2022, Niedbała, Gniewko, Kurek, Jarosław, Świderski, Bartosz, Wojciechowski, Tomasz, Antoniuk, Izabella, Bobran, Krzysztof

In this paper, we present a high-accuracy model for blueberry yield prediction, trained using structurally innovative data sets. Blueberries are blooming plants, valued for their antioxidant and anti-inflammatory properties. Yield on the plantations depends on several factors, both internal and external. Predicting the accurate amount of harvest is an important aspect in work planning and storage space selection. Machine learning algorithms are commonly used in such prediction tasks, since they are capable of finding correlations between various factors at play. Overall data were collected from years 2016–2021, and included agronomic, climatic and soil data as well satellite-imaging vegetation data. Additionally, growing periods according to BBCH scale and aggregates were taken into account. After extensive data preprocessing and obtaining cumulative features, a total of 11 models were trained and evaluated. Chosen classifiers were selected from state-of-the-art methods in similar applications. To evaluate the results, Mean Absolute Percentage Error was chosen. It is superior to alternatives, since it takes into account absolute values, negating the risk that opposite variables will cancel out, while the final result outlines percentage difference between the actual value and prediction. Regarding the research presented, the best performing solution proved to be Extreme Gradient Boosting algorithm, with MAPE value equal to 12.48%. This result meets the requirements of practical applications, with sufficient accuracy to improve the overall yield management process. Due to the nature of machine learning methodology, the presented solution can be further improved with annually collected data.

2023, Türkoğlu, Aras, Haliloğlu, Kamil, Demirel, Fatih, Aydin, Murat, Çiçek, Semra, Yiğider, Esma, Demirel, Serap, Piekutowska, Magdalena, Szulc, Piotr, Niedbała, Gniewko

The objective of this study was to comprehend the efficiency of wheat regeneration, callus induction, and DNA methylation through the application of mathematical frameworks and artificial intelligence (AI)-based models. This research aimed to explore the impact of treatments with AgNO3 and Ag-NPs on various parameters. The study specifically concentrated on analyzing RAPD profiles and modeling regeneration parameters. The treatments and molecular findings served as input variables in the modeling process. It included the use of AgNO3 and Ag-NPs at different concentrations (0, 2, 4, 6, and 8 mg L−1). The in vitro and epigenetic characteristics were analyzed using several machine learning (ML) methods, including support vector machine (SVM), random forest (RF), extreme gradient boosting (XGBoost), k-nearest neighbor classifier (KNN), and Gaussian processes classifier (GP) methods. This study’s results revealed that the highest values for callus induction (CI%) and embryogenic callus induction (EC%) occurred at a concentration of 2 mg L−1 of Ag-NPs. Additionally, the regeneration efficiency (RE) parameter reached its peak at a concentration of 8 mg L−1 of AgNO3. Taking an epigenetic approach, AgNO3 at a concentration of 2 mg L−1 demonstrated the highest levels of genomic template stability (GTS), at 79.3%. There was a positive correlation seen between increased levels of AgNO3 and DNA hypermethylation. Conversely, elevated levels of Ag-NPs were associated with DNA hypomethylation. The models were used to estimate the relationships between the input elements, including treatments, concentration, GTS rates, and Msp I and Hpa II polymorphism, and the in vitro output parameters. The findings suggested that the XGBoost model exhibited superior performance scores for callus induction (CI), as evidenced by an R2 score of 51.5%, which explained the variances. Additionally, the RF model explained 71.9% of the total variance and showed superior efficacy in terms of EC%. Furthermore, the GP model, which provided the most robust statistics for RE, yielded an R2 value of 52.5%, signifying its ability to account for a substantial portion of the total variance present in the data. This study exemplifies the application of various machine learning models in the cultivation of mature wheat embryos under the influence of treatments and concentrations involving AgNO3 and Ag-NPs.

2025, Agho, Collins, Avni, Adi, Bacu, Ariola, Bakery, Ayat, Balazadeh, Salma, Baloch, Faheem Shehzad, Bazakos, Christos, Čereković, Nataša, Chaturvedi, Palak, Chauhan, Harsh, De Smet, Ive, Dresselhaus, Thomas, Ferreira, Liliana, Fíla, Jan, Fortes, Ana M., Fotopoulos, Vasileios, Francesca, Silvana, García-Perez, Pascual, Gong, Wen, Graci, Salvatore, Granell, Antonio, Gulyás, Andrea, Hidvégi, Norbert, Honys, David, Jankovska-Bortkevič, Elžbieta, Jonak, Claudia, Jurkonienė, Sigita, Kaiserli, Eirini, Kanwar, Meenakshi, Kavas, Musa, Koceska, Natasa, Koceski, Saso, Kollist, Hannes, Lakhneko, Olha, Lieberman-Lazarovich, Michal, Lukić, Nataša, Luyckx, Adrien, Mellidou, Ifigeneia, Mendes, Marta, Miras-Moreno, Begoña, Mirmazloum, Iman, Mladenov, Velimir, Mozafarian, Maryam, Mueller-Roeber, Bernd, Mühlemann, Joëlle, Munaiz, Eduardo D., Niedbała, Gniewko, Nieto, Cristina, Niinemets, Ülo, Papa, Stela, Pedreño, Maria, Piekutowska, Magdalena, Provelengiou, Stella, Quinet, Muriel, Radanović, Aleksandra, Resentini, Francesca, Rieu, Ivo, Rigano, Maria Manuela, Robert, Hélène S., Rojas, Laura I., Šamec, Dunja, Santos, Ana Paula, Schrumpfova, Petra P., Shalha, Boushra, Simm, Stefan, Spanic, Valentina, Stahl, Yvonne, Šućur, Rada, Vlachonasios, Κonstantinos E., Vraggalas, Stavros, Vriezen, Wim H., Wojciechowski, Tomasz, Fragkostefanakis, Sotirios

2023, Türkoğlu, Aras, Bolouri, Parisa, Haliloğlu, Kamil, Eren, Barış, Demirel, Fatih, Işık, Muhammet İslam, Piekutowska, Magdalena, Wojciechowski, Tomasz, Niedbała, Gniewko

A comprehensive understanding of genetic diversity and the categorization of germplasm is important to effectively identify appropriate parental candidates for the goal of breeding. It is necessary to have a technique of tissue culture that is both effective and reproducible to perform genetic engineering on fodder pea genotypes (Pisum sativum var. arvense L.). In this investigation, the genetic diversity of forty-two fodder pea genotypes was assessed based on their ability of callus induction (CI), the percentage of embryogenic callus by explant number (ECNEP), the percentage of responding embryogenic calluses by explant number (RECNEP), the number of somatic embryogenesis (NSE), the number of responding somatic embryogenesis (RSE), the regeneration efficiency (RE), and the number of regenerated plantlets (NRP). The findings of the ANOVA showed that there were significant differences (p < 0.001) between the genotypes for all in vitro parameters. The method of principal component analysis (PCA) was used to study the correlations that exist between the factors associated with tissue culture. While RE and NRP variables were most strongly associated with Doğruyol, Ovaçevirme-4, Doşeli-1, Yolgeçmez, and Incili-3 genotypes, RECNEP, NSE, RDE, and RECNEP variables were strongly associated with Avcılar, Ovaçevirme-3, and Ardahan Merkez-2 genotypes. The in vitro process is a complex multivariate process and more robust analyses are needed for linear and nonlinear parameters. Within the scope of this study, artificial neural network (ANN), random forest (RF), and multivariate adaptive regression spline (MARS) algorithms were used for RE estimation, and these algorithms were also compared. The results that we acquired from our research led us to the conclusion that the employed ANN-multilayer perceptron (ANN-MLP) model (R2 = 0.941) performs better than the RF model (R2 = 0.754) and the MARS model (R2 = 0.214). Despite this, it has been shown that the RF model is capable of accurately predicting RE in the early stages of the in vitro process. The current work is an inquiry regarding the use of RF, MARS, and ANN models in plant tissue culture, and it indicates the possibilities of application in a variety of economically important fodder peas.