In this study, we propose a novel noninvasive glucose detection approach based on diffused photon-pair density wave (DPPDW) and heterodyne interference technique. DPPDW is produced by correlated polarized photon-pairs (PPPs) at different temporal frequencies and a pair of parallel linear polarized states in a multiple scattering medium. Since the heterodyne signal is generated by PPPs based on spatial coherence and degree of polarization (DOP) properties simultaneously, therefore, the spatial coherence gating and the polarization gating are able to select the weak scattering PPPs out of multiple scattering photons in a multiple scattering medium. The signal to noise ratio (SNR) of amplitude and phase detection of the heterodyne signal has been improved by the features of coherent detection and common-path propagation of PPPs in a multiple scattering medium. Adding glucose to a multiple scattering medium will raise the refraction index of the medium and will consequently decrease the reduced scattering coefficient of the medium as a whole. The reduced scattering coefficient and the absorption coefficient are calculated by measurement of DPPDW and then correlate with the change of glucose concentration.