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1. From Arteries to Capillaries: Approaches to Engineering Human Vasculature

   https://doi.org/10.1002/adfm.201910811  

   Fleischer, Sharon; Tavakol, Daniel_Naveed; Vunjak‐Novakovic, Gordana (June 2020, Advanced Functional Materials)

   Abstract From microscaled capillaries to millimeter‐sized vessels, human vasculature spans multiple scales and cell types. The convergence of bioengineering, materials science, and stem cell biology has enabled tissue engineers to recreate the structure and function of different hierarchical levels of the vascular tree. Engineering large‐scale vessels aims to replace damaged arteries, arterioles, and venules and their routine application in the clinic may become a reality in the near future. Strategies to engineer meso‐ and microvasculature are extensively explored to generate models for studying vascular biology, drug transport, and disease progression as well as for vascularizing engineered tissues for regenerative medicine. However, bioengineering tissues for transplantation has failed to result in clinical translation due to the lack of proper integrated vasculature for effective oxygen and nutrient delivery. The development of strategies to generate multiscale vascular networks and their direct anastomosis to host vasculature would greatly benefit this formidable goal. In this review, design considerations and technologies for engineering millimeter‐, meso‐, and microscale vessels are discussed. Examples of recent state‐of‐the‐art strategies to engineer multiscale vasculature are also provided. Finally, key challenges limiting the translation of vascularized tissues are identified and perspectives on future directions for exploration are presented. 

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2. Realizations of vascularized tissues: From in vitro platforms to in vivo grafts

   https://doi.org/10.1063/5.0131972  

   Ren, Bing; Jiang, Zhihua; Murfee, Walter Lee; Katz, Adam J.; Siemann, Dietmar; Huang, Yong (March 2023, Biophysics Reviews)

   Vascularization is essential for realizing thick and functional tissue constructs that can be utilized for in vitro study platforms and in vivo grafts. The vasculature enables the transport of nutrients, oxygen, and wastes and is also indispensable to organ functional units such as the nephron filtration unit, the blood–air barrier, and the blood–brain barrier. This review aims to discuss the latest progress of organ-like vascularized constructs with specific functionalities and realizations even though they are not yet ready to be used as organ substitutes. First, the human vascular system is briefly introduced and related design considerations for engineering vascularized tissues are discussed. Second, up-to-date creation technologies for vascularized tissues are summarized and classified into the engineering and cellular self-assembly approaches. Third, recent applications ranging from in vitro tissue models, including generic vessel models, tumor models, and different human organ models such as heart, kidneys, liver, lungs, and brain, to prevascularized in vivo grafts for implantation and anastomosis are discussed in detail. The specific design considerations for the aforementioned applications are summarized and future perspectives regarding future clinical applications and commercialization are provided. 

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3. Sacrificial strategy towards the formation of vascular‐like networks in volumetric tissue constructs

   https://doi.org/10.1002/bmm2.12118  

   Buckley, Christian; Ibrahim, Rana; Giordano, Felicia; Xu, Nuo; Sems, Brandon; Wang, Hongjun (October 2024, BMEMat)

   Abstract The fields of tissue engineering and regenerative medicine have made astounding progress in recent years, evidenced by cutting‐edge 4D printing technologies, precise gene editing tools, and sustained long‐term functionality of engineered tissue grafts. Despite these fantastic feats, the clinical success of tissue‐engineered constructs so far remains limited to only those relatively simple types of tissues such as thin bilayer skin equivalents or avascular cartilage. On the other hand, volumetric tissues (larger than a few millimeters in all dimensions), which are highly desirable for clinical utility, suffer from poor oxygen supply due to limited dimensional diffusion. Notably, large, complex tissues typically require a vascular network to supply the growing cells with nutrients for metabolic demands to prolong viability and support tissue formation. In recognition, extensive efforts have been made to create vascular‐like networks in order to facilitate mass exchange through volumetric scaffolds. This review underlines the urgent need for continued research to create more complex and functional vascular networks, which is crucial for generating viable volumetric tissues, and highlights the recent advances in sacrificial template‐enabled formation of vascular‐like networks. 

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4. Rapid model-guided design of organ-scale synthetic vasculature for biomanufacturing

   https://doi.org/10.1126/science.adj6152  

   Sexton, Zachary A; Rütsche, Dominic; Herrmann, Jessica E; Hudson, Andrew R; Sinha, Soham; Du, Jianyi; Shiwarski, Daniel J; Masaltseva, Anastasiia; Solberg, Fredrik Samdal; Pham, Jonathan; et al (June 2025, Science)

   Our ability to produce human-scale biomanufactured organs is limited by inadequate vascularization and perfusion. For arbitrarily complex geometries, designing and printing vasculature capable of adequate perfusion poses a major hurdle. We introduce a model-driven design platform that demonstrates rapid synthetic vascular model generation alongside multifidelity computational fluid dynamics simulations and three-dimensional bioprinting. Key algorithmic advances accelerate vascular generation 230-fold and enable application to arbitrarily complex shapes. We demonstrate that organ-scale vascular network models can be generated and used to computationally vascularize >200 engineered and anatomic models. Synthetic vascular perfusion improves cell viability in fabricated living-tissue constructs. This platform enables the rapid, scalable vascular model generation and fluid physics analysis for biomanufactured tissues that are necessary for future scale-up and production. 

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5. Engineering the Lymphatic Network: A Solution to Lymphedema

   https://doi.org/10.1002/adhm.202001537  

   Jia, Wenkai; Hitchcock‐Szilagyi, Hannah; He, Weilue; Goldman, Jeremy; Zhao, Feng (January 2021, Advanced Healthcare Materials)

   Abstract Secondary lymphedema is a life‐long disorder characterized by chronic tissue swelling and inflammation that obstruct interstitial fluid circulation and immune cell trafficking. Regenerating lymphatic vasculatures using various strategies represents a promising treatment for lymphedema. Growth factor injection and gene delivery have been developed to stimulate lymphangiogenesis and augment interstitial fluid resorption. Using bioengineered materials as growth factor delivery vehicles allows for a more precisely targeted lymphangiogenic activation within the injured site. The implantation of prevascularized lymphatic tissue also promotesin situlymphatic capillary network formation. The engineering of larger scale lymphatic tissues, including lymphatic collecting vessels and lymph nodes constructed by bioengineered scaffolds or decellularized animal tissues, offers alternatives to reconnecting damaged lymphatic vessels and restoring lymph circulation. These approaches provide lymphatic vascular grafting materials to reimpose lymphatic continuity across the site of injury, without creating secondary injuries at donor sites. The present work reviews molecular mechanisms mediating lymphatic system development, approaches to promoting lymphatic network regeneration, and strategies for engineering lymphatic tissues, including lymphatic capillaries, collecting vessels, and nodes. Challenges of advanced translational applications are also discussed. 

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