One step at a time, stem cell therapy for traumatic brain injury needs two more breakthroughs

G. Shyam
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引用次数: 1

Abstract

Firearm injury is a serious public health problem in the United States (US) costing more than $70-75 billion annually [1,2]. Nonfatal gunshot injuries in the US have increased from 20.5 per 100,000 Americans in 2002 to 23.7 per 100,000 by 2011, mainly due to increased assaults [3]. Despite increasing incidence, timely neurosurgical intervention aided with improved neuro imaging and advances in acute trauma management have lowered the firearm fatality rate [4-6]. Thus, among the estimated 5.3 million people living in the US with traumatic brain injury (TBI)-related disability, the proportion of gun-shot wound survivors has been rising steadily [3,7-11]. Among head injuries, penetrating injuries (PTBI) are associated with the worst outcomes [12,13], and no effective restorative treatment beyond physical therapy is currently available to mitigate post-TBI disability [12-14]. Therefore, there is an urgent need to explore additional treatment options to address long term TBI related disabilities. Studies with preclinical models have demonstrated that failure of injuryinduced regenerative neurogenesis; chronic inflammation and atrophy underlie poor outcomes [15-17]. Loss of neurons and consequent brain atrophy is a consistent neuro pathological finding in TBI survivors and may underlie long-term functional deficits, resulting in reduced executive and integrative capability [18-20]. Human PTBI neuro pathological findings support neuronal and axonal loss with significant brain atrophy [21]. The milestones in neural stem cell (NSC) research were outlined in a review by Gage and Temple, pioneers of the field [22]. NSCs afford the plasticity to generate, repair, and change nervous system function thus are of great interest to basic scientists as well as clinicians. NSCs have not blossomed into a therapeutic as yet and in this article some the issues that underlies the dormancy are discussed. The cell therapy field needed to address four main issues before clinical trials can be started. Firstly, production of the cell therapy candidate under good manufacturing conditions (GMP), second discovery of efficient immunosuppression, third demonstration of therapeutic benefit under controlled conditions. Three decades of basic science has managed to address first two issues.
治疗创伤性脑损伤的干细胞疗法还需要两个突破,一步一个脚印
在美国,火器伤害是一个严重的公共卫生问题,每年造成的损失超过700 - 750亿美元[1,2]。美国的非致命枪伤从2002年的20.5 / 10万增加到2011年的23.7 / 10万,主要原因是袭击事件的增加[3]。尽管发病率增加,但及时的神经外科干预以及神经影像学的改善和急性创伤管理的进步降低了火器死亡率[4-6]。因此,在美国估计有530万的创伤性脑损伤(TBI)相关残疾患者中,枪伤幸存者的比例一直在稳步上升[3,7-11]。在头部损伤中,穿透性损伤(PTBI)的预后最差[12,13],目前除了物理治疗外,还没有有效的恢复性治疗来减轻tbi后的残疾[12-14]。因此,迫切需要探索额外的治疗方案来解决长期创伤性脑损伤相关的残疾。临床前模型研究表明,损伤诱导的再生神经发生失败;慢性炎症和萎缩是不良预后的基础[15-17]。神经元丧失和随之而来的脑萎缩是创伤性脑损伤幸存者的一致神经病理学发现,可能是长期功能缺陷的基础,导致执行能力和综合能力下降[18-20]。人类PTBI神经病理结果支持神经元和轴突丧失伴显著脑萎缩[21]。神经干细胞(NSC)研究的里程碑由该领域的先驱Gage和Temple在一篇综述中概述[22]。神经干细胞具有产生、修复和改变神经系统功能的可塑性,是基础科学家和临床医生非常感兴趣的研究对象。到目前为止,NSCs还没有发展成为一种治疗药物,在这篇文章中,我们讨论了一些潜伏在休眠状态下的问题。在开始临床试验之前,细胞治疗领域需要解决四个主要问题。首先,在良好的生产条件(GMP)下生产细胞治疗候选药物,其次发现有效的免疫抑制,第三在受控条件下证明治疗效果。三十年的基础科学已经成功地解决了前两个问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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