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| 2021-A02539-32 | Registry Identifier | ID-RCB |
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The use of a personalized 3D model of the breast in the management of breast cancer would be very useful to help the surgeon better understand the three-dimensional location of tumors in the operative position and thus better plan incisions and dissection of the breast tissue. This could be achieved with the help of a 3D biomechanical breast model that ideally should integrate the patient-specific mechanical properties of all breast tissue structures. The elasticity of the skin and especially the consideration of factors that can make it vary with age has been little studied. However, the integration of this parameter would clearly increase the robustness of the 3D model.
Main objective:
To perform a pilot evaluation of the performance of the biomechanical model by integrating the biomechanical characteristics of the skin and the collagenous architecture of the breast, during the transition from prone to supine or lateral position.
Secondary Objectives:
To describe the values of skin elasticity and thickness at different points of the breast, in women in the general population To search for clinical factors predictive of elasticity and skin thickness To carry out a pilot description of the collagen architecture of the breast
Participation in this study will be offered to all patients consulting the gynecology-obstetrics department of the Montpellier University Hospital and meeting the inclusion criteria-Visit 1: Inclusion and measurement of skin thickness and elasticity:
Inclusion will take place during the follow-up consultation in the obstetrics gynecology department of the Montpellier University Hospital. The patient's written consent will be obtained after a reflection period at the end of the consultation. Measurements of elasticity and thickness will then be performed for each of the 200 patients. Skin elasticity: The patient will be installed in dorsal decubitus position, with her arms at her sides on an examination table. Measurements will be performed at 3 sites on one of the two breasts: at the areola, above the areola and below. The measurements will be performed by a single gynecologist in the gynecology department using a cutometer provided by a laboratory of Grenoble. It has just been used by the Dutch Cancer Institute in Amsterdam to measure the elasticity of the tongue in a clinical study including 10 patients. Three measurements will be performed at each site. One measurement corresponds to a 10-second suction time (progressive rise of the depression) followed by 5 seconds of relaxation of the measurement site.
The duration of these measurements will be approximately 15 minutes. Skin thickness: The measurement of skin thickness will be performed using an ultrasound device available in the obstetrics and gynecology consultation department. The measurement will be performed at 3 sites. The duration of the measurements will be of approximately 10 minutes. Adverse events will be collected at the end of the measurements.
-Visit 2: Within 3 weeks after the first visit. Among the 200 patients, 10 patients who should benefit from a breast MRI as part of their follow-up, will have a breast MRI in 3 different positions: prone (standard protocol) and two additional acquisitions (as part of the research) in dorsal and right lateral decubitus. This examination will be scheduled in the Lapeyronie Hospital.
Breast cancer is the most common cancer in France. Its screening and diagnosis use mammography, ultrasound and MRI. These imaging only show the topography of the tumors in the breast volume in two dimensions (2D). The surgeon must then mentally reconstruct the three-dimensional (3D) anatomy of the breast before planning the surgery.The use of a personalized 3D model of the breast would be very useful to help the surgeon to better understand the three-dimensional localization of the tumors in the operative position and thus to better plan the incisions and the dissection of the breast tissue, preserving the maximum of healthy tissue but also being more relevant in the oncological aspect.
This could be achieved with the help of a 3D biomechanical model of the breast which should ideally integrate the subject-specific mechanical properties of all the tissue structures of the breast. However, obtaining a model of the breast is very difficult due to the complexity and diversity of the 3D geometry of the structures and their highly heterogeneous mechanical character. All breast tissues (skin, connective tissue, mammary gland, fat, pectoral muscle) must be modeled. For this, their mechanical behavior must be known. As biomechanical properties vary according to ex-vivo and in-vivo conditions, it is important to obtain in-vivo measurements.
The biomechanical properties of the breast skin have been little studied. The integration of the mechanical parameters of the skin would thus clearly increase the robustness of a 3D model.
Some studies have focused on skin elasticity, mainly on the arms and face. Several non-invasive measurement techniques of the biomechanical properties of the skin have been tested: suction test, torsion test, bi-axial test, and multi-axial test. These techniques may be dependent on the experimental conditions: tension application technique, probe size, skin thickness, ... Among these procedures, suction tests are considered as a reference technique, non-invasive and easy to use, for the measurement of skin elasticity.
The mobility and deformation of the breast skin make it difficult to obtain accurate measurements of biomechanical properties. Sutradhar et al studied these properties in 23 women: variations in elasticity were found for different regions of the breast; lying or standing did not appear to have an impact. In 2016, Coltman et al conducted a study on breast skin elasticity and thickness involving 339 women. Regarding factors that may influence skin elasticity, Coltman et al found a decrease in skin elasticity with age. This effect was not found in the study by Sutradhar et al. A study of 15 women showed a variation in skin elasticity of the breast according to the cycle and whether or not they were taking contraception.Main objective:
To perform a pilot evaluation of the performance of the biomechanical model by integrating the biomechanical characteristics of the skin and the collagenous architecture of the breast, during the transition from prone to supine or lateral position.
Secondary Objectives:
To describe the values of skin elasticity and thickness at different points of the breast, in women in the general population To search for clinical factors predictive of elasticity and skin thickness To carry out a pilot description of the collagen architecture of the breast
Participation in this study will be offered to all patients consulting the gynecology-obstetrics department of the Montpellier University Hospital and meeting the inclusion criteria-Visit 1: Inclusion and measurement of skin thickness and elasticity:
Inclusion will take place during the follow-up consultation in the obstetrics gynecology department of the Montpellier University Hospital. The patient's written consent will be obtained after a reflection period at the end of the consultation. Measurements of elasticity and thickness will then be performed for each of the 200 patients. Skin elasticity: The patient will be installed in dorsal decubitus position, with her arms at her sides on an examination table. Measurements will be performed at 3 sites on one of the two breasts: at the areola, above the areola and below. The measurements will be performed by a single gynecologist in the gynecology department using a cutometer provided by laboratory of Grenoble. It has just been used by the Dutch Cancer Institute in Amsterdam to measure the elasticity of the tongue in a clinical study including 10 patients. Three measurements will be performed at each site. One measurement corresponds to a 10-second suction time (progressive rise of the depression) followed by 5 seconds of relaxation of the measurement site.
The duration of these measurements (installation of the patient - installation of the material - realization of the measurements) will be approximately 15 minutes.
Skin thickness: The measurement of skin thickness will be performed using an ultrasound device available in the obstetrics and gynecology consultation department. The measurement will be performed at 3 sites. The duration of the measurements will be of approximately 10 minutes. Adverse events will be collected at the end of the measurements.
-Visit 2: Within 3 weeks after the first visit. Among the 200 patients, 10 patients who should benefit from a breast MRI as part of their follow-up, will have a breast MRI in 3 different positions: prone (standard protocol) and two additional acquisitions (as part of the research) in dorsal and right lateral decubitus. This examination will be scheduled in t the Lapeyronie Hospital.
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| Label | Type | Description | Intervention Names |
|---|---|---|---|
| Study Group | Other | Measurements of elasticity and thickness will be performed for each of the 200 patients. Among the 200 patients, 10 will have a breast MRI in 3 different positions |
|
| Name | Type | Description | Arm Group Labels | Other Names |
|---|---|---|---|---|
| Skin and thickness measurement/breast MRI | Other | Patient will be installed in dorsal decubitus position. Measurements will be performed at 3 sites on one breast: at the areola, above the areola and below. Measurements will be performed by a single gynecologist using a cutometer provided by TIMC-IMAG laboratory of Grenoble. Three measurements will be performed at each site. Duration of measurements will be approximately 15 minutes. Measurement of skin thickness will be performed using an ultrasound device available in obstetrics/gynecology consultation department. The measurement will be performed at 3 sites. The duration of the measurements will be of approximately 10 minutes. Among the 200 patients, 10 patients who should benefit from a breast MRI as part of their follow-up, will have a breast MRI in 3 different positions: prone (standard protocol) and two additional acquisitions (as part of the research) in dorsal and right lateral decubitus. This examination will be scheduled in the senology department of the Lapeyronie Hospital |
| Measure | Description | Time Frame |
|---|---|---|
| Measurement of skin elasticity using a cutometer | Skin elasticity measurements will be taken at 3 sites on one of the two breasts, during their 1st visit (baseline): at the level of the areola, above the areola and below. They will be performed by a single gynecologist from the gynecology department. Measurements will be made using a cutometer. It includes a computer, tubing connected to a 10, 15 or 20 mm cup. Three measurements will be carried out on each of the sites. A measurement corresponds to a time of gradual rise in suction of 10 seconds followed by 5 seconds of relaxation of the measurement site. A method based on an inverse model will then make it possible to estimate the local elasticity (Young's modulus) of the skin. | At baseline |
| Measurement of skin thickness using an ultrasound device | Measurements of skin thickness will be made using an ultrasound machine available in the gynecology department. They will be done at 6 sites on one of the two breasts, during their 1st visit (baseline). | At baseline |
| Collagen architecture of the breast | Precise 3D anatomical description of different breast tissues, the position and orientation of the tissues, on 10 patients with additional MRI acquisitions, at the 2nd visit (3 weeks after the 1st visit). | 3 weeks after baseline |
| 3D model | To carry out a pilot evaluation of the performance of the biomechanical model by integrating the biomechanical characteristics of the skin and the collagenous architecture of the breast, during the transition from the prone position to the dorsal or lateral decubitus position | Through study completion, an average of 1 year |
| Measure | Description | Time Frame |
|---|---|---|
| Age in years | Evaluate the potential predictive factors of the biomechanical characteristics of the skin. | At baseline |
| Body Mass Index in kilogram per square meter | Evaluate the potential predictive factors of the biomechanical characteristics of the skin. |
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Inclusion Criteria:
Exclusion Criteria:
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| Name | Affiliation | Role |
|---|---|---|
| Martha DURAES, MD | University Hospital, Montpellier | Study Director |
| Facility | Status | City | State | ZIP | Country | Contacts |
|---|---|---|---|---|---|---|
| CHU Montpellier | Montpellier | Outside of the US | 34090 | France |
| PubMed Identifier | Type | Citation | Retractions |
|---|---|---|---|
| 24595342 | Background | Han L, Hipwell JH, Eiben B, Barratt D, Modat M, Ourselin S, Hawkes DJ. A nonlinear biomechanical model based registration method for aligning prone and supine MR breast images. IEEE Trans Med Imaging. 2014 Mar;33(3):682-94. doi: 10.1109/TMI.2013.2294539. | |
| 22173131 | Background | Han L, Hipwell JH, Tanner C, Taylor Z, Mertzanidou T, Cardoso J, Ourselin S, Hawkes DJ. Development of patient-specific biomechanical models for predicting large breast deformation. Phys Med Biol. 2012 Jan 21;57(2):455-72. doi: 10.1088/0031-9155/57/2/455. Epub 2011 Dec 15. |
| Label | URL |
|---|---|
| Suction Chamber Methods for Measurement of Skin Mechanics : The New Digital Version of the Cutometer. | View source |
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| ID | Term |
|---|---|
| D001943 | Breast Neoplasms |
| ID | Term |
|---|---|
| D009371 | Neoplasms by Site |
| D009369 | Neoplasms |
| D001941 | Breast Diseases |
| D012871 | Skin Diseases |
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|
| At baseline |
| Bra cup size | Evaluate the potential predictive factors of the biomechanical characteristics of the skin. | At baseline |
| Time in the menstrual cycle | Evaluate the potential predictive factors of the biomechanical characteristics of the skin. | At baseline |
| Contraception | Presence and type of contraception. Evaluate the potential predictive factors of the biomechanical characteristics of the skin. | At baseline |
| Menopausal status | Evaluate the potential predictive factors of the biomechanical characteristics of the skin. | At baseline |
| History of breast radiotherapy | Evaluate the potential predictive factors of the biomechanical characteristics of the skin. | At baseline |
| Breastfeeding history | Breastfeeding history after their potential pregnancies. Evaluate the potential predictive factors of the biomechanical characteristics of the skin. | At baseline |
| History of breast surgery | Evaluate the potential predictive factors of the biomechanical characteristics of the skin. | At baseline |
| 17673835 | Background | Gefen A, Dilmoney B. Mechanics of the normal woman's breast. Technol Health Care. 2007;15(4):259-71. |
| 2768836 | Background | Escoffier C, de Rigal J, Rochefort A, Vasselet R, Leveque JL, Agache PG. Age-related mechanical properties of human skin: an in vivo study. J Invest Dermatol. 1989 Sep;93(3):353-7. |
| 21281361 | Background | Krueger N, Luebberding S, Oltmer M, Streker M, Kerscher M. Age-related changes in skin mechanical properties: a quantitative evaluation of 120 female subjects. Skin Res Technol. 2011 May;17(2):141-8. doi: 10.1111/j.1600-0846.2010.00486.x. Epub 2011 Feb 1. |
| 23441628 | Background | Kim E, Cho G, Won NG, Cho J. Age-related changes in skin bio-mechanical properties: the neck skin compared with the cheek and forearm skin in Korean females. Skin Res Technol. 2013 Aug;19(3):236-41. doi: 10.1111/srt.12020. Epub 2013 Feb 26. |
| 19159383 | Background | Ryu HS, Joo YH, Kim SO, Park KC, Youn SW. Influence of age and regional differences on skin elasticity as measured by the Cutometer. Skin Res Technol. 2008 Aug;14(3):354-8. doi: 10.1111/j.1600-0846.2008.00302.x. |
| 18498486 | Background | Diridollou S, Vabre V, Berson M, Vaillant L, Black D, Lagarde JM, Gregoire JM, Gall Y, Patat F. Skin ageing: changes of physical properties of human skin in vivo. Int J Cosmet Sci. 2001 Dec;23(6):353-62. doi: 10.1046/j.0412-5463.2001.00105.x. |
| 18503429 | Background | Diridollou S, Black D, Lagarde JM, Gall Y, Berson M, Vabre V, Patat F, Vaillant L. Sex- and site-dependent variations in the thickness and mechanical properties of human skin in vivo. Int J Cosmet Sci. 2000 Dec;22(6):421-35. |
| 11428960 | Background | Diridollou S, Patat F, Gens F, Vaillant L, Black D, Lagarde JM, Gall Y, Berson M. In vivo model of the mechanical properties of the human skin under suction. Skin Res Technol. 2000 Nov;6(4):214-221. doi: 10.1034/j.1600-0846.2000.006004214.x. |
| 12877691 | Background | Hendriks FM, Brokken D, van Eemeren JT, Oomens CW, Baaijens FP, Horsten JB. A numerical-experimental method to characterize the non-linear mechanical behaviour of human skin. Skin Res Technol. 2003 Aug;9(3):274-83. doi: 10.1034/j.1600-0846.2003.00019.x. |
| 33276256 | Background | Kappert KDR, Connesson N, Elahi SA, Boonstra S, Balm AJM, van der Heijden F, Payan Y. In-vivo tongue stiffness measured by aspiration: Resting vs general anesthesia. J Biomech. 2021 Jan 4;114:110147. doi: 10.1016/j.jbiomech.2020.110147. Epub 2020 Nov 25. |
| 6712522 | Background | Schneider DC, Davidson TM, Nahum AM. In vitro biaxial stress-strain response of human skin. Arch Otolaryngol. 1984 May;110(5):329-33. doi: 10.1001/archotol.1984.00800310053012. |
| 18040732 | Background | Kvistedal YA, Nielsen PM. Estimating material parameters of human skin in vivo. Biomech Model Mechanobiol. 2009 Feb;8(1):1-8. doi: 10.1007/s10237-007-0112-z. Epub 2007 Nov 27. |
| 7633759 | Background | Reihsner R, Balogh B, Menzel EJ. Two-dimensional elastic properties of human skin in terms of an incremental model at the in vivo configuration. Med Eng Phys. 1995 Jun;17(4):304-13. doi: 10.1016/1350-4533(95)90856-7. |
| 22891621 | Background | Sutradhar A, Miller MJ. In vivo measurement of breast skin elasticity and breast skin thickness. Skin Res Technol. 2013 Feb;19(1):e191-9. doi: 10.1111/j.1600-0846.2012.00627.x. Epub 2012 Aug 14. |
| 27800637 | Background | Coltman CE, Steele JR, McGhee DE. Effect of aging on breast skin thickness and elasticity: implications for breast support. Skin Res Technol. 2017 Aug;23(3):303-311. doi: 10.1111/srt.12335. Epub 2016 Nov 1. |
| 26273846 | Background | Coumare R, Bouten L, Barbier F. Influence of the menstrual cycle on breast skin elasticity. Comput Methods Biomech Biomed Engin. 2015;18 Suppl 1:1912-3. doi: 10.1080/10255842.2015.1069558. Epub 2015 Aug 14. No abstract available. |
| 30408760 | Background | Mira A, Carton AK, Muller S, Payan Y. A biomechanical breast model evaluated with respect to MRI data collected in three different positions. Clin Biomech (Bristol). 2018 Dec;60:191-199. doi: 10.1016/j.clinbiomech.2018.10.020. Epub 2018 Oct 17. |
| 38174585 | Result | Duraes M, Briot N, Connesson N, Chagnon G, Payan Y, Duflos C, Rathat G, Captier G, Subsol G, Herlin C. Evaluation of breast skin and tissue stiffness using a non-invasive aspiration device and impact of clinical predictors. Clin Anat. 2024 Apr;37(3):329-336. doi: 10.1002/ca.24134. Epub 2024 Jan 4. |
| 41549904 | Result | Duraes M, Rathat G, Coutureau J, Mandoul C, Francini S, Rebel L, Captier G, Subsol G, Herlin C. New Insights on Breast Anatomy Based on Magnetic Resonance Imaging and Surgical Observations. Clin Anat. 2026 Jan 19. doi: 10.1002/ca.70071. Online ahead of print. |
| In-Vivo Soft Tissues Mechanical Characterization: Volume-Based Aspiration Method Validated on Silicones | View source |
| D017437 |
| Skin and Connective Tissue Diseases |