Compared with conventional photon radiotherapy, particle therapy offers distinct dosimetric advantages. Its unique dose distribution can effectively reduce damage to surrounding normal tissues and achieve a more conformal dose delivery. However, in clinical practice, uncertainties during the treatment process may diminish these advantages. The Compton camera, a novel γ-ray imaging technology, detects γ-rays of specific energies generated during particle therapy and thus holds promise for in vivo range verification, ultimately enabling real-time dose monitoring in particle therapy. This review begins with the imaging principles of Compton cameras and then provides an overview of current research progress in proton therapy, heavy-ion therapy, and boron neutron capture therapy.

Compared with conventional photon radiotherapy, particle therapy offers distinct dosimetric advantages. Its unique dose distribution can effectively reduce damage to surrounding normal tissues and achieve a more conformal dose delivery. However, in clinical practice, uncertainties during the treatment process may diminish these advantages. The Compton camera, a novel γ-ray imaging technology, detects γ-rays of specific energies generated during particle therapy and thus holds promise for in vivo range verification, ultimately enabling real-time dose monitoring in particle therapy. This review begins with the imaging principles of Compton cameras and then provides an overview of current research progress in proton therapy, heavy-ion therapy, and boron neutron capture therapy.