TY - JOUR
T1 - Developing Innovative, Robust and Affordable Medical Linear Accelerators for Challenging Environments
AU - Dosanjh, M.
AU - Aggarwal, A.
AU - Pistenmaa, D.
AU - Amankwaa-Frempong, E.
AU - Angal-Kalinin, D.
AU - Boogert, S.
AU - Brown, D.
AU - Carlone, M.
AU - Collier, P.
AU - Court, L.
AU - Di Meglio, A.
AU - Van Dyk, J.
AU - Grover, S.
AU - Jaffray, D.A.
AU - Jamieson, C.
AU - Khader, J.
AU - Konoplev, I.
AU - Makwani, H.
AU - McIntosh, P.
AU - Militsyn, B.
AU - Palta, J.
AU - Sheehy, S.
AU - Aruah, S.C.
AU - Syratchev, I.
AU - Zubizarreta, E.
AU - Coleman, C.N.
PY - 2019/6
Y1 - 2019/6
N2 - The annual global incidence of cancer is projected to rise in 2035 to 25 million cases (13 million deaths), with 70% occurring in low- and middle-income countries (LMICs), where there is a severe shortfall in the availability of radiotherapy [[1]] – an essential component of overall curative and palliative cancer care. A 2015 report by the Global Task Force on Radiotherapy for Cancer Control estimated that by 2035 at least 5000 additional megavolt treatment machines would be needed to meet LMIC demands, together with about 30 000 radiation oncologists, 22 000 medical physicists and 80 000 radiation therapy technologists [[2]]. Among the main reasons for the shortfall identified in the workshop and thoroughly discussed in the Clinical Oncology special issue on radiotherapy in LMICs [[3]] are: (i) the initial cost of linear accelerators, (ii) the cost of service on the machines and (iii) a shortage of trained personnel needed to deliver safe, effective and high-quality treatment. A number of authors who contributed to the Clinical Oncology special issue are participating in the CERN, International Cancer Expert Corps (ICEC), Science and Technology Facilities Council (STFC) collaborative effort described in this editorial (Aggarwal, Coleman, Court, Grover, Palta, Van Dyk and Zubizarreta).
AB - The annual global incidence of cancer is projected to rise in 2035 to 25 million cases (13 million deaths), with 70% occurring in low- and middle-income countries (LMICs), where there is a severe shortfall in the availability of radiotherapy [[1]] – an essential component of overall curative and palliative cancer care. A 2015 report by the Global Task Force on Radiotherapy for Cancer Control estimated that by 2035 at least 5000 additional megavolt treatment machines would be needed to meet LMIC demands, together with about 30 000 radiation oncologists, 22 000 medical physicists and 80 000 radiation therapy technologists [[2]]. Among the main reasons for the shortfall identified in the workshop and thoroughly discussed in the Clinical Oncology special issue on radiotherapy in LMICs [[3]] are: (i) the initial cost of linear accelerators, (ii) the cost of service on the machines and (iii) a shortage of trained personnel needed to deliver safe, effective and high-quality treatment. A number of authors who contributed to the Clinical Oncology special issue are participating in the CERN, International Cancer Expert Corps (ICEC), Science and Technology Facilities Council (STFC) collaborative effort described in this editorial (Aggarwal, Coleman, Court, Grover, Palta, Van Dyk and Zubizarreta).
UR - http://www.scopus.com/inward/record.url?eid=2-s2.0-85061825522&partnerID=MN8TOARS
U2 - 10.1016/j.clon.2019.02.002
DO - 10.1016/j.clon.2019.02.002
M3 - Article
SN - 0936-6555
VL - 31
SP - P352-355
JO - Clinical Oncology
JF - Clinical Oncology
IS - 6
ER -