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"[Studi ini telah dilakukan untuk mengetahui karakteristik dari EPID dosimetri yang digunakan sebagai verifikasi pasien IMRT dan VMAT. Penelitian ini dilakukan dengan membandingkan indeks gamma dari hasil verifikasi 5 pasien brain, 5 pasien cervix, 5 pasien kepala dan leher serta 5 pasien paru menggunakan EPID dosimetri dengan MatriXX 2D array pada dua Linac yang berbeda di instalasi radioterapi MRCCC SHS dan Siloam Hospital TBS. Dari penelitian ini dihasilkan nilai indeks gamma untuk kasus IMRT di MRCCC 99.59% ± 0.46 untuk EPID dosimetri dan 99.13% ± 0.75 untuk MatriXX 2D array, sedangkan di Siloam Hospital TBS 99.8% ± 0.20 untuk EPID dosimetri dan 99.71% ± 0.14 untuk MatriXX 2D array. Pada kasus VMAT di MRCCC 97.71% ± 1.27 untuk EPID dosimetri dan 99.50% ± 0.39 untuk MatriXX 2D array, sedangkan di SiloamHospital TBS 97.78% ± 1.45 untuk EPID dosimetri dan 98.66% ± 1.26 untuk MatriXX 2D array. Kesimpulan dari penelitian ini adalah perbedaan antara EPID dosimetri dan MatriXX 2D array di kedua rumah sakit menunjukan nilai kurang dari 1% untuk kasus IMRT dan kurang dari 2% untuk kasus VMAT.

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This work was aimed to study the characteristics of EPID dosimetry in use as patient specific QA for IMRT and VMAT. We compare result of gamma index from patient specific QA with each 5 cases of brain, cervix, head and neck, lung

using EPID dosimetry and MatriXX 2D array in two different linacs at MRCCC SHS and Siloam Hospital TBS. Calculated gamma index from IMRT case in MRCCC SHS ware 99.59% ± 0.46 for EPID dosimetry and 99.13% ± 0.75 for MatriXX 2D array, meanwhile at Siloam Hospital TBS the calculated gamma index were 99.8% ± 0.20 for EPID dosimetry and 99.71% ± 0.14 for MatriXX 2D array.Gamma index from VMAT cases in MRCCC were 97.71% ± 1.27 for EPID dosimetry and 99.50% ± 0.39 for MatriXX 2D array, and in Siloam Hospital TBS the value were 97.78% ± 1.45 for EPID dosimetry and 98.66% ± 1.26 for MatriXX 2D array. We conclude that the difference between EPID dosimetry and Matrixx 2D arrays at two hospitals were less than 1% and less than 2% for IMRT and VMAT cases, respectively. This work was aimed to study the characteristics of EPID dosimetry in use as patient specific QA for IMRT and VMAT. We compare result of gamma index from patient specific QA with each 5 cases of brain, cervix, head and neck, lung using EPID dosimetry and MatriXX 2D array in two different linacs at MRCCC SHS and Siloam Hospital TBS. Calculated gamma index from IMRT case in MRCCC SHS ware 99.59% ± 0.46 for EPID dosimetry and 99.13% ± 0.75 for

MatriXX 2D array, meanwhile at Siloam Hospital TBS the calculated gamma index were 99.8% ± 0.20 for EPID dosimetry and 99.71% ± 0.14 for MatriXX 2D array.Gamma index from VMAT cases in MRCCC were 97.71% ± 1.27 for EPID dosimetry and 99.50% ± 0.39 for MatriXX 2D array, and in Siloam Hospital TBS the value were 97.78% ± 1.45 for EPID dosimetry and 98.66% ± 1.26 for MatriXX 2D array. We conclude that the difference between EPID dosimetry and Matrixx 2D arrays at two hospitals were less than 1% and less than 2% for IMRT and VMAT cases, respectively.;This work was aimed to study the characteristics of EPID dosimetry in use as

patient specific QA for IMRT and VMAT. We compare result of gamma index

from patient specific QA with each 5 cases of brain, cervix, head and neck, lung

using EPID dosimetry and MatriXX 2D array in two different linacs at MRCCC

SHS and Siloam Hospital TBS. Calculated gamma index from IMRT case in

MRCCC SHS ware 99.59% ± 0.46 for EPID dosimetry and 99.13% ± 0.75 for

MatriXX 2D array, meanwhile at Siloam Hospital TBS the calculated gamma

index were 99.8% ± 0.20 for EPID dosimetry and 99.71% ± 0.14 for MatriXX 2D

array.Gamma index from VMAT cases in MRCCC were 97.71% ± 1.27 for EPID

dosimetry and 99.50% ± 0.39 for MatriXX 2D array, and in Siloam Hospital TBS

the value were 97.78% ± 1.45 for EPID dosimetry and 98.66% ± 1.26 forMatriXX

2D array. We conclude that the difference between EPID dosimetry and Matrixx

2D arrays at two hospitals were less than 1% and less than 2% for IMRT and

VMAT cases, respectively., This work was aimed to study the characteristics of EPID dosimetry in use as

patient specific QA for IMRT and VMAT. We compare result of gamma index

from patient specific QA with each 5 cases of brain, cervix, head and neck, lung

using EPID dosimetry and MatriXX 2D array in two different linacs at MRCCC

SHS and Siloam Hospital TBS. Calculated gamma index from IMRT case in

MRCCC SHS ware 99.59% ± 0.46 for EPID dosimetry and 99.13% ± 0.75 for

MatriXX 2D array, meanwhile at Siloam Hospital TBS the calculated gamma

index were 99.8% ± 0.20 for EPID dosimetry and 99.71% ± 0.14 for MatriXX 2D

array.Gamma index from VMAT cases in MRCCC were 97.71% ± 1.27 for EPID

dosimetry and 99.50% ± 0.39 for MatriXX 2D array, and in Siloam Hospital TBS

the value were 97.78% ± 1.45 for EPID dosimetry and 98.66% ± 1.26 forMatriXX

2D array. We conclude that the difference between EPID dosimetry and Matrixx

2D arrays at two hospitals were less than 1% and less than 2% for IMRT and

VMAT cases, respectively.]"

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"Presents the proceedings of the IUPESM World Congress on Biomedical Engineering and Medical Physics, a triennially organized joint meeting of medical physicists, biomedical engineers and adjoining health care professionals"

"At the heart of every medical imaging technology is a sophisticated mathematical model of the measurement process and an algorithm to reconstruct an image from the measured data. This book provides a firm foundation in the mathematical tools used to model the measurements and derive the reconstruction algorithms used in most imaging modalities in current use. In the process, it also covers many important analytic concepts, and techniques used in Fourier analysis, integral equations, sampling theory, and noise analysis.This text uses X-ray computed tomography as a "pedagogical machine" to illustrate important ideas and incorporates extensive discussions of background material making the more advanced mathematical topics accessible to readers with a less formal mathematical education. The mathematical concepts are illuminated with over 200 illustrations and numerous exercises.New to the second edition are a chapter on magnetic resonance imaging (MRI), a revised section on the relationship between the continuum and discrete Fourier transforms, a new section on Grangreat formula, an improved description of the gridding method, and a new section on noise analysis in MRI."

"Radiologic physics -- Concepts of radiologic science -- Radiologic quantities and units -- Fundamentals of physics -- The atom -- Electromagnetic radiation -- Electricity and magnetism -- Electromagnetism -- The x-ray beam -- The x-ray imaging system -- The x-ray tube -- X-ray production -- X-ray emission -- X-ray interaction with matter -- The radiographic image -- Radiographic film -- Processing the latent image -- Intensifying screens -- Beam-restricting devices -- The grid -- Radiation exposure -- Image quality -- Radiographic technique -- Special imaging methods -- Special x-ray imaging -- Mammography -- Mammography quality control -- Fluoroscopy -- Interventional radiology -- Introduction to computer science -- Digital radiography -- Digital fluoroscopy -- Computed tomography -- Spiral computed tomography -- Quality control -- Image artifacts -- Radiation protection -- Human biology -- Fundamental principles of radiobiology -- Molecular and cellular radiobiology -- Early effects of radiation -- Late effects of radiation -- Health physics -- Designing for radiation protection -- Radiation protection procedures"

"The seventh edition is the most radical revision of this textbook to date and now includes color figures, a visual transformation over the sixth edition. However, we were careful to retain the same format as the sixth edition, which divided the book into two parts. Part I contains 17 chapters and represents both a general introduction to radiation biology and a complete self-contained course in the subject, suitable for residents in diagnostic radiology and nuclear medicine. It follows the format of the Syllabus in Radiation Biology prepared by the Radiological Society of North America (RSNA), and its content reflects the questions appearing in recent years in the written examination for diagnostic radiology residents given by the American Board of Radiology. Part II consists of 11 chapters of more in-depth material designed primarily for residents in radiation oncology. We live in an exciting time, but yet a dangerous time as well. The threat of nuclear terror rears its head way too often. If such an event occurs, those trained in the radiation sciences will be called on to manage exposed individuals. For this reason, we have included a new chapter on Radiologic Terrorism (Chapter 14). The translation of molecular imaging into the clinic is moving at a rapid pace. Therefore, we also included a chapter on fundamental concepts in molecular imaging that involves ionizing radiation such as CAT scans and PET imaging to reflect these new advances and describe the underlying biologic principles for each of these technologies (Chapter 15). The subject of retreatment with radiotherapy is not covered in most textbooks, and, because of this void, we have dedicated a new chapter to this subject"

"This well-received book, now in its fifth edition, is unique in providing a detailed examination of the technological basis of radiation therapy. Another unique feature is that the chapters are jointly written by North American and European authors. This considerably broadens the book’s contents and increases its applicability in daily practice throughout the world. The book is divided into two sections. The first section covers basic concepts in treatment planning and explains the various approaches to radiation therapy, such as intensity-modulated radiation therapy, tomotherapy, stereotactic radiotherapy, and high and low dose rate brachytherapy. The second discusses in depth the practical clinical applications of the different radiation therapy techniques in a wide range of cancer sites. All chapters have been written by leaders in the field. "