PMID- 34655249
OWN - NLM
STAT- MEDLINE
DCOM- 20211216
LR  - 20211216
IS  - 2473-4209 (Electronic)
IS  - 0094-2405 (Linking)
VI  - 48
IP  - 12
DP  - 2021 Dec
TI  - Optimization of treatment isocenter location in single-isocenter LINAC-based 
      stereotactic radiosurgery for management of multiple brain metastases.
PG  - 7632-7640
LID - 10.1002/mp.15294 [doi]
AB  - PURPOSE: Single-isocenter linear accelerator (LINAC)-based stereotactic 
      radiosurgery (SRS) has become a promising treatment technique for the management 
      of multiple brain metastases. Because of the high prescription dose and steep 
      dose gradient, SRS plans are sensitive to geometric errors, resulting in loss of 
      target coverage and suboptimal local tumor control. Current planning techniques 
      rely on adding a uniform and isotropic setup margin to all gross tumor volumes 
      (GTVs) to account for rotational uncertainties. However, this setup margin may be 
      insufficient, since the magnitude of rotational uncertainties varies and is 
      dependent upon the distance between a GTV and the isocenter. In this study, we 
      designed a framework to determine the optimal isocenter of a single-isocenter SRS 
      plan for multiple brain metastases using stochastic optimization to mitigate 
      potential errors resulting from rotational uncertainties. METHODS: Planning 
      target volumes (PTVs), defined as GTVs plus a 1-mm margin following common SRS 
      planning convention, were assumed to be originally treated with a prescription 
      dose and therefore covered by the prescription isodose cloud. The dose 
      distribution, including the prescription isodose, was considered invariant 
      assuming small rotations throughout the study. A stochastic optimization scheme 
      was developed to determine the location of the optimal isocenter, so that the 
      prescription dose coverage of rotated GTVs, equivalent to the intersecting 
      volumes between the rotated GTVs and original PTVs, was maximized for any random 
      small rotations about the isocenter. To evaluate the coverage of GTVs, the 
      expected V100% undergoing random rotations was approximated as the sample average 
      V100% undergoing a predetermined number of rotations. The expected V100% of each 
      individual GTV and total GTVs was then compared between the plans using the 
      optimal isocenter and the center-of-mass (CoM), respectively. RESULTS: Twenty-two 
      patients previously treated for multiple brain metastases in a single institute 
      were included in this retrospective study. Each patient was initially treated for 
      more than three brain metastases (mean: 7.6; range: 3-15) with the average GTV 
      volume of 0.89 cc (range: 0.03-11.78 cc). The optimal isocenter found for each 
      patient was significantly different from the CoM, with the average Euclidean 
      distance between the optimal isocenter and the CoM being 4.36 +/- 2.59 cm. The dose 
      coverage to GTVs was also significantly improved (paired t-test; p < 0.001) when 
      the optimal isocenter was used, with the average V100% of total GTVs increasing 
      from 87.1% (standard deviation as std: 11.7%; range: 39.9-98.2%) to 94.2% (std: 
      5.4%; range: 77.7-99.4%). The volume of a GTV was positively correlated with the 
      expected V100% regardless of the isocenter used (Spearman coefficient: rho =  0.66 
      ; p < 0.001). The distance between a GTV and the isocenter was negatively 
      correlated with the expected V100% when the CoM was used ( rho =  - 0.21 ; 
      p = 0.004), however no significant correlation was found when the optimal 
      isocenter was used ( rho =  - 0.11 ; p = 0.137). CONCLUSION: The proposed framework 
      provides an effective approach to determine the optimal isocenter of 
      single-isocenter LINAC-based SRS plans for multiple brain metastases. The 
      implementation of the optimal isocenter results in SRS plans with consistently 
      higher target coverage despite potential rotational uncertainties, and therefore 
      significantly improves SRS plan robustness against random rotational 
      uncertainties.
CI  - (c) 2021 American Association of Physicists in Medicine.
FAU - Cui, Taoran
AU  - Cui T
AD  - Department of Radiation Oncology, Rutgers Cancer Institute of New Jersey, New 
      Brunswick, New Jersey, USA.
FAU - Zhou, Yongkang
AU  - Zhou Y
AD  - Department of Radiation Oncology, Zhongshan Hospital, Shanghai, China.
FAU - Yue, Ning J
AU  - Yue NJ
AD  - Department of Radiation Oncology, Rutgers Cancer Institute of New Jersey, New 
      Brunswick, New Jersey, USA.
FAU - Vergalasova, Irina
AU  - Vergalasova I
AD  - Department of Radiation Oncology, Rutgers Cancer Institute of New Jersey, New 
      Brunswick, New Jersey, USA.
FAU - Zhang, Yin
AU  - Zhang Y
AD  - Department of Radiation Oncology, Rutgers Cancer Institute of New Jersey, New 
      Brunswick, New Jersey, USA.
FAU - Zhu, Jiahua
AU  - Zhu J
AD  - Department of Radiation Oncology, Rutgers Cancer Institute of New Jersey, New 
      Brunswick, New Jersey, USA.
FAU - Nie, Ke
AU  - Nie K
AD  - Department of Radiation Oncology, Rutgers Cancer Institute of New Jersey, New 
      Brunswick, New Jersey, USA.
LA  - eng
PT  - Journal Article
DEP - 20211029
PL  - United States
TA  - Med Phys
JT  - Medical physics
JID - 0425746
SB  - IM
MH  - *Brain Neoplasms/diagnostic imaging/radiotherapy/surgery
MH  - Humans
MH  - *Radiosurgery
MH  - Radiotherapy Dosage
MH  - Radiotherapy Planning, Computer-Assisted
MH  - Retrospective Studies
EDAT- 2021/10/17 06:00
MHDA- 2021/12/17 06:00
CRDT- 2021/10/16 08:35
PHST- 2021/09/20 00:00 [revised]
PHST- 2021/12/08 00:00 [received]
PHST- 2021/10/06 00:00 [accepted]
PHST- 2021/10/17 06:00 [pubmed]
PHST- 2021/12/17 06:00 [medline]
PHST- 2021/10/16 08:35 [entrez]
AID - 10.1002/mp.15294 [doi]
PST - ppublish
SO  - Med Phys. 2021 Dec;48(12):7632-7640. doi: 10.1002/mp.15294. Epub 2021 Oct 29.