In this dissertation, we will develop the computational tools, on the basis of sampling entropy, to evaluate different patterns of complexity activation of the electroencephalography (EEG) in longitudinal changes in the Alzheimer's disease (AD) after the acetylcholinesterase inhibitor (AChE inhibitor). Alzheimer’s disease is the most common form of dementia. The cause and progression of AD are not well understood. One hypothesis is that AD is caused by reduced synthesis of the neurotransmitter, acetylcholine (ACh). AChE inhibitors are proved as an effective therapy. The diagnosis and evaluation in the early stage dementia is challenging in clinical medicine. Quantitative electroencephalographs (qEEG) provide a potential method to objectively quantify the cortical activations in AD, but they are too insensitive to probe the alteration of EEG in the early AD. The approximate entropy, which is a non-linear statistic and is able to quantify the irregularity of a time series, was significant lower in the bilateral temporal region in AD patients, in whom the basic pathology is hippocampus atrophy. But there were some bias in approximate entropy, such as inconsistent results, and depending on the data length. Therefore, in order to evaluate different patterns of complexity activation of the EEG in longitudinal changes in AD after the acetyl cholinesterase inhibitor therapy, it is necessary to develop a better method with the sampling entropy. However, a technical issue which has been ignored by most researchers is that the signal should be stationary. In order to resolve the non-stationarity of SaEn in EEG to improve the sensitivity, an empirical mode decomposition (EMD) was applied for detrending in this dissertation. Twenty-seven AD patients (9M/18F; mean age 74.0±1.5 years) were included. Their initial Minimal Mental Status Examination was 19.3±0.7. They received the first resting awake 30-mine EEG before the therapy. Five of them received a follow-up examination within 6 months after the therapy. The 30-s EEG data without artifacts were selected and analyzed with a new proposed method,“EMD-based detrended-SaEn” to attenuate the influence of intrinsic non-stationarity. The correlation factors in 27 AD patients showed a moderate correlation (0.361-0.523, p < 0.05) between MMSE and EMD-based detrended SaEn in Fp1, Fp2, F4 and T3. There was a high correlation (Correlation coefficient = 0.975, p < 0.05) between the changes of MMSE and the changes of EMD-based detrended-SaEn in F7 in 5 follow-up patients. The dynamic complexity of EEG fluctuations is degraded by pathological degeneration, and EMD-based detrended SaEn provides an objective, non-invasive and non-expensive tool for evaluating and following AD patients. The other issue, for clinician, it is still not predictable effect in individual patient. In this dissertation, we tried to use multiscale entropy (MSE) in EEG to predict the efficacy of AChE inhibitor. Seventeen newly diagnosed AD patients (9M/8F; mean age 74.6±7.4 years) were enrolled in this study, with an initial MMSE of 18.8±4.5. After 12 months’ therapy of AChE inhibitor, 7 patients (3M/4F; mean age 76.1±7.9 years) were responsive (responder) and 10 patients (6M/4F; 73.5±7.3 years) were non-responsive (non-responder). The major difference between two groups is Slope2 (MSE6 to 20). The area under curve (ROC curve) of Slope2 is 0.871(95% CI = 0.69 - 1). The sensitivity is 85.7% and the specificity is 60% while the cutoff value of Sloep2 is -0.024. MSE of EEG, especially Slope2, is able to be an objective tool to predict the efficacy of AChE inhibitor before the therapy. By the assistance of non-linear digital signal processing, the embedded information of EEG in AD could be extracted for the clinical evaluation, following up and even prediction the therapeutic effect.