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Open AccessArticle

Development of a 3D Printed Brain Model with Vasculature for Neurosurgical Procedure Visualisation and Training

by Manuel Encarnacion Ramirez, Issael Ramirez Pena, Rossi E. Barrientos Castillo, Albert Sufianov, Evgeniy Goncharov, Jose A. Soriano Sanchez, Manuel Colome-Hidalgo, Renat Nurmukhametov, José Rafael Cerda Céspedes and Nicola Montemurro

Biomedicines 2023, 11(2), 330; https://doi.org/10.3390/biomedicines11020330 - 24 Jan 2023

Cited by 40 | Viewed by 4850

Abstract

Background: Simulation-based techniques using three-dimensional models are gaining popularity in neurosurgical training. Most pre-existing models are expensive, so we felt a need to develop a real-life model using 3D printing technology to train in endoscopic third ventriculostomy. Methods: The brain model was made using a 3D-printed resin mold from patient-specific MRI data. The mold was filled with silicone Ecoflex™ 00-10 and mixed with Silc Pig^® pigment additives to replicate the color and consistency of brain tissue. The dura mater was made from quick-drying silicone paste admixed with gray dye. The blood vessels were made from a silicone 3D-printed mold based on magnetic resonance imaging. Liquid containing paprika oleoresin dye was used to simulate blood and was pumped through the vessels to simulate pulsatile motion. Results: Seven residents and eight senior neurosurgeons were recruited to test our model. The participants reported that the size and anatomy of the elements were very similar to real structures. The model was helpful for training neuroendoscopic 3D perception and navigation. Conclusions: We developed an endoscopic third ventriculostomy training model using 3D printing technology that provides anatomical precision and a realistic simulation. We hope our model can provide an indispensable tool for young neurosurgeons to gain operative experience without exposing patients to risk. Full article

(This article belongs to the Special Issue Trends in 3D Printing Processes for Biomedical Field: Opportunities and Challenges)

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12 pages, 3521 KB

Open AccessFeature PaperArticle

Distinct Effector Programs of Brain-Homing CD8⁺ T Cells in Multiple Sclerosis

by Steven C. Koetzier, Jamie van Langelaar, Marie-José Melief, Annet F. Wierenga-Wolf, Cato E. A. Corsten, Katelijn M. Blok, Cindy Hoeks, Bieke Broux, Beatrijs Wokke, Marvin M. van Luijn and Joost Smolders

Cells 2022, 11(10), 1634; https://doi.org/10.3390/cells11101634 - 13 May 2022

Cited by 13 | Viewed by 4868

Abstract

The effector programs of CD8⁺ memory T cells are influenced by the transcription factors RUNX3, EOMES and T-bet. How these factors define brain-homing CD8⁺ memory T cells in multiple sclerosis (MS) remains unknown. To address this, we analyzed blood, CSF and brain tissues from MS patients for the impact of differential RUNX3, EOMES and T-bet expression on CD8⁺ T cell effector phenotypes. The frequencies of RUNX3- and EOMES-, but not T-bet-expressing CD8⁺ memory T cells were reduced in the blood of treatment-naïve MS patients as compared to healthy controls. Such reductions were not seen in MS patients treated with natalizumab (anti-VLA-4 Ab). We found an additional loss of T-bet in RUNX3-expressing cells, which was associated with the presence of MS risk SNP rs6672420 (RUNX3). RUNX3⁺EOMES⁺T-bet⁻ CD8⁺ memory T cells were enriched for the brain residency-associated markers CCR5, granzyme K, CD20 and CD69 and selectively dominated the MS CSF. In MS brain tissues, T-bet coexpression was recovered in CD20^dim and CD69⁺ CD8⁺ T cells, and was accompanied by increased coproduction of granzyme K and B. These results indicate that coexpression of RUNX3 and EOMES, but not T-bet, defines CD8⁺ memory T cells with a pre-existing brain residency-associated phenotype such that they are prone to enter the CNS in MS. Full article

(This article belongs to the Special Issue Immunology of Multiple Sclerosis)

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15 pages, 1833 KB

Open AccessReview

Regulation of Adult Mammalian Neural Stem Cells and Neurogenesis by Cell Extrinsic and Intrinsic Factors

by Shuzo Matsubara, Taito Matsuda and Kinichi Nakashima

Cells 2021, 10(5), 1145; https://doi.org/10.3390/cells10051145 - 10 May 2021

Cited by 51 | Viewed by 7876

Abstract

Tissue-specific stem cells give rise to new functional cells to maintain tissue homeostasis and restore damaged tissue after injury. To ensure proper brain functions in the adult brain, neural stem cells (NSCs) continuously generate newborn neurons that integrate into pre-existing neuronal networks. Proliferation, as well as neurogenesis of NSCs, are exquisitely controlled by extrinsic and intrinsic factors, and their underlying mechanisms have been extensively studied with the goal of enhancing the neurogenic capacity of NSCs for regenerative medicine. However, neurogenesis of endogenous NSCs alone is insufficient to completely repair brains damaged by neurodegenerative diseases and/or injury because neurogenic areas are limited and few neurons are produced in the adult brain. An innovative approach towards replacing damaged neurons is to induce conversion of non-neuronal cells residing in injured sites into neurons by a process referred to as direct reprogramming. This review describes extrinsic and intrinsic factors controlling NSCs and neurogenesis in the adult brain and discusses prospects for their applications. It also describes direct neuronal reprogramming technology holding promise for future clinical applications. Full article

(This article belongs to the Collection Signaling Pathways in Cell Generation and Reprogramming)

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