Your search keyword '"Zolfaghari-Nia A"' showing total 5 results

1. Machine Learning Models for Prediction of Soil Properties in the Riparian Forests

Author

Masoud Zolfaghari Nia, Mostafa Moradi, Gholamhosein Moradi, and Ruhollah Taghizadeh-Mehrjardi

Subjects

random forest, artificial neural networks, cubist, ancillary data, soil properties, Agriculture

Abstract

Spatial variability of soil properties is a critical factor for the planning, management, and exploitation of soil resources. Thus, the use of different digital soil mapping models to provide accuracy plays a crucial role in providing soil physicochemical properties maps. Soil spatial variability in forest stands is not well-known in Iran. Meanwhile, riparian buffers are important for several services such as providing high water quality, nutrient recycling, and buffering agricultural production. Accordingly, in this research, 103 soil samples were taken using the Latin hypercubic method in the Maroon riparian forest of Behbahan and agricultural lands in the vicinity of the forest to evaluate the spatial variability of soil nitrogen, potassium, organic carbon, C:N ratio, pH, calcium carbonate, sand, silt, clay, and bulk density. Different machine learning models, including artificial neural networks, random forest, cubist regression tree, and k-nearest neighbor were used to compare the estimation of soil properties. Moreover, three main sources of spatial information including remote sensing images, digital elevation model, and climate parameters were used as ancillary data. Our results indicated that the random forest model has the best results in estimating soil pH, nitrogen, potassium, and bulk density. In contrast, the cubist regression tree indicated the best estimation for organic carbon, C:N ratio, phosphorous, and clay. Further, artificial neural networks showed the best estimation for calcium carbonate, sand, and silt contents. Our results revealed that geospatial information such as terrain parameters, climate parameters, and satellite images could be well used as ancillary data for the spatial mapping of soil physiochemical properties in riparian forests and agricultural lands. In conclusion, a specific machine learning model needs to be used for each soil property to provide highly accurate maps with less error.

Published

2022

2. Regression of Left Ventricular Mass in Athletes Undergoing Complete Detraining Is Mediated by Decrease in Intracellular but Not Extracellular Compartments

Author

Swoboda, Peter P., Garg, Pankaj, Levelt, Eylem, Broadbent, David A., Zolfaghari-Nia, Ashkun, Foley, A. James R., Fent, Graham J., Chew, Pei G., Brown, Louise A., Saunderson, Christopher E., Dall’Armellina, Erica, Greenwood, John P., and Plein, Sven

Published

2019

3. Machine Learning Models for Prediction of Soil Properties in the Riparian Forests

Author

Zolfaghari Nia, Masoud, primary, Moradi, Mostafa, additional, Moradi, Gholamhosein, additional, and Taghizadeh-Mehrjardi, Ruhollah, additional

Published

2022

4. Machine Learning Models for Prediction of Soil Properties in the Riparian Forests.

Author

Zolfaghari Nia, Masoud, Moradi, Mostafa, Moradi, Gholamhosein, and Taghizadeh-Mehrjardi, Ruhollah

Subjects

RIPARIAN forests, MACHINE learning, DIGITAL soil mapping, ARTIFICIAL neural networks, FORESTS & forestry, GEOSPATIAL data

Abstract

Spatial variability of soil properties is a critical factor for the planning, management, and exploitation of soil resources. Thus, the use of different digital soil mapping models to provide accuracy plays a crucial role in providing soil physicochemical properties maps. Soil spatial variability in forest stands is not well-known in Iran. Meanwhile, riparian buffers are important for several services such as providing high water quality, nutrient recycling, and buffering agricultural production. Accordingly, in this research, 103 soil samples were taken using the Latin hypercubic method in the Maroon riparian forest of Behbahan and agricultural lands in the vicinity of the forest to evaluate the spatial variability of soil nitrogen, potassium, organic carbon, C:N ratio, pH, calcium carbonate, sand, silt, clay, and bulk density. Different machine learning models, including artificial neural networks, random forest, cubist regression tree, and k-nearest neighbor were used to compare the estimation of soil properties. Moreover, three main sources of spatial information including remote sensing images, digital elevation model, and climate parameters were used as ancillary data. Our results indicated that the random forest model has the best results in estimating soil pH, nitrogen, potassium, and bulk density. In contrast, the cubist regression tree indicated the best estimation for organic carbon, C:N ratio, phosphorous, and clay. Further, artificial neural networks showed the best estimation for calcium carbonate, sand, and silt contents. Our results revealed that geospatial information such as terrain parameters, climate parameters, and satellite images could be well used as ancillary data for the spatial mapping of soil physiochemical properties in riparian forests and agricultural lands. In conclusion, a specific machine learning model needs to be used for each soil property to provide highly accurate maps with less error. [ABSTRACT FROM AUTHOR]

Published

2023

5. Regression of left ventricular mass in athletes undergoing complete detraining is mediated by decrease in intracellular but not extracellular compartments

Author

Pankaj Garg, Erica Dall’Armellina, Peter P Swoboda, John P Greenwood, Louise A. E. Brown, Graham Fent, David A. Broadbent, Eylem Levelt, Christopher E.D. Saunderson, Sven Plein, Pei G. Chew, A. James R. Foley, and Ashkun Zolfaghari-Nia

Subjects

Adult, Male, medicine.medical_specialty, Adolescent, Physiology, Magnetic Resonance Imaging (MRI), Contrast Media, Muscle hypertrophy, Left ventricular mass, Electrocardiography, Internal medicine, Organometallic Compounds, Extracellular, medicine, Humans, magnetic resonance imaging, Radiology, Nuclear Medicine and imaging, Prospective Studies, Pathological, Cardiovascular Deconditioning, Ventricular Remodeling, medicine.diagnostic_test, biology, Athletes, business.industry, Correction, Diagnostic test, Magnetic resonance imaging, Original Articles, Middle Aged, biology.organism_classification, Adaptation, Physiological, athletes, England, Cardiology, Female, Hypertrophy, Left Ventricular, sports, Cardiology and Cardiovascular Medicine, business, hypertrophy, human activities, Intracellular

Abstract

Background: Athletic cardiac remodeling can occasionally be difficult to differentiate from pathological hypertrophy. Detraining is a commonly used diagnostic test to identify physiological hypertrophy, which can be diagnosed if hypertrophy regresses. We aimed to establish whether athletic cardiac remodeling assessed by cardiovascular magnetic resonance is mediated by changes in intracellular or extracellular compartments and whether this occurs by 1 or 3 months of detraining. Methods: Twenty-eight athletes about to embark on a period of forced detraining due to incidental limb bone fracture underwent clinical assessment, ECG, and contrast-enhanced cardiovascular magnetic resonance within a week of their injury and then 1 month and 3 months later. Results: After 1 month of detraining, there was reduction in left ventricular (LV) mass (130±28 to 121±25 g; P P =0.02), and extracellular volume fraction (24.5±2.3% to 26.0±2.6%; P =0.0007) with no further changes by 3 months. The decrease in LV mass was mediated by a decrease in intracellular compartment volume (94±22 to 85±19 mL; P Conclusions: Regression of athletic LV hypertrophy can be detected after just 1 month of complete detraining and is mediated by a decrease in the intracellular myocardial compartment with no change in the extracellular compartment. Further studies are needed in athletes with overt and pathological hypertrophy to establish whether native T1 and extracellular volume fraction may complement electrocardiography, echocardiography, cardiopulmonary exercise testing, and genetic testing in predicting the outcome of detraining.

Published

2019