Fu Jingjing, Wang Weijun, Sun Youmei, Zhang Yousen, Luo Qihao, Wang Zhongping, Wang Degang, Feng Yanwei, Xu Xiaohui, Cui Cuiju, Sun Guohua, Li Zan, Yang Jianmin
School of Agriculture, Ludong University, Yantai 264025, China.
Yantai Haiyu Marine Technology Co., Ltd., Yantai 264000, China.
Foods. 2024 Jul 11;13(14):2191. doi: 10.3390/foods13142191.
Near-infrared spectroscopy (NIR) has become an essential tool for non-destructive analysis in various fields, including aquaculture. This study presents a pioneering application of portable NIR spectrometers to analyze glycogen content in the gonadal tissues of the Pacific oyster (), marking the first instance of developing quantitative models for glycogen in tetraploid . The research also provides a comparative analysis with models for diploid and triploid oysters, underscoring the innovative use of portable NIR technology in aquaculture. Two portable NIR spectrometers were employed: the Micro NIR 1700 (908-1676 nm) and the Micro PHAZIR RX (1624-2460 nm). Near-infrared spectra were acquired from the gonadal tissues of diploid, triploid, and tetraploid . Quantitative models for glycogen content were developed and validated using cross-validation methods. Additionally, qualitative models for different ploidies and genders were established. For the Micro NIR 1700, the cross-validation correlation coefficients (Rcv) and cross-validation relative predictive errors (RPDcv) for glycogen were 0.949 and 3.191 for diploids, 0.915 and 2.498 for triploids, and 0.902 and 2.310 for tetraploids. The Micro PHAZIR RX achieved Rcv and RPDcv values of 0.781 and 2.240 for diploids, 0.839 and 2.504 for triploids, and 0.717 and 1.851 for tetraploids. The Micro NIR 1700 demonstrated superior quantitative performance, with RPD values exceeding 2, indicating its effectiveness in predicting glycogen content across different ploidy levels. Qualitative models showed a performance index of 91.6 for diploid and 95 for tetraploid genders using the Micro NIR 1700, while the Micro PHAZIR RX achieved correct identification rates of 99.79% and 100% for diploid and tetraploid genders, respectively. However, differentiation of ploidies was less successful with both instruments. This study's originality lies in establishing the first quantitative models for glycogen content in tetraploid using portable NIR spectrometers, highlighting the significant advancements in non-destructive glycogen analysis. The applicability of these findings is substantial for oyster breeding programs focused on enhancing meat quality traits. These models provide a valuable phenotyping tool for selecting oysters with optimal glycogen content, demonstrating the practical utility of portable NIR technology in aquaculture.
近红外光谱(NIR)已成为包括水产养殖在内的各个领域中进行无损分析的重要工具。本研究展示了便携式近红外光谱仪在分析太平洋牡蛎性腺组织中糖原含量方面的开创性应用,这是首次针对四倍体牡蛎糖原建立定量模型。该研究还对二倍体和三倍体牡蛎的模型进行了比较分析,突出了便携式近红外技术在水产养殖中的创新应用。使用了两台便携式近红外光谱仪:Micro NIR 1700(908 - 1676 nm)和Micro PHAZIR RX(1624 - 2460 nm)。从二倍体、三倍体和四倍体牡蛎的性腺组织中采集近红外光谱。使用交叉验证方法建立并验证了糖原含量的定量模型。此外,还建立了不同倍性和性别的定性模型。对于Micro NIR 1700,二倍体糖原的交叉验证相关系数(Rcv)和交叉验证相对预测误差(RPDcv)分别为0.949和3.191,三倍体为0.915和2.498,四倍体为0.902和2.310。Micro PHAZIR RX的二倍体Rcv和RPDcv值分别为0.781和2.240,三倍体为0.839和2.504,四倍体为0.717和1.851。Micro NIR 1700表现出卓越的定量性能,RPD值超过2,表明其在预测不同倍性水平的糖原含量方面有效。定性模型显示,使用Micro NIR 1700时,二倍体性别和四倍体性别的性能指标分别为91.6和95,而Micro PHAZIR RX对二倍体和四倍体性别的正确识别率分别为99.79%和100%。然而,两种仪器在区分倍性方面不太成功。本研究的创新性在于首次使用便携式近红外光谱仪建立四倍体牡蛎糖原含量的定量模型,突出了无损糖原分析的重大进展。这些研究结果对于专注于提高肉质性状的牡蛎育种计划具有重要的适用性。这些模型为选择糖原含量最佳的牡蛎提供了有价值的表型分析工具,证明了便携式近红外技术在水产养殖中的实际应用价值。
