Stimulus-responsive liposomes as smart nanoplatforms for drug delivery applications

284

102

AbstractAs an emerging material, nanomaterials have attracted extensive attention due to their small size, surface effect and quantum tunneling effect, as well as potential applications in traditional materials, medical devices, electronic devices, coatings and other industries. Herein, the influence of nanoparticle selection, production process, grain size, and grain boundary structures on the mechanical properties of nanomaterials is introduced. The current research progress and application range of nano-materials are presented. The unique properties of nano-materials make them superior over traditional materials. Therefore, nanomaterials will have a broader application prospect in the future. Research on nanomaterials is significant for the development and application of materials science.

Section: Applicationmentioning

confidence: 99%

Mechanical properties of nanomaterials: A review

Miao

Zhang

et al. 2020

284

102

“…If capsules are composed of a diameter in the range 0 to 1,000 nm (e.g. in the colloidal range), they are classified as nanoparticles, better known as nanocapsules, nanoparticles or nanospheres [44][45][46]. If capsule contains a diameter less than 1 mm or 1 cm, they are called microcapsules, where capsules of diameters greater than 1 mm or 1 cm are classified as a macrocapsules [28].…”

Section: Encapsulation Technologiesmentioning

confidence: 99%

Phase change materials for building construction: An overview of nano-/micro-encapsulation

Sivanathan

Dou

Wang

et al. 2020

Buildings contribute to 40% of total global energy consumption, which is responsible to 38% of greenhouse gas emissions. It is critical to enhance the energy efficiency of buildings to mitigate global warming. In the last decade, advances in thermal energy storage (TES) techniques using phase change material (PCM) have gained much attention among researchers, mainly to reduce energy consumption and to promote the use of renewable energy sources such as solar energy. PCM technology is one of the most promising technologies available for the development of high performance and energy-efficient buildings and, therefore, considered as one of the most effective and on-going fields of research. The main limitation of PCM is its leakage problem which limits its potential use in building construction and other applications such as TES and textiles, which can be overcome by employing nano-/micro-encapsulation technologies. This paper comprehensively overviews the nano-/micro-encapsulation technologies, which are mainly classified into three categories including physical, physiochemical and chemical methods, and the properties of microcapsules prepared. Among all encapsulation technologies available, the chemical method is commonly used since it offers the best technological approach in terms of encapsulation efficiency and better structural integrity of core material. There is a need to develop a method for the synthesis of nano-encapsulated PCMs to achieve enhanced structural stability and better fracture resistance and, thus, longer service life. The accumulated database of properties/performance of PCMs and synthesised nano-/micro-capsules from various techniques presented in the paper should serve as the most useful information for the production of nano-/micro-capsules with desirable characteristics for building construction application and further innovation of PCM technology.

“…Unlike physical property design and chemical microenvironment response design, this is more based on the laws derived from a long life. In the methods including materials inspired by biology, such as liposome simulation [53] derived from the composition of the cellular membrane, DNA base complementary pairing detection derived from gene replication and antigen-antibody targeted binding derived from biorecognition, most of the raw materials are not obtained by chemical synthesis but through biochemical extraction and collection, which are then re-assembled and re-processed into new materials. The advantage of this category is that despite the mechanisms being not clear, the functions could still be obtained through biological extraction treatment.…”

Section: Bio-inspired Incorporationmentioning

confidence: 99%

A new classification method of nanotechnology for design integration in biomaterials

Zhang¹,

Liu

Xie

et al. 2020

Currently, advanced biomaterial design solutions often have more than two kinds of nanotechnology design strategies, but there is no suitable classification to describe these designs systematically. Based on the material design ideas and the modes of implementing functions, this article exemplifies and proposes a new nanotechnology classification that includes physical properties, the chemical reactions that respond to the microenvironment and bio-inspired incorporation. If two or more nanotechnology designs in the same classification are to be integrated into the same biological material, it is necessary to analyze the integration conflict between the designs. With the development of big data, this classification method may help researchers and artificial intelligence to realize automated integration of multiple designs and provide new material nanotechnology design integration solutions.