Continuous monitoring of chlorophyll-a (chl-a), whose shortage or excess leads to detrimental consequences on aquatic ecosystems, provides a better understanding of contamination sources to establish effective measures. Hyperspectral in-situ measurements at German inland waterbodies were used to estimate chl-a remotely. In this vein, Mixture Density Networks (MDNs) were employed, which outperformed other Machine Learning-based Regression (MLR) techniques due to their ability to handle ill-posed problems. Previous studies combined the predicted Gaussian functions of MDNs using maximum likelihood or simple averaging to estimate chl-a, which failed to effectively capture dependencies of multimodal distributions. To address this, Gaussian parameters of MDN were utilized to several Bayesian optimized MLRs, e.g., Support Vector Regressors (SVR), Random Forest (RF), and Gradient Boosting Regressors (GBR). The results revealed that integrating MDN with MLRs improved estimation of chl-a. The combination of MDN+RF showed the best performance with an improvement of 3.02 µg/L, 4.22%, and 0.054 for RMSE, MAPE, and RMSLE, respectively.