Breast imaging

For non-medical images of breasts, see Depictions of nudity.
Positron emission mammography is one of several methods of breast imaging.

In medicine, breast imaging is the representation or reproduction of a breast's form. There are various methods of breast imaging.

X-ray

Mammography

Main article: Mammography
The best mammographic images are produced when the breast is compressed.

Mammography is the process of using low-energy X-rays (usually around 30 kVp) to examine the human breast, which is used as a diagnostic and screening tool. The goal of mammography is the early detection of breast cancer, typically through detection of characteristic masses and/or microcalcifications. For the average woman, the U.S. Preventive Services Task Force recommended (2009) mammography every two years in women between the ages of 50 and 74.[1] The American College of Radiology and American Cancer Society recommend yearly screening mammography starting at age 40.[2] The Canadian Task Force on Preventive Health Care (2012) and the European Cancer Observatory (2011) recommends mammography every 2–3 years between 50 and 69.[3][4] These task force reports point out that in addition to unnecessary surgery and anxiety, the risks of more frequent mammograms include a small but significant increase in breast cancer induced by radiation.[5][6] Additionally, mammograms should not be done with any increased frequency in people undergoing breast surgery, including breast enlargement, mastopexy, and breast reducation.[7] The Cochrane Collaboration (2013) concluded that the trials with adequate randomisation did not find an effect of mammography screening on total cancer mortality, including breast cancer, after 10 years. The authors of systematic review write: "If we assume that screening reduces breast cancer mortality by 15% and that overdiagnosis and overtreatment is at 30%, it means that for every 2000 women invited for screening throughout 10 years, one will avoid dying of breast cancer and 10 healthy women, who would not have been diagnosed if there had not been screening, will be treated unnecessarily. Furthermore, more than 200 women will experience important psychological distress including anxiety and uncertainty for years because of false positive findings." The authors conclude that the time has come to re-assess whether universal mammography screening should be recommended for any age group.[8] They thus state that universal screening may not be reasonable.[9] The Nordic Cochrane Collection, which in 2012 reviews updated research to state that advances in diagnosis and treatment make mammography screening less effective today. They state screening is “no longer effective.” They conclude that “it therefore no longer seems reasonable to attend” for breast cancer screening at any age, and warn of misleading information on the internet.[9]

Mammography has a false-negative (missed cancer) rate of at least 10 percent. This is partly due to dense tissues obscuring the cancer and the fact that the appearance of cancer on mammograms has a large overlap with the appearance of normal tissues. A meta-analysis review of programs in countries with organized screening found 52% over-diagnosis.[9]

Digital breast tomosynthesis

Digital breast tomosynthesis (DBT) can provide a higher diagnostic accuracy compared to conventional mammography. In DBT, like conventional mammography, compression is used to improve image quality and decreases radiation dose. The laminographic imaging technique dates back to the 1930s and belongs to the category of geometric or linear tomography.[10]

Because the data acquired are very high resolution (85 - 160 micron typical ), much higher than CT, DBT is unable to offer the narrow slice widths that CT offers (typically 1-1.5 mm). However, the higher resolution detectors permit very high in-plane resolution, even if the Z-axis resolution is less. The primary interest in DBT is in breast imaging, as an extension to mammography, where it offers better detection rates with little extra increase in radiation.[11][12]

Tomosynthesis is now Food and Drug Administration (FDA) approved for use in breast cancer screening.[13]

Xeromammography

Main article: Xeromammography

Xeromammography is a photoelectric method of recording an x-ray image on a coated metal plate, using low-energy photon beams, long exposure time, and dry chemical developers. It is a form of xeroradiography.[14]

Galactography

Main article: Galactography

Galactography is a medical diagnostic procedure for viewing the milk ducts. The standard treatment of galactographically suspicious breast lesions is to perform a surgical intervention on the concerned duct or ducts: if the discharge clearly stems from a single duct, then the excision of the duct (microdochectomy) is indicated;[15] if the discharge comes from several ducts or if no specific duct could be determined, then a subareolar resection of the ducts (Hadfield's procedure) is performed instead.[15] To avoid infection, galactography should not be performed when the nipple discharge contains pus.[16]

MRI

Main article: Breast MRI
A color-enhanced MRI of a breast

Breast MRI, an alternative to mammography, has shown substantial progress in the detection of breast cancer. The available literature suggests that the sensitivity of contrast-enhanced breast MRI in detection of cancer is considerably higher than that of either radiographic mammography or ultrasound and is generally reported to be in excess of 94%.[17]

The specificity (the confidence that a lesion is cancerous and not a false positive) is only fair ('modest'),[18] (or 37%-97%[17]) thus a positive finding by MRI should not be interpreted as a definitive diagnosis.

The reports of 4,271 breast MRIs from eight large scale clinical trials were reviewed in 2006.[19]

Ultrasound

Main article: Breast ultrasound
Breast ultrasounds may be used with or without a mammogram.

Breast ultrasound is the use of medical ultrasonography to perform imaging of the breast. It can be considered either a diagnostic or a screening procedure.[20] It may be used either with or without a mammogram.[21]

Scintimammography

Main article: Scintimammography

Scintimammography is a type of breast imaging test that is used to detect cancer cells in the breasts of some women who have had abnormal mammograms, or for those who have dense breast tissue, post-operative scar tissue or breast implants, but is not used for screening or in place of a mammogram. Rather, it is used when the detection of breast abnormalities is not possible or not reliable on the basis of mammography and ultrasound. In the scintimammography procedure, a woman receives an injection of a small amount of a radioactive substance called technetium 99 sestamibi.[22]

Tactile imaging

Tactile images of breast lesions

Breast cancer is one of the most common causes of death from cancer. The lifetime probability of developing breast cancer in the next 10 years is evaluated as 13%.[23] A critical key to a continued reduction in mortality is early detection and accurate diagnosis made in a cost-effective manner. Figure 3 shows a general view of Breast Tactile Imager (BTI). The device includes a probe with a pressure sensor array, an electronic unit, and a laptop computer. BTI can quantitatively evaluate multiple mechanical and structural properties of breast and breast lesions, such as Young’s modulus, elasticity contrast, tissue nonlinearity (strain hardening), heterogeneity index, nodule size, shape and mobility, which could be altered by cancer development.[24] Clinical data collected at four different sites for 179 cases have demonstrated BTI's capability for characterizing and differentiating benign and malignant breast lesions.[25] Histologically confirmed malignant breast lesions demonstrated increased hardness and strain hardening as well as decreased mobility in comparison with benign lesions. Statistical analysis of data on 147 benign and 32 malignant lesions revealed BTI's sensitivity of 91.4% and specificity of 86.8%. Examples of cysts and ductal carcinoma images recorded by BTI are shown in Figure 4. BTI has the potential to be used as a cost effective device for cancer detection as a diagnostic modality. It was estimated that the use of the BMI after standard screening procedures (mammography alone or combination of mammography and conventional ultrasound) could significantly reduce the benign biopsy rate.[25]

References

  1. "Breast Cancer: Screening". United States Preventive Services Task Force.
  2. "Breast Cancer Early Detection". cancer.org. 2013-09-17. Retrieved 29 July 2014.
  3. "Recommendations on screening for breast cancer in average-risk women aged 40–74 years". Retrieved 2013-02-21.
  4. "Archived copy". Archived from the original on 2012-02-11. Retrieved 2015-09-21.
  5. "Breast Cancer: Screening". United States Preventive Services Task Force. Archived from the original on 2013-06-16.
  6. Friedenson B (March 2000). "Is mammography indicated for women with defective BRCA genes? Implications of recent scientific advances for the diagnosis, treatment, and prevention of hereditary breast cancer". MedGenMed. 2 (1): E9. PMID 11104455.
  7. American Society of Plastic Surgeons (24 April 2014), "Five Things Physicians and Patients Should Question", Choosing Wisely: an initiative of the ABIM Foundation, American Society of Plastic Surgeons, archived from the original on 19 July 2014, retrieved 25 July 2014
  8. Gøtzsche PC, Jørgensen KJ (2013). "Screening for breast cancer with mammography". Cochrane Database Syst Rev. 6 (6): CD001877. doi:10.1002/14651858.CD001877.pub5. PMID 23737396.
  9. 1 2 3 "Mammography-leaflet; Screening for breast cancer with mammography" (PDF). Retrieved 2012-06-24.
  10. Dedicated Computed Tomography of the Breast: Image Processing and Its Impact on Breast Mass Detectability. Qing Xia. 2007. ISBN 0549663193 pp.4
  11. Smith AP, Niklason L, Ren B, Wu T, Ruth C, Jing Z. Lesion Visibility in Low Dose Tomosynthesis. In: Digital mammography : 8th international workshop, IWDM 2006, Manchester, UK, June 18–21, 2006 : proceedings. Astley, S, Brady, M, Rose, C, Zwiggelaar, R (Eds.) (Springer, New York, 2006) pp.160.
  12. Lång, K; Andersson, I; Zackrisson, S (2014). "Breast cancer detection in digital breast tomosynthesis and digital mammography—a side-by-side review of discrepant cases". The British Journal of Radiology. 87 (1040): 20140080. doi:10.1259/bjr.20140080. ISSN 0007-1285. PMID 24896197.
  13. "Selenia Dimensions 3D System - P080003, US Food and Drug Administration (FDA), February 11, 2011
  14. Xeromammography at the US National Library of Medicine Medical Subject Headings (MeSH)
  15. 1 2 Nigel Rawlinson; Derek Alderson (29 September 2010). Surgery: Diagnosis and Management. John Wiley & Sons. p. 219. ISBN 978-1-4443-9122-0.
  16. "Breast ductography". radiopaedia.org. Retrieved 4 November 2014.
  17. 1 2 Magnetic Resonance Imaging of the Breast
  18. DeMartini W, Lehman C, Partridge S (April 2008). "Breast MRI for cancer detection and characterization: a review of evidence-based clinical applications". Acad Radiol. 15 (4): 408–16. doi:10.1016/j.acra.2007.11.006. PMID 18342764.
  19. Lehman CD (2006). "Role of MRI in screening women at high risk for breast cancer". Journal of Magnetic Resonance Imaging. 24 (5): 964–70. doi:10.1002/jmri.20752. PMID 17036340.
  20. A. Thomas Stavros; Cynthia L. Rapp; Steve H. Parker (1 January 2004). Breast ultrasound. Lippincott Williams & Wilkins. ISBN 978-0-397-51624-7. Retrieved 22 August 2010.
  21. "Breast ultrasound: MedlinePlus Medical Encyclopedia". Retrieved 2010-08-22.
  22. Nass, Sharyl J.; Henderson, I. Craig; Cancer, Institute of Medicine (U.S.). Committee on Technologies for the Early Detection of Breast (2001). Mammography and beyond: developing technologies for the early detection of breast cancer. National Academies Press. pp. 106–. ISBN 978-0-309-07283-0. Retrieved 17 July 2011.
  23. American Cancer Society. 2010. Breast Cancer Facts & Figures 2009–2010. Atlanta, GA: American Cancer Society, Inc. pp.1-40
  24. Egorov V, Sarvazyan AP (September 2008). "Mechanical imaging of the breast". IEEE Transactions on Medical Imaging. 27 (9): 1275–87. doi:10.1109/TMI.2008.922192. PMC 2581459Freely accessible. PMID 18753043.
  25. 1 2 Egorov V, Kearney T, Pollak SB, et al. (November 2009). "Differentiation of benign and malignant breast lesions by mechanical imaging". Breast Cancer Research and Treatment. 118 (1): 67–80. doi:10.1007/s10549-009-0369-2. PMC 2803347Freely accessible. PMID 19306059.
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