A central principle in quantum mechanics is that all operators that are associated with observables have to be Hermitian, to ensure real eigenvalues. Surprisingly, it turned out that there exists a class of Hamiltonians which are non-Hermitian yet still possess real eigenvalues. These describe PT-symmetric materials, which are systems that are invariant under the combined operations of parity inversion and time reversal. Moreover, through tuning of a physical parameter, it is possible to induce a phase transition in which the PT symmetry breaks at an exceptional point, rendering the eigenvalue spectrum of the system complex. What implications PT symmetry has for quantum physics is still under debate. Yet, mapped onto a photonic platform, various unusual effects onto the evolution of light have already been demonstrated and the concept even found its way to applications in lasers, optical diodes and sensing. While these experiments have been inspired by quantum mechanical concepts, they have been purely classical so far. Quantum evolution of light in PT-symmetric systems is still completely unexplored territory, with lots of new physics to be unravelled. Therefore, the objective of this action was to experimentally investigate the evolution of quantum states in PT-symmetric systems. This was carried out by implementing quantum walks of multiple correlated photons injected in PT-symmetric photonic integrated circuits fabricated using femtosecond-laser direct writing technology.