¶ 肺打印相关文献
这张图展示了从气管到肺泡的完整气道结构,并且详细列出了不同气道区域内的上皮细胞类型及其功能。图片清晰描述了各类细胞在肺部气道中的分布和作用,帮助我们更好地理解肺部气道的解剖结构以及各类细胞在呼吸过程中所起的关键作用。这对于研究呼吸系统疾病、肺组织修复以及再生医学具有重要意义。
基底细胞(Basal cell):修复和再生。
气管和大气道(Trachea and large airways):气管和大气道由多种上皮细胞组成,外围有软骨和支气管平滑肌(SMC)提供支撑,负责导引空气进入肺部。 中小气道(Medium and small airways):气道结构相对简单,包含多种上皮细胞,外围有平滑肌(SMC)控制气道通畅性。 肺泡(Alveolus):肺泡是气体交换的主要部位,由扁平的AT1细胞和立方的AT2细胞构成。 |
| 序号 | 中文题目 | 英文题目 | 发表年限 |
|---|---|---|---|
| 1 | 用于放射治疗研究的三维生物打印非小细胞肺癌模型 | Three-Dimensional-Bioprinted Non-Small Cell Lung Cancer Models in a Mouse Phantom for Radiotherapy Research | 2024 |
| 2 | 采用可见光交联的粘蛋白-透明质酸复合生物墨水进行3D生物打印用于肺组织工程 | 3D Bioprinting with Visible Light Cross-Linkable Mucin-Hyaluronic Acid Composite Bioink for Lung Tissue Engineering | 2024 |
| 3 | 即时粘合和超弹性贴片用于动态器官和伤口修复 | Instantly adhesive and ultra-elastic patches for dynamic organ and wound repair | 2024 |
| 4 | 共组装的活体材料作为体外肺上皮感染模型 | Co-assembling living material as an in vitro lung epithelial infection model | 2023 |
| 5 | 细胞衰老程序对聚合物组织支架的物理差异敏感 | Cellular Senescence Program is Sensitive to Physical Differences in Polymeric Tissue Scaffolds | 2023 |
| 6 | 3D打印通气灌注肺模型平台用于研究呼吸状态下的病毒感染反应 | A 3D Printed Ventilated Perfused Lung Model Platform to Dissect the Lung’s Response to Viral Infection in the Presence of Respiration | 2023 |
| 7 | 在芯片培养平台中促进肺癌细胞生长的3D生物打印水凝胶墨水 | 3D bio-printed hydrogel inks promoting lung cancer cell growth in a lab-on-chip culturing platform | 2023 |
| 8 | 通过模块化de novo支架设计的特异性细胞超稳定IL-4模拟物 | Design of cell-type-specific hyperstable IL-4 mimetics via modular de novo scaffolds | 2023 |
| 9 | 微流控液滴辅助制备用于药物发现的血管支持肿瘤 | Microfluidic Droplet-Assisted Fabrication of Vessel-Supported Tumors for Preclinical Drug Discovery | 2023 |
| 10 | 通过数字光处理生成的可灌注3D肺癌模型 | Generation of a Perfusable 3D Lung Cancer Model by Digital Light Processing | 2023 |
| 11 | CAR-T细胞对修饰的实体瘤细胞系的细胞毒性评估 | Evaluation of CAR-T Cells' Cytotoxicity against Modified Solid Tumor Cell Lines | 2023 |
| 12 | 3D生物打印弹性蛋白-透明质酸水凝胶的点击化学协议 | Click Chemistry Protocol for 3D Bioprintable Elastin−Hyaluronic Acid Hydrogels | 2022 |
| 13 | 基于透明质酸和胶原生物墨水支持的3D病人来源脑肿瘤类器官的沉浸式生物打印 | Immersion bioprinting of hyaluronan and collagen bioink-supported 3D patient-derived brain tumor organoids | 2022 |
| 14 | 高分辨率光刻3D生物打印 | High resolution lithography 3D bioprinting | 2022 |
| 15 | 合理设计的各向异性和呈向性水凝胶贴片用于动态器官的适应 | Rationally Designed Anisotropic and Auxetic Hydrogel Patches for Adaptation to Dynamic Organs | 2022 |
| 16 | I-DOT 2.0作为开发新型床旁检测(POCT)用于脓胸的工具 | I-DOT 2.0 as a Tool to Accelerate Developing Novel Point of Care Test (POCT) for Empyema | 2022 |
| 17 | 压力球形态发生:蜥蜴如何构建其肺脏 | Stress ball morphogenesis: How the lizard builds its lung | 2021 |
| 18 | 铜绿假单胞菌全基因组序列:20周年庆典 | The Pseudomonas aeruginosa whole genome sequence: A 20th anniversary celebration | 2021 |
| 19 | 用于病毒抑制剂研究的多细胞类型肺模型的生物打印 | Bioprinted Multi-Cell Type Lung Model for the Study of Viral Inhibitors | 2021 |
| 20 | 细胞负载Carbopol生物墨水的3D生物打印 | 3D bioprinting of cell-laden carbopol bioinks | 2021 |
| 21 | 肿瘤模型生物制造的3D生物打印进展 | Advances in 3D bioprinting for the biofabrication of tumor models | 2021 |
| 22 | 基于多糖水凝胶的3D打印肿瘤模型用于化疗药物筛选 | Polysaccharide hydrogel based 3D printed tumor models for chemotherapeutic drug screening | 2021 |
| 23 | 组织工程中的生物打印技术 | Bioprinting Technologies in Tissue Engineering | 2020 |
| 24 | 使用低温减少3D打印水凝胶晶格变形 | Utilizing Low Temperatures to Reduce Deformation in 3D Printed Hydrogel Lattices | 2020 |
| 25 | 碳酸钠明胶水凝胶的细胞负载生物墨水的特征化及可打印性用于非小细胞肺癌的共培养 | Characterization and printability of Sodium alginate -Gelatin hydrogel for bioprinting NSCLC co-culture | 2019 |
| 26 | 3D生物打印的细胞负载生物墨水的优化及其对甲型流感病毒的高效感染 | Optimization of cell-laden bioinks for 3D bioprinting and efficient infection with influenza A virus | 2018 |
| 27 | 通过孟德尔随机化证明胰岛素前体不太可能是亚临床血管重构的致病因素,并鉴定了新的胰岛素前体相关SNP | Identification of a novel proinsulin-associated SNP and demonstration that proinsulin is unlikely to be a causal factor in subclinical vascular remodelling using Mendelian randomisation | 2017 |
| 28 | CDODA-Me(一种甘草酸衍生物)和厄洛替尼联合克服NSCLC PDX球状体和3D生物打印细胞中的化疗耐药性 | Combination of CDODA-Me, a glycyrrhetinic acid derivative, and Erlotinib overcomes chemo-resistance in NSCLC PDX spheroids and 3D bio-printed cells | 2017 |
| 29 | 使用Advanced BioMatrix胶原的自动化球体侵袭测定 | Automated Spheroid Invasion Assay Using Collagen from Advanced BioMatrix | 2023 |
| 30 | 用于免疫肿瘤学应用的3D生物打印肿瘤模型 | A 3D Bioprinted Tumor Model for Immuno-oncology Applications | 2020 |