Zhang Haiyan, Chen Longjian, Lu Minsheng, Li Junbao, Han Lujia
College of Engineering, China Agricultural University (East Campus), P.O. Box 191, 17 Qing-Hua-Dong-Lu, Hai-Dian District, Beijing, 100083 People's Republic of China.
Biotechnol Biofuels. 2016 Aug 30;9(1):181. doi: 10.1186/s13068-016-0602-2. eCollection 2016.
Ultrafine grinding is an environmentally friendly pretreatment that can alter the degree of polymerization, the porosity and the specific surface area of lignocellulosic biomass and can, thus, enhance cellulose hydrolysis. Enzyme adsorption onto the substrate is a prerequisite for the enzymatic hydrolysis process. Therefore, it is necessary to investigate the enzyme adsorption properties of corn stover pretreated by ultrafine grinding.
The ultrafine grinding pretreatment was executed on corn stover. The results showed that ultrafine grinding pretreatment can significantly decrease particle size [from 218.50 μm of sieve-based grinding corn stover (SGCS) to 17.45 μm of ultrafine grinding corn stover (UGCS)] and increase the specific surface area (SSA), pore volume (PV) and surface composition (SSA: from 1.71 m(2)/g of SGCS to 2.63 m(2)/g of UGCS, PV: from 0.009 cm(3)/g of SGCS to 0.024 m(3)/g of UGCS, cellulose surface area: from 168.69 m(2)/g of SGCS to 290.76 m(2)/g of UGCS, lignin surface area: from 91.46 m(2)/g of SGCS to 106.70 m(2)/g of UGCS). The structure and surface composition changes induced by ultrafine grinding increase the enzyme adsorption capacity from 2.83 mg/g substrate of SGCS to 5.61 mg/g substrate of UGCS. A film-pore-surface diffusion model was developed to simultaneously predict the enzyme adsorption kinetics of both the SGCS and UGCS. Satisfactory predictions could be made with the model based on high R (2) and low RMSE values (R (2) = 0.95 and RMSE = 0.16 mg/g for the UGCS, R (2) = 0.93 and RMSE = 0.09 mg/g for the SGCS). The model was further employed to analyze the rate-limiting steps in the enzyme adsorption process. Although both the external-film and internal-pore mass transfer are important for enzyme adsorption on the SGCS and UGCS, the UGCS has a lower internal-pore resistance compared to the SGCS.
Ultrafine grinding pretreatment can enhance the enzyme adsorption onto corn stover by altering structure and surface composition. The film-pore-surface diffusion model successfully captures features on enzyme adsorption on ultrafine grinding pretreated corn stover. These findings identify wherein the probable rate-limiting factors for the enzyme adsorption reside and could, therefore, provide a basis for enhanced cellulose hydrolysis processes.
超细粉碎是一种环境友好型预处理方法,可改变木质纤维素生物质的聚合度、孔隙率和比表面积,从而提高纤维素水解效率。酶吸附到底物上是酶促水解过程的前提条件。因此,有必要研究经超细粉碎预处理的玉米秸秆的酶吸附特性。
对玉米秸秆进行了超细粉碎预处理。结果表明,超细粉碎预处理可显著降低粒径[从筛网粉碎玉米秸秆(SGCS)的218.50μm降至超细粉碎玉米秸秆(UGCS)的17.45μm],并增加比表面积(SSA)、孔体积(PV)和表面组成(SSA:从SGCS的1.71m²/g增至UGCS的2.63m²/g,PV:从SGCS的0.009cm³/g增至UGCS的0.024cm³/g,纤维素表面积:从SGCS的168.69m²/g增至UGCS的290.76m²/g,木质素表面积:从SGCS的91.46m²/g增至UGCS的106.70m²/g)。超细粉碎引起的结构和表面组成变化使酶吸附容量从SGCS底物的2.83mg/g增至UGCS底物的5.61mg/g。建立了膜-孔-表面扩散模型,以同时预测SGCS和UGCS的酶吸附动力学。基于较高的R²和较低的RMSE值,该模型能够做出令人满意的预测(UGCS的R² = 0.95,RMSE = 0.16mg/g;SGCS的R² = 0.93,RMSE = 0.09mg/g)。该模型进一步用于分析酶吸附过程中的限速步骤。尽管外部膜和内部孔传质对SGCS和UGCS上的酶吸附都很重要,但与SGCS相比,UGCS的内部孔阻力较低。
超细粉碎预处理可通过改变结构和表面组成来增强酶对玉米秸秆的吸附。膜-孔-表面扩散模型成功捕捉了超细粉碎预处理玉米秸秆上酶吸附的特征。这些发现确定了酶吸附可能的限速因素所在,因此可为增强纤维素水解过程提供依据。
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