- Open Access
An ultrasonographic evaluation of skin thickness in breast cancer patients after postmastectomy radiation therapy
© Wong et al; licensee BioMed Central Ltd. 2011
- Received: 23 September 2010
- Accepted: 24 January 2011
- Published: 24 January 2011
To determine the usefulness of ultrasonography in the assessment of post radiotherapy skin changes in postmastectomy breast cancer patients.
Patients treated for postmastectomy radiotherapy in National University Hospital (NUH) and Tan Tock Seng Hospital (TTSH), Singapore between January 2004- December 2005 was recruited retrospectively. Ultrasound scan was performed on these Asian patients who had been treated to a total dose of 46-50 Gy with 1 cm bolus placed on the skin. The ultrasound scans were performed blinded to the RTOG scores, and the skin thickness of the individually marked points on the irradiated chest wall was compared to the corresponding points on the non-irradiated breast.
The mean total skin thickness inclusive of the epidermis and the dermis of the right irradiated chest wall was 0.1712 mm (± 0.03392 mm) compared with the contra-lateral non-irradiated breast which was 0.1845 mm (± 0.04089 mm; p = 0.007). The left irradiated chest wall had a mean skin thickness of 0.1764 mm (± 0.03184 mm) compared with the right non-irradiated breast which was 0.1835 mm (± 0.02584 mm; p = 0.025). These independent t-tests produced a significant difference of reduced skin thickness on the right irradiated chest wall, p = 0.007 (p < 0.05) and left irradiated chest wall p = 0.025 (p < 0.025) in comparison to the non-irradiated skin thickness investigating chronic skin reactions. Patients with grade 2 acute skin toxicity presented with thinner skin as compared to patients with grade 1 (p = 0.006).
This study has shown that there is a statistically significant difference between the skin thicknesses of the irradiated chest wall and the contra-lateral non-irradiated breast and a predisposition to chronic reactions was found in patients with acute RTOG scoring of grade1 and grade 2.
- Breast Reconstruction
- Radiation Therapy Oncology Group
- Skin Thickness
- Capsular Contracture
- Skin Fibrosis
Breast cancer is the most commonly diagnosed cancer and the leading cause of cancer deaths among women worldwide . In addition to the acknowledged advances in surgical and medical therapies, the role of radiotherapy continues to remain important for all stages of breast cancer. While its role as adjuvant therapy in selected patients undergoing mastectomy for stages I and II disease is currently evolving, it has however, become an essential component of the combined modality approach for stage III disease. Postmastectomy radiotherapy (PMRT) to the chest wall and to the regional lymphatics has shown to decrease locoregional recurrence and increase survival for women with large tumors and/or node-positive disease [2–5]. These studies showed that PMRT not only reduced local regional recurrence rates but also improved disease free and overall survival rates in premenopausal patients receiving chemotherapy.
In spite of the advances in radiotherapy techniques, early and late adverse effects after breast irradiation are reported in a range of organs and tissues. Some of these adverse effects include ischemic heart disease, pneumonities and pulmonary fibrosis, erythema, telangiectasia and ulceration of the skin [6, 7] with skin being the most commonly affected area during breast cancer irradiation. While early effects can heal almost completely, the severe delayed changes that follow such as dermal atrophy, fibrosis, retraction and susceptibility to necrosis remain, and may affect the function and physical properties of the skin [8, 9]. Acute skin complications in postmastectomy patients have been well studied [10–12], but little is known about risks of long term skin complications and cosmesis of these patients. This forms the basis of our study.
Long term skin complication such as fibrosis is a common late side effect of radiotherapy treatment for breast cancer patients and is considered to be a dose-limiting factor during the therapy. Quantitative and objective assessment of late skin reactions is helpful for oncologists and clinicians to estimate the efficacies of radiotherapy regimens or prediction of cosmetics outcome of these patients
Previous studies on radiation induced skin effects have shown that skin assessments have been either descriptive or have used subjective parameters for scaling radiation effects [10, 11]. The visual assessments of skin condition are carried out subjectively by the examining physician and it is well known that the estimation of the visible changes by different examiners can be significantly biased . While the European Organisation for Research and Treatment of Cancer (EORTC) and Radiation Therapy Oncology Group (RTOG)  have an elaborate scoring system for acute skin reactions, evaluation of late skin changes are more descriptive, and there is no scoring to convey the amount of edema, indurations and fibrosis that may be present .
As such, a quantitative assessment and documentation of late postradiation skin reactions are important for following up of PMRT patients.
Quantitative methods that have been used to monitor skin changes following radiation therapy include direct evaluation of the mechanical properties of irradiated skin by the measurement of tensile strength of skin specimens or healing wound scars [15, 16], measurement of skin erythema by optical means [17–19], evaluation of skin water content by measurement of its dielectric constant  and examination of skin thickness by ultrasonic imaging [15, 21]. Among the many methods, high resolution ultrasound of the skin has proven to be a precise and validated method used in many skin assessment studies following radiotherapy [21, 22]. It enables accurate and easily reproducible determination of the skin's subcutaneous thickness  and allows real-time examination of the skin with relatively lower cost compared with other procedures such as biopsy and MRI.
Applications of ultrasound reported in dermatology are generally based on the measurements of skin thickness . Such measurements have been applied to assess various skin conditions particularly fibrosis. Gottllober et al  used the change of skin thickness as an indicator of cutaneous fibrosis in their studies on five patients with cutaneous radiation syndrome. Huang et al  also reported a significant change of skin thickness in the head and neck region after radiotherapy using 20 MHz ultrasound. All these studies demonstrated the potential use of the ultrasound detection of skin thickness in assessing the postirradiation reactions of the skins. It is potentially helpful to use the ultrasonic properties to characterize the irradiated skin fibrosis because some changes of the skin structures are induced by therapeutic irradiation.
However, few clinical data were available in the literature for documenting the ultrasonic properties of fibrotic skin in vivo for postmastectomy breast cancer patients with radiation induced fibrosis. Therefore, this study aimed to (1) measure chronic skin changes quantitatively using ultrasound, in patients who have gone through postmastectomy irradiation, and (2) determine if there is any correlation between late skin findings and acute visible changes using the RTOG scoring criteria in postmastectomy patients.
This study utilized the records of National Healthcare Group (NHG) from National University Hospital (NUH) and Tan Tock Seng Hospital (TTSH), Singapore to identify a group of female patients previously treated at these institutions for PMRT from January 2004-December 2005. Two hundred and five patient records were identified from the database. Of these, 7 patients had deceased, the data of 94 patients were not complete (absence of RTOG scoring in the five weeks of treatment), 26 were not contactable due to invalid addresses or telephone numbers, 16 patients had bilateral mastectomy, lumpectomy on the contra-lateral breast or metastases and 30 patients declined to participate in the study. This left 32 patients eligible to be invited to participate in the study. All of those patients were of Asian origin.
The primary criteria used to select patients from the data obtained from NUH and TTSH included a total mastectomy with no bilateral involvement and should have completed full course of radiotherapy and chemotherapy treatments. Radiotherapy dosages and RTOG scoring were explicitly specified on the fifth treatment of each of the five treatment weeks and six cycles of adjuvant intravenous chemotherapy; CMF (cyclophosphamide, methotrexate and 5-fluorouracil) were delivered following the radiotherapy. The contra-lateral breast which was not irradiated was categorized as control. Patients who had lumpectomy on the nonirradiated breast and breast reconstruction on one side or bilaterally, and who had previous radiotherapy to the chest wall, either as definitive treatment or as entry/exit dose from previous intra-thoracic malignancy radiotherapy were excluded from the study.
This investigation was approved by the institutional ethics review board -National Health Group (NHG) Domain-Specific Review Board (DSRB). Patient Information Sheet including the reasons and the details of the study as well as an invitation to participate in the study was mailed to the subjects. Patient's Informed Consent form was signed by the patient on the same day of the ultrasound scan, prior to the scan.
The whole breast had been irradiated using opposed tangential fields with 6 MV photons covering the axillary and the infra-and supra-clavicular areas for all patients. The total dose was 46-50 Gy administered in daily doses of 2 Gy 5 days a week using a Siemens Primus, linear accelerator (Siemens Medical Systems, USA). Wedges and bolus of 1 cm thickness were used every day in all patients to optimize the homogeneity of the dose distribution.
Relevant Equipment Settings for the 'Breast Detail' preset
0dB, Mechanical index = 1.6: As Low As Reasonably Achievable to minimize bio-effects.
Time Gain Compensation (TGC)
Adjusted to compensate the effect of attenuation in the subcutaneous tissue at greater depths in order to produce images of uniform brightness.
66 dB permits best differentiation between subtle changes in echo intensities of the skin region.
2 used to provide optimum smoothening of images with minimum movement induced artifacts.
Options range from low (0) to high (3) contrast. It was at 2 to obtain optimal level of contrast.
Set at 2dB to demonstrate tissues with appropriate brightness.
+2 to emphasize the boundaries between tissues.
Δ2 for high contrast resolution.
A form of frame averaging. SC1 selected to maximize frame rate.
Decreases with increasing the scan depth, the number of focal zones and image line density (resolution). Varies during the scan but it should not be below 10 Hz (fps).
Single focal zone placed at the level of the skin to optimize lateral resolution.
The measurements of each of the nine points of irradiated skin were compared with corresponding points of non-irradiated skin by using a t-test. This test determined the significance of differences between the values of the same measurements made under the two different conditions (postmastectomy with radiation skin thickness versus non-irradiated contra-lateral skin thickness). These measurements obtained in the radiated breast were compared to the retrospective data of the peak acute RTOG scoring obtained during the treatment weeks by utilizing a t-test. A p value < 0.05 was considered significant.
Reduced mean skin thickness on the Right mastectomy side with radiation in comparison to the Left non-irradiated breast.
Std. Error Mean
Skin thickness mm
Reduced mean skin thickness on the Left mastectomy side with radiation in comparison to the Right non-irradiated breast
Std. Error Mean
Skin thickness mm
Skin thickness for grade 1 and grade 2 of skin toxicity was compared in this study. Other grades were not included as there was only one patient representing grade 0 and grade 3 respectively and none of grade 4. Patients with grade 2 acute skin toxicity presented with thinner skin compared to patients with grade 1. The mean skin thickness for patients who had grade 2 was 0.1720 mm (± 0.03132 mm), while for grade 1 it was 0.1879 mm (± 0.03900 mm, p = 0.006).
Skin thickness of points marked on the medial and lateral side
Std. Error Mean
Skin thickness on contralateral non-irradiated breast mm
Skin thickness on mastectomy irradiated side
In this study we demonstrated quantitative ultrasound as an objective means of assessing late skin toxicity in postmastectomy breast cancer patients after radiation therapy. Huang et al  has demonstrated that skin thickness measured via ultrasonic imaging proved to be a reliable quantitative and noninvasive measure to provide diagnostically useful information for an in vivo assessment of skin fibrosis. Using this as a feasible study, skin thickness was measured as a proxy for radiation induced fibrosis and edema in 32 postmastectomy breast cancer patients who received full course of radiation therapy in our department. This is one of the few studies of its kind on postmastectomy breast cancer patients follow up comparing late skin effects particularly radiation induced fibrosis with acute scoring. To the best of our knowledge, there is limited literature available about radiation induced fibrosis after postmastectomy radiotherapy in ultrasonic imaging. This study attempted to provide some basic clinical results for this purpose. Our study has shown that there is a statistically significant difference between the skin thicknesses of the irradiated chest wall and the contra-lateral non-irradiated breast and a predisposition to chronic reactions was found in patients with acute RTOG scoring of grade 1 and grade 2. These differences could assist to explain breast reconstruction complications in postmastectomy breast cancer patients after receiving a course of radiotherapy. A number of studies have demonstrated an increased rate of breast reconstruction complications after postmastectomy radiotherapy [26–29]. Tallet et al  reported breast reconstruction complications were significantly greater in patients who received radiotherapy than those who did not (51% vs 14%) and a study by Behranwala et al  suggested that the rate of capsular contracture due to radiation might be as high as 40%. As such most complications were either due to capsular contracture with or without pain, or skin fibrosis due to radiation exposure.
In an effort to explain the increased breast reconstruction complications in patients due to increased radiation dose to the skin, a separate pilot study (results submitted for publication) was conducted in our department to assess skin dose in post-mastectomy radiation measured by TLDs in a customized chestwall phantom. The measurements were also analyzed with the use of wedges and the presence of bolus. The surface dose with bolus was determined to be much larger than that without bolus as expected (39% increase in dose when bolus was used).
In addition, results showed that the oblique incident angle and flat chestwall thickness also played an important factor in increasing the skin dose in postmastectomy patients. As severity of skin toxicity is radiation-dose related, this suggests a possible relationship with breast reconstruction complications and an impairment of the skin thickness with radiation due to skin fibrosis.
The accuracy of the ultrasonic measurement of skin thickness has been established since the late 1970s . By introducing this method in our study, we found that the breast skin thickness decreased significantly in the postmastectomy patients after radiotherapy. In our study, the skin thickness of the postmastectomy breast cancer patients was approximately 9.2% to 9.6% smaller than that of the control non-irradiated side. This is in contrast to previous publications [24, 30] that reported an increase of 37% in the neck region and 38% in the conservatively managed breast following irradiation. One possible reason for the discrepancies was the difference of radiation dosage used for the patients. Another possible reason was the difference of the follow-up time of the subjects at recruitment.
Correlations of Acute skin scoring (RTOG) and fibrotic skin thickness
RTOG Scoring Criteria for Acute Radiation Skin Reactions
RTOG Scoring Criteria
No change over baseline
Follicular, faint or dull erythema, epilation, dry desquamation, decreased sweating
Tender or bright erythema, patchy moist desquamation, moderate oedema
Confluent, moist desquamation other than skin folds, pitting oedema
Ulceration haemorrhage, necrosis
In this study, grade 1 acute skin reaction was found in 72% of patients, grade 2 in 22% of patients and grade 3 and grade 0 were found in 3% each. No patient had grade 4 skin reaction in the study. These results are similar to those reported in literature whereby Back  demonstrated a low rate of acute toxicity with a RTOG score of 3 and 4 which occurred in only 6% of women receiving radiotherapy. Small and Woloschak  also added that on average, more than 80% of acute skin toxicity during breast radiation was in the grades of 1 and 2.
Reduced mean skin thickness in patients with grade 2 acute skin reactions
Std. Error Mean
On ultrasound, the skin appears echogenic and is well demarcated from the underlying hypoechoic subcutaneous fat. However, the epidermis cannot be resolved from the dermis on ultrasound. The epidermis is composed of several layers. The stratum basale is the deepest layer where the majority of cell division occurs. This layer is the most sensitive for radiation injury that results in the clinically visible acute radiation skin reactions .
In addition, we also looked at the variation in skin thickness across the breast. The medial and lateral aspects of both sides were examined symmetrically. Our results showed that the skin on the medial aspect was consistently thicker than the lateral aspect on both the irradiated postmastectomy and non-irradiated side. This reported mean thickness is similar to previous studies by Wratten et al  that compared variation in skin thickness in the conservatively managed breast. This finding suggests a need to use the same examination point when performing serial and comparative examinations.
The results of this study may be limited because of small study population and non-representation of patients with all the grades of RTOG scoring. Our study has a low incidence of other grades of reactions especially higher grades and thus, it was not possible to investigate whether the higher grades (grade 3 and grade 4) showed a convincing trend of an increased probability of thinning in the skin thickness.
It is also possible that other factors such as the age, chemotherapy and surgery of the patients may have influenced the results. However, Turesson et al  studied 402 breast cancer patients who received radiotherapy and were followed up for ten years. Prognostic factors for acute and late skin reactions such as treatment-related variables and patient-related variables were analyzed. They could not verify that age; hemoglobin level, smoking and collagen vascular diseases had significant influence on the acute and late skin reactions.
High frequency ultrasound provides easy, low cost and quantitative value in studying skin thickness in acute and chronic skin reactions. A great attention to the ultrasound technique must be given. It is important to maintain the ultrasound beam perpendicular to the surface of the skin to avoid artifacts due to scattering and minimizing variations in pressure of the transducer on the skin which may alter its apparent skin thickness. In this study, each marked point was only measured once and may have affected the intra-rater variability. An average measurement of two to three times would be more representative of each of the measured point. However, Agner et al  reported that the coefficient of variation of repeated ultrasound measurements were low (approximately 2.2% on normal skin).
Further prospective studies are required in measuring ultrasonic skin thickness before, during and after radiotherapy treatment followed-up yearly after treatment for about 10 years to document quantitative skin changes. Warszawski et al  proved that the structural changes in the assessment of early and late skin reactions can be recorded by ultrasonic evaluation and much earlier than visible reactions by the naked eye of the examining physicians. However, results did not demonstrate any significant difference in skin changes over long periods.
Patients requiring radiotherapy had a higher rate of expander implant breast reconstruction failure and complications to patients who did not receive RT . This can be explained in part by increased thinning of the skin post radiotherapy which increased overall contracture failure rate and thus, adverse cosmetic outcome.
Further studies are needed to confirm this explanation by quantifying the changes of the water and collagen in post irradiated skin. Two directions may be considered in future investigations to study how the severity of fibrosis affects skin thickness. One is to conduct biochemical or histological examinations directly to quantify the level of skin fibrosis and the other is to measure specifically the physical properties such as elasticity of the skin layer, as an indicator of the cutaneous fibrosis before and after radiation. This leads us to our next study which looks at histological changes of human skin cells after fractionated radiotherapy in an effort to explain the effects of fibrosis and skin changes in postmastectomy radiotherapy.
Our study has proven that high frequency ultrasound can be utilized to document quantitative sonographic changes of the skin thickness in postmastectomy breast cancer patients following radiotherapy. This study also demonstrated a statistically significant difference in the skin thickness between the irradiated side and the contra-lateral non-irradiated breast. This finding might be helpful to predict late skin reactions. In spite of just using two grades of RTOG scoring in this study, a statistically significant predisposition to chronic reactions was found in patients with acute radiation reaction. The ability to successfully predict the complication risk for individual patients can lead to real advances in radiation oncology. These results can be used to decide which patients would benefit from breast reconstruction and perhaps dissuade patients whose skin is too thin and who are likely to experience breast reconstruction failure after postmastectomy radiotherapy.
Written informed consent was obtained from the patient for publication of this case report and accompanying images.
This work was supported partially by a grant from The Cancer Institute (TCI) Endownment Fund and NUH Cancer Fund.
- Kols A: Breast Cancer: Increasing Incidence. Limited Options Outlook 2002, 19: 1-8.Google Scholar
- Overgaard M: Overview of randomized trials in high risk breast cancer patients treated with adjuvant systemic therapy with or without postmastectomy irradiation. Seminar Radiation Oncology 1999, 9: 292-299. 10.1016/S1053-4296(99)80022-8View ArticleGoogle Scholar
- Overgaard M, Jensen MB, Overgaard J: Postoperative radiotherapy in high-risk postmenopausal breast cancer patients given adjuvant tamoxifen. Danish Breast Cancer Cooperative Group DBCG 82c randomised trial 1999, 353: 1641-1648.Google Scholar
- Ragaz J, Jackson SM, Le N: Adjuvant radiotherapy and chemotherapy in node-positive premenopausal women with breast cancer. N Engl J Med 1997, 337: 956-62. 10.1056/NEJM199710023371402View ArticlePubMedGoogle Scholar
- Recht A, Edge SB, Solin LJ: Postmastectomy radiotherapy: clinical practice guidelines of the American Society of Clinical Oncology. J Clin Oncol 2001, 19: 1539-1569.PubMedGoogle Scholar
- Fuller SA, Haybittle JL, Smith RE, Dobbs HJ: Cardiac doses in post-operative breast irradiation. Radiother, Oncol 1992, 25: 19-24. 10.1016/0167-8140(92)90190-6View ArticleGoogle Scholar
- Paszat LF, Mackillop WJ, Groome PA: Mortality from myocardial infarction following postlumpectomy radiotherapy for breast cancer: a population-based study in Ontario, Canada. Int J of Radiat Oncol Biol Phys 1999, 43: 755-762. 10.1016/S0360-3016(98)00412-XView ArticleGoogle Scholar
- Archambeau JO, Pezner R, Wasserman T: Pathophysiology of irradiated skin and breast. Int J of Radiat Oncol Biol Phys 1995, 31: 1171-1185. 10.1016/0360-3016(94)00423-IView ArticleGoogle Scholar
- Hopewell JW: The skin: its structure and response to ionizing radiation. Int J of Radiat Oncol Biol Phys 1990, 57: 751-773. 10.1080/09553009014550911View ArticleGoogle Scholar
- Fernando IN, Ford HT, Powles TJ: Factors affecting acute skin toxicity in patients having breast irradiation after conservative surgery: A prospective study of treatment practice at the Royal Marsden Hospital. Clinical Oncology 1996, 8: 226-233. 10.1016/S0936-6555(05)80657-0View ArticlePubMedGoogle Scholar
- Harper JL, Franklin LE, Jenrette JM, Aguero EG: Skin toxicity during breast irradiation: pathophysiology and management. Sout Med 2004, 989-93. 10.1097/01.SMJ.0000140866.97278.87Google Scholar
- Bentzen SM, Overgaard M: Relationship between early and late normal tissue injury after postmastectomy radiotherapy. Radiother, Oncol 1991, 20: 159-165. 10.1016/0167-8140(91)90092-UView ArticleGoogle Scholar
- Dische S, Warburton MF, Jones D, Lartigau E: The recording of morbidity related to radiotherapy. Radiother, Oncol 1989, 16: 103-108. 10.1016/0167-8140(89)90026-1View ArticleGoogle Scholar
- Emami B, Lyman J, Brown A: Tolerance of normal tissue to therapeutic irradiation. Int J of Radiat Oncol Biol Phys 1991, 21: 109-122. 10.1016/0360-3016(91)90171-YView ArticleGoogle Scholar
- Baker MR, Bader D, Hopewell JW: The effects of single doses of x-rays on the mechanical properties of pig skin in vivo. Br J Radiol 1989, 830-837. 10.1259/0007-1285-62-741-830Google Scholar
- Gorodetsky R, Mou XD, Fisher DR, Taylor JM, Withers HR: Radiation effect in mouse skin: Dose fractionation and would healing. Int J of Radiat Oncol Biol Phys 1990, 18: 1077-1081. 10.1016/0360-3016(90)90443-NView ArticleGoogle Scholar
- Turesson I: Skin reaction as a biologic parameter for control of different dose schedules and gap correction. Acta Radiol Ther Phys Biol 1976, 162-176.Google Scholar
- Nias AH: Some comparisons of fractionation effects by erythema measurements on human skin. Br J Radiol 1963, 183-187. 10.1259/0007-1285-36-423-183Google Scholar
- Russell NS, Knaken H, Bruinvis IA, Hart AA, Begg AC, Lebesque JV: Quantification of patient to patient variation of skin erythema developing as a response to radiotherapy. Radiother Oncol 1994, 30: 213-221. 10.1016/0167-8140(94)90460-XView ArticlePubMedGoogle Scholar
- Nuutinen J, Latinen T, Turrunen M: A dielectric method for measuring early and late reactions in irradiated human skin. Radiother Oncol 1998, 47: 249-254. 10.1016/S0167-8140(97)00234-XView ArticlePubMedGoogle Scholar
- Warszawski A, RE : 20 MHz ultrasonic imaging for quantitative assessment and documentation of early and late post radiation skin reactions in breast cancer patients. Radiother Oncol 1998, 47: 241-247. 10.1016/S0167-8140(97)00201-6View ArticlePubMedGoogle Scholar
- Fornage BD, McGavran MH, Duvic M, Waldron CA: Imaging of the skin with 20 MHz Ultrasound. Radiology 1993, 189: 69-76.View ArticlePubMedGoogle Scholar
- Alexander H, Miller DL: Determining skin thickness with pulsed ultra sound. J Invest Dermatol 1979, 72: 17-19. 10.1111/1523-1747.ep12530104View ArticlePubMedGoogle Scholar
- Gottlober P, Kerscher MJ, Korting HC, Peter RU: Sonographic determination of cutaneous and subcutaneous fibrosis after accidental exposure to ionising radiation in the course of the Chernobyl nuclear power plant accident. Ultrasound Med Biol 1997, 23: 9-13. 10.1016/S0301-5629(96)00173-1View ArticlePubMedGoogle Scholar
- Huang YP, Zheng YP, Leung SF, Choi AP: High Frequency Ultrasound Assessment of Skin Fibrosis: Clinical Results. Ultrasound Med Biol 2007, 8: 1191-1198. 10.1016/j.ultrasmedbio.2007.02.009View ArticleGoogle Scholar
- Hussien M, Saleh B, Malyon A: The effect of radiotherapy on the use of immediate breast reconstruction. EJSO 2004, 30: 490-4. 10.1016/j.ejso.2004.03.005View ArticlePubMedGoogle Scholar
- Behranwala KA, Dua RS, Ross GE: The influence of radiotherapy on capsule formation and aesthetic outcome after immediate breast reconstruction using biodimensional anatomical expander implants. J Plastic Reconstr Aesthet Surg 2006, 59: 1043-51. 10.1016/j.bjps.2006.01.051View ArticleGoogle Scholar
- Gui GPH, Bhranwala K, Dua RS: The impact of radiotherapy on capsule formation and aesthetic outcome after immediate breast reconstruction using biodimensional anatomic expander implants [Abstract no 409]. Breast Cancer Res Treat 2005, 94: S37. 10.1007/s10549-005-6939-zView ArticleGoogle Scholar
- Tallet AV, Salem N, Moutardier V, Ananian P, Braud AC, Zalta R, Cowen D, Houvenaeghel G: Radiotherapy and immediate two-stage breast reconstruction with a tissue expander and implant. Complications and esthetic results. Int J of Radiat Oncol Biol Phys 2003, 57: 136-142. 10.1016/S0360-3016(03)00526-1View ArticleGoogle Scholar
- Warszawski A, Rottinger EM, Vogel R, Warszawski N: 20MHZ ultrasonic imaging for quantitative assessment and documentation of early and late postradiation skin reactions in breast cancer patients. Radiother Oncol 1997, 47: 241-247. 10.1016/S0167-8140(97)00201-6View ArticleGoogle Scholar
- Small WJR, Woloschak GE: Radiation Toxicity: A Practical Guide. New York: Springer Science; 2006.View ArticleGoogle Scholar
- Bomford CK: Radiation physics therapy and oncology. In Walter and Miller's Textbook of Radiotherapy. 6th edition. Churchill Livingstone; 2003:298-299.Google Scholar
- Leucht WJ, Rabe DR: Sonographic findings following conservative surgery and irradiation for breast carcinoma. Ultrasound in Med Biol 1988, 14: 27-41. 10.1016/0301-5629(88)90044-0View ArticleGoogle Scholar
- Calkins AR, Jackson VP, Morphis JG, Stehman FB: The sonographic appearance of the irradiated breast. J Clin Ultrasound 1988, 16: 409-415. 10.1002/jcu.1870160608View ArticlePubMedGoogle Scholar
- Trotti A, Byhardt R, Stetz J, Gwede C, Corn B, Fu K, Gunderson L, McCormick B, Morris M, Rich T, Shipley W, Curran W, Radiation Therapy Oncology Group: Common toxicity criteria: version 2.0. an improved reference for grading the acute effects of cancer treatment; impact on radiotherapy. Int J of Radiat Oncol Biol Phys 2000, 47: 13-47. 10.1016/S0360-3016(99)00559-3View ArticleGoogle Scholar
- Back M, Guerrieri M, Wratten C, Steigler A: Impact of Radiation Therapy on Acute Toxicity in Breast Conservation Therapy for Early Breast Cancer. Clin Oncol 2004, 16: 12-16. 10.1016/j.clon.2003.08.005View ArticleGoogle Scholar
- Mellor RH, Bush NL, Stanton AW, Bamber JC, Levick JR, Mortimer PS: Dual frequency Ultrasound Examination of skin and subcutis thickness in breast cancer related lymphedema. The Breast Journal 2004, 496-503. 10.1111/j.1075-122X.2004.21458.xGoogle Scholar
- Wratten C, Kilmurray J, Wright S, O'Brien PC, Back M, Hamilton CS, Denham JW: Pilot Study of High Frequency Ultrasound to assess cutaneous oedema in the conservatively managed breast. Int J Cancer Radiat Oncol Invest 2000, 295-301.Google Scholar
- Agner T: Noninvasive measuring methods for the investigation of irritant patch test reactions. A study of patients with hand eczema, atopic dermatitis and controls. Acta Derm Venereol Suppl Stockh. Review 1992, 173: 1-26.Google Scholar
- Krueger EA, Wilkins EG, Strawderman N: Complications and patient satisfaction following expander/implant breast reconstruction with and without radiotherapy. Int J of Radiat Oncol Biol Phys 2001, 49: 713-721. 10.1016/S0360-3016(00)01402-4View ArticleGoogle Scholar
This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.