Combining stem cell science and Tissue engineering to study the development and repair of Human skeletal tissues

结合干细胞科学与组织工程学研究人体骨骼组织的发育与修复

• 批准号: BB/G010560/1
• 负责人: Alicia El Haj
• 金额: $ 79.68万
• 依托单位: Keele University
• 依托单位国家: 英国
• 项目类别: Research Grant
• 财政年份: 2010
• 资助国家: 英国
• 起止时间: 2010 至 无数据
• 项目状态: 已结题
• 来源: https://gtr.ukri.org/projects?ref=BB%2FG010560%2F1
• 关键词: Combining; stem; cell; science; Tissue

With an ever increasing ageing population, strategies that allow the simple repair and enhancement of bone tissue, lost due to diseases such as osteoporosis and osteoarthritis or with ageing or after an accident, are urgently needed. Whilst there are a number of surgical techniques that can be used to repair bone and to aid fracture healing, there is a great need for the development of alternative bone and cartilage repair and regeneration strategies. To try and solve the lack of bone a patient may have at one site, the surgeon can try and harvest and use existing bone from another site (known as autogenous bone) in the patient although, naturally, the amounts available to use are limited. Other options include the use of donor bone from a different individual (known as allogeneic bone). However donor bone carries risks of rejection and infection. Tissue engineering aims to make tissues and organs - including bone tissue - using stem and precursor cells, scaffolds upon which the cells can grow and be guided, and necessary mechanical cues to create bone tissue in the laboratory for transplantation to replace damaged or diseased tissues. Within all our bone marrow are stem cells (called skeletal or mesenchymal stem cells), which can be isolated using selective markers and which can be grown up to give lots of cells, while retaining their ability to form a variety of tissues like bone and fat. Similarly we have expertise in the ability to create structures (scaffolds) for the cells to grow on and these scaffolds can be tailored to release select growth factors and proteins needed to guide and tell the stem cells to make bone and cartilage. In addition, we know that mechanical cues are very important in stimulating new bone growth (for example we know excessive bed rest or weightlessness leads to loss of bone). Thus the application of stem cells, select scaffolds and the use of signalling cues to generate new bone tissue is currently one of the most exciting and promising areas for disease treatment and bone repair. We propose as well as combining these key ingredients, that, critically, a new way of thinking as to how scientists currently try to create skeletal tissue is urgently needed if we are to meet the challenges of new skeletal formation for an increasing ageing population. We propose that it is vital to understand bone development and formation and that if we can harness the information of how bone develops and if we can understand bone biology, this will set the foundation and inform us how to repair and make new skeletal tissue. Thus, we propose an ambitious programme of research to significantly advance the state-of-the-art in developmental biology, stem cells, materials chemistry, mechanical signalling and loading and translational medicine to generate new models of skeletal development that can be used to inform skeletal repair strategies for clinical use in bone repair and regeneration. To achieve our goal we will use a multidisciplinary strategy that brings together stem cell biologists, developmental biologists, materials scientists, mechanobiologists and clinicians with an ability to draw lessons from skeletal developmental biology to inform our tissue engineering strategy for skeletal formation and repair.

随着人口日益老龄化，迫切需要能够简单修复和增强因骨质疏松症和骨关节炎等疾病或因衰老或事故而丢失的骨组织的策略。虽然有许多外科技术可用于修复骨骼和帮助骨折愈合，但仍非常需要开发替代骨和软骨修复和再生策略。为了解决患者某一部位缺骨的问题，外科医生可以尝试从患者的另一部位（称为自体骨）获取并使用现有的骨，当然，可用的骨量是有限的。其他选择包括使用来自不同个体的供体骨（称为异体骨）。然而，供体骨有排斥和感染的风险。组织工程的目标是利用干细胞和前体细胞制造组织和器官（包括骨组织）、细胞生长和引导的支架，以及必要的机械线索，在实验室中制造骨组织，用于移植以取代受损或患病的组织。在我们所有的骨髓中都有干细胞（称为骨骼或间充质干细胞），它们可以用选择性标记分离出来，长大后可以产生许多细胞，同时保持它们形成各种组织（如骨和脂肪）的能力。同样，我们在制造细胞生长的结构（支架）方面也有专业知识，这些支架可以被定制，以释放特定的生长因子和蛋白质，这些生长因子和蛋白质是引导和告诉干细胞制造骨骼和软骨所需要的。此外，我们知道机械提示在刺激新骨生长方面非常重要（例如，我们知道过度卧床休息或失重会导致骨质流失）。因此，应用干细胞、选择支架和使用信号信号来产生新的骨组织是目前最令人兴奋和最有希望的疾病治疗和骨修复领域之一。我们提出并结合这些关键成分，关键的是，如果我们要应对日益老龄化的人口新骨骼形成的挑战，迫切需要一种新的思维方式，即科学家目前如何尝试创造骨骼组织。我们认为，了解骨骼的发育和形成是至关重要的，如果我们能利用骨骼如何发育的信息，如果我们能理解骨骼生物学，这将奠定基础，并告诉我们如何修复和制造新的骨骼组织。因此，我们提出了一个雄心勃勃的研究计划，以显著推进发育生物学、干细胞、材料化学、机械信号和负荷以及转化医学方面的最新技术，以产生新的骨骼发育模型，这些模型可用于骨修复和再生的临床应用。为了实现我们的目标，我们将采用多学科策略，将干细胞生物学家、发育生物学家、材料科学家、机械生物学家和临床医生聚集在一起，从骨骼发育生物学中吸取教训，为骨骼形成和修复的组织工程策略提供信息。

项目成果

Translation of remote control regenerative technologies for bone repair.

• DOI: 10.1038/s41536-018-0048-1
• 发表时间: 2018
• 期刊: NPJ Regenerative medicine
• 影响因子: 7.2
• 作者: Markides H;McLaren JS;Telling ND;Alom N;Al-Mutheffer EA;Oreffo ROC;Zannettino A;Scammell BE;White LJ;El Haj AJ
• 通讯作者: El Haj AJ

Therapeutic Benefit for Late, but Not Early, Passage Mesenchymal Stem Cells on Pain Behaviour in an Animal Model of Osteoarthritis.

• DOI: 10.1155/2017/2905104
• 发表时间: 2017
• 期刊: Stem cells international
• 影响因子: 4.3
• 作者: Chapman V;Markides H;Sagar DR;Xu L;Burston JJ;Mapp P;Kay A;Morris RH;Kehoe O;El Haj AJ
• 通讯作者: El Haj AJ

Online Monitoring Of Mechanical Properties Of 3D Tissue Engineered Constructs For Quality Assessment

在线监测 3D 组织工程结构的机械性能以进行质量评估

• 发表时间: 2016
• 期刊: TISSUE ENGINEERING PART A
• 影响因子: 4.1
• 作者: El Haj A. J.

Magnetic ion channel activation of TREK1 in human mesenchymal stem cells using nanoparticles promotes osteogenesis in surrounding cells.

• DOI: 10.1177/2041731418808695
• 发表时间: 2018-01
• 期刊: Journal of tissue engineering
• 影响因子: 8.2
• 作者: Henstock JR;Rotherham M;El Haj AJ
• 通讯作者: El Haj AJ