Showing papers in "Materials Science & Engineering R-reports in 2007"

Bone structure and formation: A new perspective

Abstract: Bone is a hierarchically structured composite material which, in addition to its obvious biological value, has been well studied by the materials engineering community because of its unique structure and mechanical properties. This article will review the existing bone literature, with emphasis on the prevailing theories regarding bone formation and structure, which lay the groundwork for proposing a new model to explain how intrafibrillar mineralization of collagen can be achieved during bone formation. Intrafibrillar refers to the fact that growth of the mineral phase is somehow directed by the collagen matrix, which leads to a nanostructured architecture consisting of uniaxially oriented nanocrystals of hydroxyapatite embedded within and roughly [0 0 1] aligned parallel to the long collagen fibril axes. Secondary (osteonal) bone, the focus of this review, is a laminated organic–inorganic composite composed primarily of collagen, hydroxyapatite, and water; but minor constituents, such as non-collagenous proteins (NCPs), are also present and are thought to play an important role in bone formation. To date, there has been no clear understanding of the role of these NCPs, although it has been generally assumed that the NCPs regulate solution crystal growth via some type of ‘epitaxial’ relationship between specific crystallographic faces and specific protein conformers. Indeed, ‘epitaxial’ relationships have been calculated; but in practice, it has not been demonstrated that intrafibrillar mineralization can be accomplished via this route. Because of the difficulty in examining biomineralization processes in vivo , the authors of this article have turned to using in vitro model systems to investigate the possible physicochemical mechanisms that may be involved in biomineralization. In the case of bone biomineral, we have now been able to duplicate the most fundamental level of bone structure, the interpenetrating nanostructured architecture, using relatively simple anionic polypeptides that mimic the polyanionic character of the NCPs. We propose that the charged polymer acts as a process-directing agent, by which the conventional solution crystallization is converted into a precursor process. This polymer-induced liquid-precursor (PILP) process generates an amorphous liquid-phase mineral precursor to hydroxyapatite which facilitates intrafibrillar mineralization of type-I collagen because the fluidic character of the amorphous precursor phase enables it to be drawn into the nanoscopic gaps and grooves of collagen fibrils by capillary action. The precursor then solidifies and crystallizes upon loss of hydration waters into the more thermodynamically stable phase, leaving the collagen fibrils embedded with nanoscopic hydroxyapatite (HA) crystals. Electron diffraction patterns of the highly mineralized collagen fibrils are nearly identical to those of natural bone, indicating that the HA crystallites are preferentially aligned with [0 0 1] orientation along the collagen fibril axes. In addition, studies of etched samples of natural bone and our mineralized collagen suggest that the long accepted “deck of cards” model of bone's nanostructured architecture is not entirely accurate. Most importantly, this in vitro model demonstrates that a highly specific, epitaxial-type interaction with NCPs is not needed to stimulate crystal nucleation and regulate crystal orientation, as has long been assumed. Instead, we propose that collagen is the primary template for crystal organization, but with the important caveat that this templating occurs only for crystals formed from an infiltrated amorphous precursor. These results suggest that the 25-year-old debate regarding bone formation via an amorphous precursor phase needs to be revisited. From a biomedical perspective, in addition to providing possible insight into the role of NCPs in bone formation, this in vitro system may pave the way toward the ultimate goal of fabricating a synthetic bone substitute that not only has a composition similar to bone, but has comparable mechanical properties and bioresorptive potential as natural bone. From a materials chemistry perspective, the non-specificity of the PILP process and capillary infiltration mechanism suggests that non-biological materials could also be fabricated into nanostructured composites using this “biomimetic” strategy.

New materials for micro-scale sensors and actuators An engineering review

Abstract: This paper provides a detailed overview of developments in transducer materials technology relating to their current and future applications in micro-scale devices. Recent advances in piezoelectric, magnetostrictive and shape-memory alloy systems are discussed and emerging transducer materials such as magnetic nanoparticles, expandable micro-spheres and conductive polymers are introduced. Materials properties, transducer mechanisms and end applications are described and the potential for integration of the materials with ancillary systems components is viewed as an essential consideration. The review concludes with a short discussion of structural polymers that are extending the range of micro-fabrication techniques available to designers and production engineers beyond the limitations of silicon fabrication technology.

Self-assembly of mineralized collagen composites

Abstract: This paper presents a review of the current understanding of the structure, self-assembly mechanisms, and properties of mineralized collagen fibril composites in connective tissues, such as in lamellar bones, woven bones, zebrafish skeletal bone, and ivory. Recent work involving biomimetic synthesis of new materials with the structure of mineralized collagen is described. The focus in the paper is mainly on materials containing type I collagen, with mineralization by Ca–P crystals although some other systems are also described. Investigation and simulation of naturally occurring fibril structures can offer some new ideas in the design and fabrication of new functional materials, for applications such as bone grafts or for use as scaffolds in tissue engineering and biomimetic engineering materials. The development of bone grafts based on the mineralization of self-assembled collagen fibrils in vivo and in vitro is an active area of research. This kind of bone graft composite has already shown great promise and success in clinical applications, on account of its compositional and structural similarity to autologous bone. It is suggested that future work in this should focus on both basic theoretical aspects as well as the development of applications. In particular issues including control of morphology, incorporation of foreign ions, interaction with biomolecules, and the assembly of organic and inorganic phases are all still not well understood. In the area of applications, the design of composite materials with a hierarchical structure closer to that of natural hard tissues, and the synthesis of bone grafts and tooth regenerative materials, as well as biomimetic functional materials, are areas currently being examined by many research groups.

Infectious disease: Connecting innate immunity to biocidal polymers

Abstract: Infectious disease is a critically important global healthcare issue. In the U.S. alone there are 2 million new cases of hospital-acquired infections annually leading to 90,000 deaths and 5 billion dollars of added healthcare costs. Couple these numbers with the appearance of new antibiotic resistant bacterial strains and the increasing occurrences of community-type outbreaks, and clearly this is an important problem. Our review attempts to bridge the research areas of natural host defense peptides (HDPs), a component of the innate immune system, and biocidal cationic polymers. Recently discovered peptidomimetics and other synthetic mimics of HDPs, that can be short oligomers as well as polymeric macromolecules, provide a unique link between these two areas. An emerging class of these mimics are the facially amphiphilic polymers that aim to emulate the physicochemical properties of HDPs but take advantage of the synthetic ease of polymers. These mimics have been designed with antimicrobial activity and, importantly, selectivity that rivals natural HDPs. In addition to providing some perspective on HDPs, selective mimics, and biocidal polymers, focus is given to the arsenal of biophysical techniques available to study their mode of action and interactions with phospholipid membranes. The issue of lipid type is highlighted and the important role of negative curvature lipids is illustrated. Finally, materials applications (for instance, in the development of permanently antibacterial surfaces) are discussed as this is an important part of controlling the spread of infectious disease.

Multiscale friction mechanisms and hierarchical surfaces in nano- and bio-tribology

Abstract: Various mechanisms of solid–solid and solid–liquid friction are studied in this review, and their relation to the surface roughness hierarchy is discussed. For ideal solid bodies with conservative forces acting between them, there would be no friction. Different deviations from the ideal state, such as the surface roughness, contamination and chemical heterogeneity, bulk material deformation and non-conservative adhesive bonds, lead to energy dissipation. Most heterogeneities involved into various dry friction mechanisms are associated with small ratios of magnitudes and of characteristic lengths of the forces at the interface and in the bulk. This small ratio leads to an almost linear dependence of the friction force upon load (the Coulomb law). However, the heterogeneities lead also to non-linear and multiscale effects. Mapping of dry friction mechanisms is proposed based upon the characteristic length parameters. It is discussed also how hierarchical friction mechanisms lead to biological hierarchical surfaces with reduced or increased adhesion and friction. Current advances in nano- and bio-tribology reveal a growing number of hierarchical (multiscale) surfaces. From the lotus leaf and gecko foot to self-affine and textured engineering surfaces, the hierarchy plays a fundamental role in frictional energy dissipation.

Nucleic acid delivery: Where material sciences and bio-sciences meet

Abstract: Advances in biotechnology have led to an accelerated discovery of macromolecular therapeutics such as peptides, proteins and polynucleotides. These macromolecules can be targeted against a variety of diseases, each requiring delivery to a well-defined compartment of the body. As such therapeutics are often prone to degradation before reaching their target site, or do not reach their target site at all, they often require a special formulation. This review focuses on several types of materials that are currently under investigation for the delivery of nucleic acid therapeutics and aims to pinpoint the limitations of these materials with the ultimate goal to identify the material challenges which, in our opinion, will constitute a new generation of ‘intelligent’ materials for nucleic acid delivery. Such ‘intelligent’ materials should be able to sense and respond to environmental changes. The generated response to these environmental changes should give the material new properties that favor the intracellular delivery of their payload. Besides dealing with material properties, we especially aim to focus on the biological barriers such intelligent materials will have to deal with when used for the delivery of nucleic acids. Furthermore, we briefly discuss the advanced light microscopy techniques that are often used to visualize and quantify the steps of the delivery process of nucleic acids.