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Improving Glioma Drug Delivery: A Multifaceted Approach for Glioma Drug Development

2024; Elsevier BV; Volume: 208; Linguagem: Inglês

10.1016/j.phrs.2024.107390

1096-1186

Marybeth Yonk, Megan Amber Lim, Charee M. Thompson, Muhibullah S. Tora, Yuliya Lakhina, Yuhong Du, Kimberly Hoang, Annette M. Molinaro, Nicholas M. Boulis, Wael Hassaneen, Kecheng Lei,

Drug Transport and Resistance Mechanisms

Glioma is one of the most common central nervous system (CNS) cancers that can be found within the brain and the spinal cord. One of the pressing issues plaguing the development of therapeutics for glioma originates from the selective and semipermeable CNS membranes: the blood-brain barrier (BBB) and blood-spinal cord barrier (BSCB). It is difficult to bypass these membranes and target the desired cancerous tissue because the purpose of the BBB and BSCB is to filter toxins and foreign material from invading CNS spaces. There are currently four varieties of Food and Drug Administration (FDA)-approved drug treatment for glioma; yet these therapies have limitations including, but not limited to, relatively low transmission through the BBB/BSCB, despite pharmacokinetic characteristics that allow them to cross the barriers. Steps must be taken to improve the development of novel and repurposed glioma treatments through the consideration of pharmacological profiles and innovative drug delivery techniques. This review addresses current FDA-approved glioma treatment's gaps, shortcomings, and challenges. We then outline how incorporating computational BBB/BSCB models and innovative drug delivery mechanisms will help motivate clinical advancements in glioma drug delivery. Ultimately, considering these attributes will improve the process of novel and repurposed drug development in glioma and the efficacy of glioma treatment.