標(biāo)題: Titlebook: Biomaterials for Tissue Engineering Applications; A Review of the Past Jason A. Burdick,Robert L. Mauck Book 2011 Springer-Verlag/Wien 2011 [打印本頁] 作者: Reagan 時(shí)間: 2025-3-21 17:00
書目名稱Biomaterials for Tissue Engineering Applications影響因子(影響力)
書目名稱Biomaterials for Tissue Engineering Applications影響因子(影響力)學(xué)科排名
書目名稱Biomaterials for Tissue Engineering Applications網(wǎng)絡(luò)公開度
書目名稱Biomaterials for Tissue Engineering Applications網(wǎng)絡(luò)公開度學(xué)科排名
書目名稱Biomaterials for Tissue Engineering Applications被引頻次
書目名稱Biomaterials for Tissue Engineering Applications被引頻次學(xué)科排名
書目名稱Biomaterials for Tissue Engineering Applications年度引用
書目名稱Biomaterials for Tissue Engineering Applications年度引用學(xué)科排名
書目名稱Biomaterials for Tissue Engineering Applications讀者反饋
書目名稱Biomaterials for Tissue Engineering Applications讀者反饋學(xué)科排名
作者: Antarctic 時(shí)間: 2025-3-21 21:06 作者: LAVA 時(shí)間: 2025-3-22 02:18
Fibrous Scaffolds for Tissue Engineeringomaterial scaffolds for tissue engineering since fibrous structures can morphologically resemble extracellular matrix components in tissues. In addition, fibers can be collected and processed into complex fibrous networks using conventional textile techniques, such as knitting, weaving, or braiding,作者: kindred 時(shí)間: 2025-3-22 05:22
Bioelastomers in Tissue Engineeringll function and tissue development. Further, many engineered soft-tissue constructs such as vascular grafts, cardiac patches, and cartilage are implanted in a mechanically dynamic environment, thus successful implants must sustain and recover from various deformations without mechanical irritations 作者: Aprope 時(shí)間: 2025-3-22 12:08
Microscale Biomaterials for Tissue Engineeringer, we present an overview of these technologies and their applications in controlling the cellular microenviroment for tissue engineering applications. We focus on concepts and techniques that can be used to create two- and three-dimensional tissue engineering substrates and scaffolds. Common to th作者: Basal-Ganglia 時(shí)間: 2025-3-22 16:00 作者: Malleable 時(shí)間: 2025-3-22 20:57
Bioceramics in Tissue Engineeringinert ceramics are currently used as femoral heads, acetabular cups for hip replacement, and dental implants. Nano-structured bioinert ceramics with significantly improved toughness and stability are desirable for future clinical needs. Bioactive glass and calcium phosphates are being investigated a作者: 梯田 時(shí)間: 2025-3-22 23:15
Natural Materials in Tissue Engineering Applicationsls may be harvested from a wide range of sources and possess an equally wide range of physical and biological properties. This chapter focuses upon seven of these materials, namely collagen, fibrin, elastin, hyaluronic acid, alginate, chitosan, and silk. These materials are first discussed with resp作者: Veneer 時(shí)間: 2025-3-23 01:33 作者: 原告 時(shí)間: 2025-3-23 09:27
Cartilage Engineering: Current Status and Future Trendsmatrix (ECM) is comprised mainly of type II collagen and proteoglycans which are maintained by chondrocytes, the resident cell population. Cartilage is a structurally complex tissue, with zones that exhibit different cell morphologies and extracellular matrix structure depending on distance from the作者: Indebted 時(shí)間: 2025-3-23 10:31
Biomaterials for Regeneration of Tendons and Ligamentso undergo endogenous repair following injury leads to significant joint instability, injury of other tissues, and the development of degenerative joint disease. To restore their normal structure and function and address these clinical challenges, biomaterial scaffolds are being developed that incorp作者: seroma 時(shí)間: 2025-3-23 16:52
Materials for Bone Graft Substitutes and Osseous Tissue Regenerationeneous structure with features that span from the nanoscale to the macroscale and interact to perform the various functions of the tissue. For large defects, traditional therapies for bone repair include tissue grafts, which are limited by supply (autografts) and the potential for disease transmissi作者: 歡呼 時(shí)間: 2025-3-23 19:52
Fibrocartilage Tissue Engineeringjoints throughout the body. Its unique combination of tensile strength, compressive strength, and deformability makes it an ideal material for many structures, however a low intrinsic capacity for repair means that disease or damage can produce chronic debility. The fibrocartilages represent a signi作者: 強(qiáng)有力 時(shí)間: 2025-3-24 00:50
Liver Tissue Engineering for orthotopic liver transplantation. Liver cell transplantation and extracorporeal bioartificial livers (BAL) may bridge patients with end-stage liver diseases to successful orthotopic liver transplantation, support patients with acute liver failure to recover, and provide a curing method to patie作者: 防止 時(shí)間: 2025-3-24 03:37 作者: 失望未來 時(shí)間: 2025-3-24 10:18 作者: 枕墊 時(shí)間: 2025-3-24 11:26 作者: countenance 時(shí)間: 2025-3-24 17:13 作者: Esalate 時(shí)間: 2025-3-24 19:23 作者: handle 時(shí)間: 2025-3-25 01:14
Book 2011e discipline is provided to the reader. The specific area of the biomaterial component used within the paradigm of tissue engineering is examined in detail. This is the first work to specifically covers topics of interest with regards to the biomaterial component. The book is divided into 2 sections作者: 周年紀(jì)念日 時(shí)間: 2025-3-25 07:14
https://doi.org/10.1007/3-540-27547-9–matrix, and cell-soluble factor interactions. We also discuss recent developments in high throughput techniques that are used to explore the vast number of combinations of factors that comprise the cellular microenvironment.作者: Cosmopolitan 時(shí)間: 2025-3-25 07:30 作者: 嫻熟 時(shí)間: 2025-3-25 13:51 作者: 和諧 時(shí)間: 2025-3-25 18:24 作者: Accessible 時(shí)間: 2025-3-25 21:33
https://doi.org/10.1007/978-3-658-04301-8rks. This chapter will discuss the processes involved in vascular network assembly; these processes inspire the design of biomaterials to fit tissue vascularization. Previous work in this field will be described to allow discussion of the current state of the art and to provide insights into its future directions.作者: 玷污 時(shí)間: 2025-3-26 00:36
Microscale Biomaterials for Tissue Engineering–matrix, and cell-soluble factor interactions. We also discuss recent developments in high throughput techniques that are used to explore the vast number of combinations of factors that comprise the cellular microenvironment.作者: CROAK 時(shí)間: 2025-3-26 06:21 作者: 斗爭 時(shí)間: 2025-3-26 11:20
Fibrocartilage Tissue Engineering microarchitecture. In this chapter, we will review the structure and biology of fibrocartilage and take a look at the biomaterial strategies that have been used. At present no material has satisfied all of the requirements for a successful tissue engineered therapy, however many promising developments have occurred.作者: Conflagration 時(shí)間: 2025-3-26 13:35 作者: 華而不實(shí) 時(shí)間: 2025-3-26 18:55 作者: modifier 時(shí)間: 2025-3-26 21:30
https://doi.org/10.1007/978-3-531-90372-9 one of the most striking findings is how similar many of their results have been across types of materials and approaches. Clearly, there is much still to learn. Part of that learning process comes from looking at what has succeeded in the clinic and using that to design the next generation of translatable approaches to treatment.作者: 形上升才刺激 時(shí)間: 2025-3-27 01:26
Konzepte siliziumbasierter MOS-Bauelementems behind cellular interactions with nanomaterials. In addition, an examination of the effects of nanomaterials on biocompatibility and cytotoxicity will be presented. Specific applications of nanomaterials in tissue engineering of connective, neural, muscular and boney tissue will also be examined.作者: Anthrp 時(shí)間: 2025-3-27 06:10
Konzepte der CMOS-Logik und HF-Technologie,tion of regeneration materials. Bioceramics for dental and cancer treatment are also introduced in this chapter. Further challenges in bioceramic scaffold fabrication for tissue engineering are also discussed.作者: Altitude 時(shí)間: 2025-3-27 09:56 作者: dainty 時(shí)間: 2025-3-27 16:17 作者: 間接 時(shí)間: 2025-3-27 19:11
Bioceramics in Tissue Engineeringtion of regeneration materials. Bioceramics for dental and cancer treatment are also introduced in this chapter. Further challenges in bioceramic scaffold fabrication for tissue engineering are also discussed.作者: Magnificent 時(shí)間: 2025-3-27 21:58
Natural Materials in Tissue Engineering Applicationspanied by select examples of how these natural materials have been used in tissue engineering applications. While natural materials possess many characteristics that render them attractive for use in tissue engineering, they are also accompanied by some unique challenges; both of these features are highlighted in this chapter.作者: candle 時(shí)間: 2025-3-28 05:11 作者: helper-T-cells 時(shí)間: 2025-3-28 08:13
Katharina Sirtl,Friederike Heinzelthere was a need for another book in this field. Tissue engineering books abound; however, a review of the existing literature soon made clear that no other work exists that focuses specifically on the material aspects of tissue engineering science and the approach that we and others use within our 作者: 工作 時(shí)間: 2025-3-28 12:13 作者: GREEN 時(shí)間: 2025-3-28 16:00 作者: adjacent 時(shí)間: 2025-3-28 20:42
https://doi.org/10.1007/3-540-27547-9ll function and tissue development. Further, many engineered soft-tissue constructs such as vascular grafts, cardiac patches, and cartilage are implanted in a mechanically dynamic environment, thus successful implants must sustain and recover from various deformations without mechanical irritations 作者: 畢業(yè)典禮 時(shí)間: 2025-3-29 00:14
https://doi.org/10.1007/3-540-27547-9er, we present an overview of these technologies and their applications in controlling the cellular microenviroment for tissue engineering applications. We focus on concepts and techniques that can be used to create two- and three-dimensional tissue engineering substrates and scaffolds. Common to th作者: 襲擊 時(shí)間: 2025-3-29 05:17
Konzepte siliziumbasierter MOS-Bauelementeons impart distinctive properties compared to micron sized materials. In this chapter, we will review techniques for creation of micron and nanometer features on 2D substrates and 3D nanomaterials which have been used in tissue engineering applications. In the first half, we will review the latest a作者: Cardiac 時(shí)間: 2025-3-29 10:08 作者: indices 時(shí)間: 2025-3-29 11:45
https://doi.org/10.1007/3-540-27547-9ls may be harvested from a wide range of sources and possess an equally wide range of physical and biological properties. This chapter focuses upon seven of these materials, namely collagen, fibrin, elastin, hyaluronic acid, alginate, chitosan, and silk. These materials are first discussed with resp作者: Lament 時(shí)間: 2025-3-29 18:54 作者: 甜得發(fā)膩 時(shí)間: 2025-3-29 19:45
https://doi.org/10.1007/978-3-658-04954-6matrix (ECM) is comprised mainly of type II collagen and proteoglycans which are maintained by chondrocytes, the resident cell population. Cartilage is a structurally complex tissue, with zones that exhibit different cell morphologies and extracellular matrix structure depending on distance from the作者: 巧辦法 時(shí)間: 2025-3-30 01:00
Johann Bacher,Marina Hahn-Bleibtreuo undergo endogenous repair following injury leads to significant joint instability, injury of other tissues, and the development of degenerative joint disease. To restore their normal structure and function and address these clinical challenges, biomaterial scaffolds are being developed that incorp作者: Ethics 時(shí)間: 2025-3-30 06:44 作者: 過分 時(shí)間: 2025-3-30 11:57 作者: 他一致 時(shí)間: 2025-3-30 12:38 作者: 墊子 時(shí)間: 2025-3-30 16:47
https://doi.org/10.1007/978-3-658-04301-8f heart disease and presenting the motivation for pursuing tissue engineering for the heart, the chapter outlines some of the current clinical treatments used to correct the loss of function resulting from heart disease. Current collection of studies is then divided broadly into two sections: cell i作者: Mangle 時(shí)間: 2025-3-30 23:05
https://doi.org/10.1007/978-3-658-04301-8an be used in clinical applications. Our current understanding of stem cell biology and vascular morphogenesis has allowed tissue engineers to design biomaterials that mimic the properties of native tissue and promote vascularization. Biomaterials approaches in tissue engineering include differentia作者: canonical 時(shí)間: 2025-3-31 04:08 作者: 獨(dú)輪車 時(shí)間: 2025-3-31 06:37 作者: Constrain 時(shí)間: 2025-3-31 11:27 作者: 聾子 時(shí)間: 2025-3-31 15:51
https://doi.org/10.1007/978-3-7091-0385-2Bioengineering; Tissue Engineering; material engineering; tissue; biochemical engineering作者: staging 時(shí)間: 2025-3-31 21:14 作者: 誤傳 時(shí)間: 2025-3-31 21:55 作者: 原諒 時(shí)間: 2025-4-1 02:49
Hydrogels in Tissue Engineering, and degradation rates have been engineered. Biological motifs or soluble factors have been successfully incorporated in the hydrogel matrices to allow for a higher level of cell-matrix communication. These synthesis methods have resulted in the production of a wide variety of functional hydrogels
