Litcius/Paper detail

Modeling of Modulated Exosome Release From Differentiated Induced Neural Stem Cells for Targeted Drug Delivery

Mladen Veletić, Michael Taynnan Barros, Hamidreza Arjmandi, Sasitharan Balasubramaniam, Ilangko Balasingham

2020IEEE Transactions on NanoBioscience24 citationsDOIOpen Access PDF

Abstract

A novel implantable and externally controllable stem-cell-based platform for the treatment of Glioblastoma brain cancer has been proposed to bring hope to patients who suffer from this devastating cancer type. Induced Neural Stem Cells (iNSCs), known to have potent therapeutic effects through exosomes-based molecular communication, play a pivotal role in this platform. Transplanted iNSCs demonstrate long-term survival and differentiation into neurons and glia which then fully functionally integrate with the existing neural network. Recent studies have shown that specific types of calcium channels in differentiated neurons and astrocytes are inhibited or activated upon cell depolarization leading to the increased intracellular calcium concentration levels which, in turn, interact with mobilization of multivesicular bodies and exosomal release. In order to provide a platform towards treating brain cancer with the optimum therapy dosage, we propose mathematical models to compute the therapeutic exosomal release rate that is modulated by cell stimulation patterns applied from the external wearable device. This study serves as an initial and required step in the evaluation of controlled exosomal secretion and release via induced stimulation with electromagnetic, optical and/or ultrasonic waves.

Topics & Concepts

MicrovesiclesExosomeNeural stem cellDrug deliveryStem cellNeuroscienceCancer cellSecretionCell biologyStimulationCell typeCellDepolarizationCancer researchCancerBiologymicroRNAMedicineMaterials scienceNanotechnologyBiophysicsInternal medicineBiochemistryGeneMolecular Communication and NanonetworksNeuroscience and Neural Engineeringstochastic dynamics and bifurcation