Investigating structural and dynamic changes in cellulose due to nanocrystallization.

IF 1.3 3区生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY

Journal of Biomolecular NMR Pub Date : 2025-07-16 DOI:10.1007/s10858-025-00472-z

Bijay Laxmi Pradhan, Prince Sen, Krishna Kishor Dey, Manasi Ghosh

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引用次数: 0

Abstract

Cellulose nanocrystals (CNCs) is synthesized from alpha-cellulose by acid hydrolysis method, and formation of nanocrystallization is comprised by using various microscopic and spectroscopic techniques like PXRD, XPS, Raman, FTIR, PL, UV-Vis, DSC, TGA, DLS, SEM, TEM. Nanocrystalline cellulose shows a notably higher photoluminescence (PL) intensity than cellulose, which enhances its ability to absorb and emit visible light. This increase in PL intensity is attributed to a smaller particle size of CNCs, greater surface area, and quantum confinement effects. The higher intensity of the XPS spectrum further supports the larger surface area of CNCs. PXRD and Raman spectroscopy results show that CNCs has a higher crystallinity index than cellulose. Through deconvolution of the ¹³C CP-MAS SSNMR spectrum, we confirmed a significant reduction in the relative abundance of the amorphous region of cellulose (43.61%) to just 4.97% in CNCs. The ¹³C CP-MAS SSNMR spectrum of CNCs, at the C4, C6, C2C3C5 nuclei sites, can be fitted by two distinct lines for both amorphous and crystalline region, indicating the formation of a co-crystal from two nanocrystallites. Despite this, the principal components of the CSA (chemical shift anisotropy) tensor remain unchanged, suggesting similar electronic environments for these two nanocrystallites. The spin-lattice relaxation time and local correlation time of cellulose and CNCs are determined for chemically distinct carbon nuclei residing on D-glucopyranose units. It is noteworthy that the ¹³C spin-lattice relaxation time and ¹³C local correlation time are longer for each chemically distinct nucleus in CNCs compared to cellulose. It can be predicted by observing the NMR relaxometry data that the longer relaxation time in CNCs is due to the enhancement of crystallinity index. Hence, a correlation between the crystallinity index and nuclear spin dynamics can be established by NMR relaxometry measurements. These findings offer significant insights into the intricate structure and dynamic behavior of cellulose and nanocrystalline cellulose (CNCs), crucial for advancing biomimetic material design, which has huge applications across the pharmaceutical, textile, and cosmetics industries.

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研究纳米结晶引起的纤维素结构和动态变化。

以α -纤维素为原料，采用酸水解法制备了纤维素纳米晶（CNCs），并采用PXRD、XPS、Raman、FTIR、PL、UV-Vis、DSC、TGA、DLS、SEM、TEM等多种显微和光谱技术对纳米晶的形成进行了分析。纳米晶纤维素的光致发光强度明显高于纤维素，增强了其吸收和发射可见光的能力。这种PL强度的增加归因于更小的cnc颗粒尺寸，更大的表面积和量子限制效应。更高的XPS光谱强度进一步支持了cnc的更大表面积。PXRD和拉曼光谱分析结果表明，碳纳米管的结晶度高于纤维素。通过对13C CP-MAS SSNMR光谱的反卷积，我们证实纤维素无定形区域的相对丰度（43.61%）在cnc中显著降低至4.97%。在C4， C6， C2C3C5核位上，CNCs的13C CP-MAS SSNMR谱可以用两条不同的线来拟合非晶区和晶区，表明两个纳米晶形成了共晶。尽管如此，CSA（化学位移各向异性）张量的主成分保持不变，表明这两种纳米晶体的电子环境相似。纤维素和cnc的自旋晶格弛豫时间和局部相关时间被确定为化学上不同的碳核驻留在D-glucopyranose单元。值得注意的是，与纤维素相比，CNCs中每个化学性质不同的核的13C自旋晶格弛豫时间和13C局部相关时间更长。通过观察核磁共振弛豫数据可以预测，cnc中较长的弛豫时间是由于结晶度指数的增强。因此，结晶度指数和核自旋动力学之间的相关性可以通过核磁共振弛豫测量来建立。这些发现为纤维素和纳米晶纤维素（CNCs）复杂的结构和动态行为提供了重要的见解，这对于推进仿生材料的设计至关重要，在制药、纺织和化妆品行业有着巨大的应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Biomolecular NMR 生物-光谱学

CiteScore

6.00

自引率

3.70%

发文量

审稿时长

6-12 weeks

期刊介绍： The Journal of Biomolecular NMR provides a forum for publishing research on technical developments and innovative applications of nuclear magnetic resonance spectroscopy for the study of structure and dynamic properties of biopolymers in solution, liquid crystals, solids and mixed environments, e.g., attached to membranes. This may include: Three-dimensional structure determination of biological macromolecules (polypeptides/proteins, DNA, RNA, oligosaccharides) by NMR. New NMR techniques for studies of biological macromolecules. Novel approaches to computer-aided automated analysis of multidimensional NMR spectra. Computational methods for the structural interpretation of NMR data, including structure refinement. Comparisons of structures determined by NMR with those obtained by other methods, e.g. by diffraction techniques with protein single crystals. New techniques of sample preparation for NMR experiments (biosynthetic and chemical methods for isotope labeling, preparation of nutrients for biosynthetic isotope labeling, etc.). An NMR characterization of the products must be included.