The maximum likelihood detection (MLD) with QR decomposition and M-algorithm (QRM-MLD) is a near-optimal algorithm which can achieve a good tradeoff between error rate performance and complexity. However, the conventional QRM-MLD still requires high complexity in the high SNR (Signal to Noise Ratio) region. In this thesis, we propose an instantaneously-adaptive candidate selection scheme for the QRM-MLD algorithm in multiple-input multiple-output (MIMO) detection. First, in order to evaluate the reliability of each symbol candidate, we adopt a probability metric with normalized likelihood function of each symbol candidate in each detection layer. Then, the average simulated symbol error rate is used to be the error rate threshold. By means of decreasing the number of candidates with low reliability, a large amount of the computation for the path metric is avoided. Hence, the complexity of the proposed detection scheme can be reduced. Besides, we also analyze the effect of channel column norm ordering in QRM-MLD and adopt it into the proposed scheme. Simulation results show that the proposed scheme achieves the near-optimal error rate performance with significantly lower complexity. Our scheme reduces 46% to 71% computation for 4QAM (Quadrature Amplitude Modulation) and 16QAM in 4×4 MIMO systems as compared with the conventional QRM-MLD.