Twitter Analysis of the Nonmedical Use and Side Effects of Methylphenidate: Machine Learning Study

Journals

1. Singh T, Roberts K, Cohen T, Cobb N, Wang J, Fujimoto K, Myneni S. Social Media as a Research Tool (SMaaRT) for Risky Behavior Analytics: Methodological Review. JMIR Public Health and Surveillance 2020;6(4):e21660 View
2. Alvarez-Mon M, Llavero-Valero M, Asunsolo del Barco A, Zaragozá C, Ortega M, Lahera G, Quintero J, Alvarez-Mon M. Areas of Interest and Attitudes Toward Antiobesity Drugs: Thematic and Quantitative Analysis Using Twitter. Journal of Medical Internet Research 2021;23(10):e24336 View
3. Kim M, Kim M, Kim J, Kim K. Fine-Tuning BERT Models to Classify Misinformation on Garlic and COVID-19 on Twitter. International Journal of Environmental Research and Public Health 2022;19(9):5126 View
4. Medina A, Kabani A, Reyes-Vasquez C, Dafny N. Age differences to methylphenidate-NAc neuronal and behavioral recordings from freely behaving animals. Journal of Neural Transmission 2022;129(8):1061 View
5. Schmitz F, Ferreira F, Silveira J, V. R. Júnior O, T. S. Wyse A. Effects of methylphenidate after a long period of discontinuation include changes in exploratory behavior and increases brain activities of Na+,K+-ATPase and acetylcholinesterase. Neurobiology of Learning and Memory 2022;192:107637 View
6. Purushothaman V, McMann T, Li Z, Cuomo R, Mackey T. Content and trend analysis of user-generated nicotine sickness tweets: A retrospective infoveillance study. Tobacco Induced Diseases 2022;20(March):1 View
7. Schmitz F, Silveira J, Venturin G, Greggio S, Schu G, Zimmer E, Da Costa J, Wyse A. Evidence That Methylphenidate Treatment Evokes Anxiety-Like Behavior Through Glucose Hypometabolism and Disruption of the Orbitofrontal Cortex Metabolic Networks. Neurotoxicity Research 2021;39(6):1830 View
8. Alex B, Whyte D, Duma D, Owen R, Fairley E. Classifying patient and professional voice in social media health posts. BMC Medical Informatics and Decision Making 2021;21(1) View
9. de Anta L, Alvarez-Mon M, Ortega M, Salazar C, Donat-Vargas C, Santoma-Vilaclara J, Martin-Martinez M, Lahera G, Gutierrez-Rojas L, Rodriguez-Jimenez R, Quintero J, Alvarez-Mon M. Areas of Interest and Social Consideration of Antidepressants on English Tweets: A Natural Language Processing Classification Study. Journal of Personalized Medicine 2022;12(2):155 View
10. Yuan A, King N, Kharas N, Yang P, Dafny N. The effect of environment on cross-sensitization between methylphenidate and amphetamine in female rats. Physiology & Behavior 2022;252:113845 View
11. Yuan A, Kharas N, King N, Yang P, Dafny N. Methylphenidate cross-sensitization with amphetamine is dose dependent but not age dependent. Behavioural Brain Research 2023;438:114178 View
12. Kasson E, Filiatreau L, Davet K, Kaiser N, Sirko G, Bekele M, Cavazos-Rehg P. Examining Symptoms of Stimulant Misuse and Community Support Among Members of a Recovery-Oriented Online Community. Journal of Psychoactive Drugs 2024;56(3):422 View
13. Yuan A, Claussen C, Jones Z, Tang B, Dafny N. Methylphenidate induces a different response in the dorsal raphe as compared to ventral tegmental area and locus coeruleus: behavioral and concomitant neuronal recordings in adult rats. Journal of Neural Transmission 2023;130(12):1579 View
14. Shin H, Yuniar C, Oh S, Purja S, Park S, Lee H, Kim E. The Adverse Effects and Nonmedical Use of Methylphenidate Before and After the Outbreak of COVID-19: Machine Learning Analysis. Journal of Medical Internet Research 2023;25:e45146 View
15. Reyes-Vasquez C, Jones Z, Tang B, Dafny N. Dopamine, Norepinephrine and Serotonin Participate Differently in Methylphenidate Action in Concomitant Behavioral and Ventral Tegmental Area, Locus Coeruleus and Dorsal Raphe Neuronal Study in Young Rats. International Journal of Molecular Sciences 2023;24(23):16628 View
16. Mayer B, Kringel D, Lötsch J. Artificial intelligence and machine learning in clinical pharmacological research. Expert Review of Clinical Pharmacology 2024;17(1):79 View
17. Kwon J, Kim J, Lim K, Kim M. Integration of the Natural Language Processing of Structural Information Simplified Molecular-Input Line-Entry System Can Improve the In Vitro Prediction of Human Skin Sensitizers. Toxics 2024;12(2):153 View
18. Dafny N, Claussen C, Frazier E, Liu Y. Differential Roles of Key Brain Regions: Ventral Tegmental Area, Locus Coeruleus, Dorsal Raphe, Nucleus Accumbens, Caudate Nucleus, and Prefrontal Cortex in Regulating Response to Methylphenidate: Insights from Neuronal and Behavioral Studies in Freely Behaving Rats. International Journal of Molecular Sciences 2024;25(11):5938 View
19. Rieder A, Ramires Júnior O, Prauchner G, Wyse A. Effects of methylphenidate on mitochondrial dynamics and bioenergetics in the prefrontal cortex of juvenile rats are sex-dependent. Progress in Neuro-Psychopharmacology and Biological Psychiatry 2024;134:111057 View
20. Lamy F, Meemon N. Exploring Twitter chatter to assess the type and availability of cannabis-related products in Thailand. Journal of Ethnicity in Substance Abuse 2024:1 View
21. Dafny N, Elizondo G, Perez-Vasquez C. Differential Impact of Serotonin Signaling Methylphenidate on Young versus Adult: Insights from Behavioral and Dorsal Raphe Nucleus Neuronal Recordings from Freely Behaving Rats. International Journal of Molecular Sciences 2024;25(15):8082 View
22. Schmitz F, Durán-Carabali L, Rieder A, Silveira J, Ramires Junior O, Bobermin L, Quincozes-Santos A, Alves V, Coutinho-Silva R, Savio L, Coelho D, Vargas C, Netto C, Wyse A. Methylphenidate Exposing During Neurodevelopment Alters Amino Acid Profile, Astrocyte Marker and Glutamatergic Excitotoxicity in the Rat Striatum. Neurotoxicity Research 2024;42(5) View