The full exploitation of the physics potential of a multi-TeV muon collider will ultimately depend on the
detector's ability to cope with unprecedented levels of machine-induced backgrounds. This contribution
introduces the MUSIC (MUon System for Interesting Collisions) detector concept and presents its performance
in the context of $\sqrt{s} = 10$ TeV muon–antimuon collisions. The MUSIC detector is designed to mitigate
machine-induced background effects while maintaining high efficiency and accuracy in the reconstruction of
physics events, particularly in the Higgs boson sector and in searches for new physics. It features an
all-silicon tracking system, a semi-homogeneous lead-fluorite crystal electromagnetic calorimeter, an
iron–scintillator sampling hadronic calorimeter, and a superconducting magnet providing a 5 T magnetic field.
Detailed detector simulations including the dominant machine-induced backgrounds are presented. The results
demonstrate promising tracking efficiency, as well as muon, photon, electron, and jet reconstruction
capabilities, together with jet flavor identification performance, highlighting the strong potential of the
detector for high-energy muon collider experiments.