Radyoterapide Kullanılan İmmobilizasyon Cihazlarının Gelişimi: Tarihsel Perspektif
Özet
Radyoterapi immobilizasyon cihazlarının evrimi, radyasyon onkolojisinin gelişiminin çok önemli bir yönü olmuştur. Görüntü kılavuzluğunda radyoterapinin piyasaya sürülmesi, görüntüleme teknolojisinin radyasyon tedavisi cihazlarına entegrasyonuna izin vererek radyasyonun hedef hacme çok yüksek dozların daha kesin ve doğru şekilde iletilmesine yol açmıştır. Vakum yastıklı immobilizasyon ve özelleştirilmiş immobilizasyon sistemleri dahil olmak üzere immobilizasyon cihazlarının kullanımının, set-up hatalarını en aza indirerek ve intrafraksiyon hareketini azaltarak radyoterapinin etkinliğini artırmada faydalı olduğu olmuştur. Radyoterapi teknolojisindeki gelişmeler, organ korumaya yönelik tedavilerin uygulanmasına olanak tanıyarak invaziv prosedürlere olan ihtiyacı azaltmıştır. Modern radyoterapi teknikleri için klinik kanıtlar hala sınırlı olsa da, randomize deneyler birçok farklı kanser türünde etkinlik ve tolerans çalışmaları, gelişmiş radyoterapi teknolojisi kullanımı ile belirli kanser türleri için lokal kontrol ve genel sağkalımda iyileşmeye neden olmuştur. Radyoterapi tedavisinde gelişen teknoloji olanaklarını hastaya uyarlamak için aracı teknolojik gereçler olan immobilizasyon aletleri tarihsel süreçte önemli bir evrim geçirmiştir.
Referanslar
Rakıcı SY. Radyasyon Maruziyeti. Ankara: Akademisyen Kitabevi; 2022. 1-969 p.
Connell PP, Hellman SJCr. Advances in radiotherapy and implications for the next century: a historical perspective. 2009;69(2):383-392.
Delaney GP, Barton MBJCO. Evidence-based estimates of the demand for radiotherapy. 2015;27(2):70-76.
Thariat J, Hannoun-Levi J-M, Sun Myint A, et al. Past, present, and future of radiotherapy for the benefit of patients. 2013;10(1):52-60.
Jaffray DAJNrCo. Image-guided radiotherapy: from current concept to future perspectives. 2012;9(12):688-699.
Verellen D, De Ridder M, Storme GJR, et al. A (short) history of image-guided radiotherapy. 2008;86(1):4-13.
Beaton L, Bandula S, Gaze MN, et al. How rapid advances in imaging are defining the future of precision radiation oncology. 2019;120(8):779-790.
Chetty IJ, Martel MK, Jaffray DA, et al. Technology for innovation in radiation oncology. 2015;93(3):485-492.
Chen HH, Kuo MTJO. Improving radiotherapy in cancer treatment: Promises and challenges. 2017;8(37):62742.
Li W, Cashell A, Lee I, et al. Patient perspectives on frame versus mask immobilization for gamma knife stereotactic radiosurgery. 2020;51(4):567-573.
Leksell LJAcs. The stereotaxic method and radiosurgery of the brain. 1951;102:316-319.
Ramakrishna N, Rosca F, Friesen S, et al. A clinical comparison of patient setup and intra-fraction motion using frame-based radiosurgery versus a frameless image-guided radiosurgery system for intracranial lesions. 2010;95(1):109-115.
Rakici SY, Çinar Y, Eren M. Total scalp irradiation: the comparison of five different plans using volumetric modulated arc therapy-simultaneous integrated boost (VMAT-SIB) technique. Turkish Journal of Oncology. 2017;32(3).
Saw CB, Yakoob R, Enke CA, et al. Immobilization devices for intensity-modulated radiation therapy (IMRT). 2001;26(1):71-77.
Verhey LJ, editor Immobilizing and positioning patients for radiotherapy. Seminars in radiation oncology; 1995: Elsevier.
Gilson RC, Pham CM, Gilson RTJJCR. Bullous Pseudomonas skin infection and bacteremia caused by tattoo ink used in radiation therapy. 2015;1(4):222-224.
Dickie CI, Parent A, Griffin A, et al. A device and procedure for immobilization of patients receiving limb-preserving radiotherapy for soft tissue sarcoma. 2009;34(3):243-249.
Mitine C, Hoornaert MT, Dutreix A, et al. Radiotherapy of pelvic malignancies: impact of two types of rigid immobilisation devices on localisation errors. 1999;52(1):19-27.
Rakici SY, Inecikli FM, Okumus NO, et al. High Dose 3D Conformal Radiotherapy of Prostate Cancer Using Spaceoar Gel.
Li W, Purdie TG, Taremi M, et al. Effect of immobilization and performance status on intrafraction motion for stereotactic lung radiotherapy: analysis of 133 patients. 2011;81(5):1568-1575.
Mitine C, Hoornaert MT, Dutreix A, et al. Radiotherapy of pelvic malignancies: impact of two types of rigid immobilisation devices on localisation errors. Radiotherapy oncology 1999;52(1):19-27.
Wachter S, Gerstner N, Dorner D, et al. The influence of a rectal balloon tube as internal immobilization device on variations of volumes and dose-volume histograms during treatment course of conformal radiotherapy for prostate cancer. 2002;52(1):91-100.
Negoro Y, Nagata Y, Aoki T, et al. The effectiveness of an immobilization device in conformal radiotherapy for lung tumor: reduction of respiratory tumor movement and evaluation of the daily setup accuracy. 2001;50(4):889-898.
Asfia A, Novak JI, Mohammed MI, et al. A review of 3D printed patient specific immobilisation devices in radiotherapy. 2020;13:30-35.
Halperin R, Roa W, Field M, et al. Setup reproducibility in radiation therapy for lung cancer: a comparison between T-bar and expanded foam immobilization devices. 1999;43(1):211-216.
Van de Werf E, Verstraete J, Lievens YJR, et al. The cost of radiotherapy in a decade of technology evolution. 2012;102(1):148-153.
Physics IMRTCWGJIJoROB. Intensity-modulated radiotherapy: current status and issues of interest. 2001;51(4):880-914.
Lievens Y, Borras J-M, Grau C, et al. Value-based radiotherapy: a new chapter of the ESTRO-HERO project. 2021;160:236-239.
Ling CC, Humm J, Larson S, et al. Towards multidimensional radiotherapy (MD-CRT): biological imaging and biological conformality. 2000;47(3):551-560.
Pacelli R, Caroprese M, Palma G, et al., editors. Technological evolution of radiation treatment: Implications for clinical applications. Seminars in oncology; 2019: Elsevier.
Steinmeier T, Schleithoff SS, Timmermann BJCO. Evolving radiotherapy techniques in paediatric oncology. 2019;31(3):142-150.
Kavanagh BD, Haffty BG, Tepper JEJJoCO. Radiation oncology: a snapshot in time, 2014. 2014;32(26):2825.
Alongi F, Di Muzio NJTJ. Radiobiology and molecular oncology: how are they changing radiotherapy in clinical practice? 2010;96(1):175-177.
Malkin J. Medical and dental space planning: A comprehensive guide to design, equipment, and clinical procedures: John Wiley & Sons; 2014.
Irwin JG, Hoffman JJ, Lamont BTJJoE, et al. The effect of the acquisition of technological innovations on organizational performance: A resource-based view. 1998;15(1):25-54.
Wan TT, Lin BY-J, Ma AJJoMS. Integration mechanisms and hospital efficiency in integrated health care delivery systems. 2002;26:127-143.
Radiology ESo. ECR 2012 Book of Abstracts-H-Scientific Sessions for Students. 2012;3(Suppl 1):445.
Greenbaum DJSCHTL. Direct digital engagement of patients and democratizing health care. 2015;32:93.
Li W, Sahgal A, Foote M, et al. Impact of immobilization on intrafraction motion for spine stereotactic body radiotherapy using cone beam computed tomography. 2012;84(2):520-526.
Nutting CM, Khoo VS, Walker V, et al. A randomised study of the use of a customised immobilisation system in the treatment of prostate cancer with conformal radiotherapy. 2000;54(1):1-9.
Steinmetz A, Platt M, Janssen E, et al. Design of a 3D printed immobilization device for radiation therapy of experimental tumors in mice. 2017;99(2):E618.
Robar JL, Kammerzell B, Hulick K, et al. Novel multi jet fusion 3D‐printed patient immobilization for radiation therapy. 2022;23(11):e13773.
