons of mammography screening is challenged, but that we still discuss mammography screening as if it will never change and always stay the same. Normally when something is not working properly, we try to find ways of improvement. Most areas within oncology have developed quite dramatically over the years. Within breast cancer, therapeutic advances in radio-, chemo- and hormonal therapy has decreased recurrence rate and increased cause-specific survival. Over the last decade, antibodies have introduced the concept of targeted and individualised therapy. An oncologist would today never rely simply on an X-ray, but use CT, MRI, PET, etc for proper diagnostics and follow-up.

All medical interventions, diagnostic or therapeutic, should do more good than harm. In addition, they have to be cost effective and acceptable to society, patients and health-care providers. Suppose we agree that early detection of a disease is generally better than postponing diagnosis and therapy, and that this leads to a decrease in breast cancer mortality (estimated to be 20% by the review) and also to a significant rate of overdiagnosis (estimated 11%), it raises the following questions: how to make screening more efficient? Is it possible to increase sensitivity and specificity of the tests, to decrease the number of false positive and negative test results? How do we identify the fatal cancers? Could we find means to target those woman who are most likely to benefit from screening and avoid spending time and money on those in whom we merely induce anxiety? Questions like these are seldom heard in the screening debate.

Mammography is an imaging technique that is dependent on identifying a contrast between a malignant tumour and the surrounding normal breast tissue. Mammography screening has been used in more or less the same way over the past 40 years and very little has been done to increase efficiency. Age of entry into the programme and screening intervals are discussed, but most programmes assume that the risk of breast cancer is solely dependent on age, that is, a women will benefit equally from screening as long as she is within a certain age range. However, there are many other factors that determine a woman’s risk of breast cancer. Mammographic density is a comparatively simple measure of individual breast cancer risk. Mammographic density measures the proportion of non-fatty tissue in the breast – women with very dense breast have several times the risk of breast cancer compared to women with low density. Women with high mammographic density are in effect hit twice; they have a dramatically increased risk of breast cancer and, due to increased density, a lower likelihood of having a cancer detected. It therefore seems like an intuitive next step to move from age-based to risk-based screening only based on mammographic density and times are changing. US states have begun passing laws that requires clinicians to tell women if they have dense breasts or not. Under those laws, women with dense breast must be told that they have an increased risk of breast cancer and that a cancer can hide in the density. This should lead to additional screening tests such as ultrasound and MRI.

In addition, there are many other genetic and non-genetic markers for breast cancer risk. Risk-based screening is already routine for women with a strong family history and/or carry a BRCA1 or BRCA2 mutation; the principle could be extended to utilise other markers. Nearly 80 common genetic variants for breast cancer have now been identified, and collectively these identify 1% of women with a risk more than three times the average (Michailidou et al, 2013). Many more such variants are likely to be identified in the coming years. Several breast cancer risk models including BOADICEA, Tyrer-Cuzick and Gail already exist and are utilised widely in genetic counselling and prevention trials; some would argue that the current models have low predictive power, but combining the effects of genetic markers, lifestyle risk factors and mammographic density should lead to tests with useful discriminatory power.

A more nuanced risk-based screening programme would involve women at higher risk being screened from a younger age, or more intensively, or with additional modalities (e.g., MRI), while women at lower risk would be screened less often or not at all. The obvious advantage is that resources are targeted on women with the highest likelihood of benefit while at the same time reducing screening interventions for women at lower risk, thus producing more benefit at a lower cost (Pashayan et al, 2011). Moreover, we also know that both genetic and non-genetic risk factors can, to some extent, predict the risk of specific tumour subtypes as recently shown (Garcia-Closas et al, 2013). This information might enable the rate of overdiagnosis to be reduced as well.

While individualised screening is already accepted in the context of women with a family history, there are clearly many challenges to be faced before this model could become a reality in national screening programmes. The public tolerability is crucial but also probably the least problematic. For decades, perfectly healthy individuals are ‘screened’ for factors that influence the risk of cardiovascular disorders and measurements of blood lipids and blood pressure fully accepted. The organisational aspects are challenging. If genetic and other risk assessments were extended to all women, what form of counselling would be available? Most countries lack the infrastructure needed to handle of this massive information exchange. The professional acceptability of a change to an individualised screening programme is difficult to predict, although again the acceptance of individualised intervention for cardiovascular disease provides a model. On top of all this there are ethical, legal and social considerations to be taken into consideration.

Finally, we have not even touched on what to offer women in the highest risk group. Future prediction models will identify many more women with a lifetime risk of more than 30% – classified as ‘high risk’ according to NICE (National Institute for Health and Clinical Excellence, 2006). Intensified screening will surely be too passive an intervention for this group. In the context of a familial history, such women would generally be offered MRI, prophylactic surgery and/or chemoprophylactics – would this also be extended to the population at large?

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