This study aimed to integrate a cost-effective approach on the conversion of rice straw into fermentable sugars and biobutanol production through Acetone-Butanol-Ethanol (ABE) fermentation. The optimal initial cell concentration and incubation temperature for ABE fermentation under both sterile and non-sterile conditions were resolved by central composite design and response surface methodology (CCD-RSM). Saccharification experiments of non-pretreated rice straw (NPRS), pretreated rice straw (PRS), and mixture of pretreated rice straw and acid hydrolysate (MPRSH) were conducted in a series of batch reactors. Glucose was the major product. The results show that the glucose yield of 0.52 g glucose/g rice straw for NPRS was compatible to those of 0.50 and 0.58 g glucose/g rice straw for PRS and MPRSH, respectively. Thus, the saccharification of the rice straw grinded only without other pretreatment is more cost-effective if concerning to save operating time, energy and chemical cost. Simulated NPRS hydrolysate contained 2.73 g/L arabinose, 28.10 g/L glucose, 10.00 g/L galactose, and 5.00 g/L acetic acid was then used as the medium for ABE fermentation batch experiments with pH 5.42±0.03 and 100 rpm agitation. Conventional ABE fermentations are conducted under sterile condition to avoid contaminations from other microbes. However, sterilization is one of the costly steps in conventional ABE fermentation. To evaluate the feasibility of non-sterile ABE fermentation, the fermentation experiments in this study were performed under sterile and non-sterile environmental conditions. The results from the batch experiments were used for determine the maximum butanol productivity, butanol yield, and butanol production rate estimated by the modified Gompertz equation. During the fermentation, glucose was easily and sharply utilized by Clostridium saccharoperbutylacetonicum N1-4 while arabinose was hardly utilized. Acetic acid was reutilized by cell to form butanol, acetone or ethanol. When batch experiments conducted under non-sterile condition, high initial cell concentration of C. saccharoperbutylacetonicum N1-4 can constrain the contaminations from other microbes and ensure the biobutanol production compatible with those under sterile condition. Low initial cell concentration (< 800 mg/L) or high incubation temperature (> 42 ℃) cause low biobutanol production. As results from the statistical approach by RSM, the maximum butanol productivity (1.45 g/L/d), butanol yield (0.22 g/g), and butanol production rate (4.05 g/L/d) were obtained at the initial cell concentrations and incubation temperatures of 1.96 g/L and 32.3℃, 2.01 g/L and 26.3℃, and 2.33 g/L and 30.5℃, respectively, under sterile condition. Meanwhile, under non-sterile condition, similar butanol productivity (1.45 g/L/d), butanol yield (0.32 g/g), and butanol production rate (3.74 g/L/d) could be achieved when the initial cell concentrations and incubation temperatures were controlled at 2.33 g/L and 26.4℃, 2.33 g/L and 25.0℃, and 2.33 g/L and 25.0℃, respectively. To overlook this study, the biobutanol production from non-pretreated rice straw powder can be achieved feasibly and economically under non-sterile environmental condition.