Syed Abdullah Basit scite author profile

COVID-19 has taken a huge toll on our lives over the last 3 years. Global initiatives put forward by all stakeholders are still in place to combat this pandemic and help us learn lessons for future ones. While the vaccine rollout was not able to curb the spread of the disease for all strains, the research community is still trying to develop effective therapeutics for COVID-19. Although Paxlovid and remdesivir have been approved by the FDA against COVID-19, they are not free of side effects. Therefore, the search for a therapeutic solution with high efficacy continues in the research community. To support this effort, in this latest version (v3) of COVID-19Base, we have summarized the biomedical entities linked to COVID-19 that have been highlighted in the scientific literature after the vaccine rollout. Eight different topic-specific dictionaries, i.e., gene, miRNA, lncRNA, PDB entries, disease, alternative medicines registered under clinical trials, drugs, and the side effects of drugs, were used to build this knowledgebase. We have introduced a BLSTM-based deep-learning model to predict the drug-disease associations that outperforms the existing model for the same purpose proposed in the earlier version of COVID-19Base. For the very first time, we have incorporated disease-gene, disease-miRNA, disease-lncRNA, and drug-PDB associations covering the largest number of biomedical entities related to COVID-19. We have provided examples of and insights into different biomedical entities covered in COVID-19Base to support the research community by incorporating all of these entities under a single platform to provide evidence-based support from the literature. COVID-19Base v3 can be accessed from: https://covidbase-v3.vercel.app/. The GitHub repository for the source code and data dictionaries is available to the community from: https://github.com/91Abdullah/covidbasev3.0.

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Machine learning based personalized drug response prediction for lung cancer patients

Qureshi

Basit

Shamsi

et al. 2022

Sci Rep

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Lung cancers with a mutated epidermal growth factor receptor (EGFR) are a major contributor to cancer fatalities globally. Targeted tyrosine kinase inhibitors (TKIs) have been developed against EGFR and show encouraging results for survival rate and quality of life. However, drug resistance may affect treatment plans and treatment efficacy may be lost after about a year. Predicting the response to EGFR-TKIs for EGFR-mutated lung cancer patients is a key research area. In this study, we propose a personalized drug response prediction model (PDRP), based on molecular dynamics simulations and machine learning, to predict the response of first generation FDA-approved small molecule EGFR-TKIs, Gefitinib/Erlotinib, in lung cancer patients. The patient’s mutation status is taken into consideration in molecular dynamics (MD) simulation. Each patient’s unique mutation status was modeled considering MD simulation to extract molecular-level geometric features. Moreover, additional clinical features were incorporated into machine learning model for drug response prediction. The complete feature set includes demographic and clinical information (DCI), geometrical properties of the drug-target binding site, and the binding free energy of the drug-target complex from the MD simulation. PDRP incorporates an XGBoost classifier, which achieves state-of-the-art performance with 97.5% accuracy, 93% recall, 96.5% precision, and 94% F1-score, for a 4-class drug response prediction task. We found that modeling the geometry of the binding pocket combined with binding free energy is a good predictor for drug response. However, we observed that clinical information had a little impact on the performance of the model. The proposed model could be tested on other types of cancers. We believe PDRP will support the planning of effective treatment regimes based on clinical-genomic information. The source code and related files are available on GitHub at: https://github.com/rizwanqureshi123/PDRP/.

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Survival prediction of lung cancer patients by integration of clinical and molecular features using machine learning

Basit

Qureshi

Shahid

et al. 2021

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Applying different Feature Selection and Classification Parameters for Categorization

Basit¹,

Qiang²,

Abdul³

et al. 2019

IJCA

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In today's data-intensive world, millions of data is generated, processed and transferred, The main factors for the generation of data is an increase in the usage of social media and so is the increase in data mining methodologies. Text Classification is one of the most important aspects of data mining which includes fetching of data, pre-processing it and then applying classifiers to divide the data into the categories so as it would be easy to process and subject to further experimentation. In this paper, data is subjected through certain feature selection techniques enhancing its parameters and then applied multiple Machine Learning classifiers on it so as to study various parameters of the data which include accuracy, precision and various averages. The impact of increasing or decreasing the categories for classification of text on accuracy through various classifiers is studied which include Naive Bayes, Support Vector Machine and K-Nearest Neighbour and also the combination of individual classifiers in an ensemble classifier. In this research the internal parameters of Feature Selection Techniques and classifiers are also changed which lead to a slightest increase in overall accuracy of the classifier. Reducing different categories also increases accuracy to a greater extent because it also reduces the presence of multiple similar categories which lead to decrease in overall accuracy. Certain changes in the feature selection parameters are also included which is trying algorithms on uni-gram, bi-gram and tri-gram models and out of which bi-gram shows the best overall accuracy result with Support Vector Machine classifier.

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