This paper reviews the quad-porosity shale system, from a production standpoint. Understanding the complex but coupled flow mechanisms in such reservoirs is essential to design appropriate completions and further, optimally produce them. Dual-porosity and dual permeability models are most commonly used to describe a typical shale gas reservoir. Characterization of such reservoirs with extremely low permeability does not aptly capture the physics and complexities of gas storage and flow through their existing Nano-pores. This paper reviews the methods and experimental studies used to describe the flow mechanisms of gas through such systems, and critically recommend the direction in which this work could be extended. A quad porosity shale system is defined not just as porosity in the matrix and fracture, but a combination of multiple porosity values. It has been observed from studies conducted that shale gas production modeled with conventional simulator / model is seen to be much lower than actually observed in field data. This paper reviews the various flow mechanisms in shale Nano-pores by capturing the physics behind the actual process. The contribution of Knudson diffusion and gas slippage, gas desorption and gas diffusion from Kerogen to total production is studied in detail. Results observed from simulation runs indicate that the above effects should be considered while modeling and making production forecast for such reservoirs.