Recycled fish bones offer five star sun protection

Written by Cally Haynes for Chemistry World

An effective new sunscreen based on iron-doped hydroxyapatite (HAp)-based materials derived from cod fish bones, a by-product of the food industry, has been developed by scientists in Portugal.

Fish bones could be converted into a valuable product © iStock

Fish bones could be converted into a valuable product © iStock

Commercial sunscreens are usually based on materials like TiO2 and ZnO, which absorb UV to reduce its harmful effects on the skin. However, there are concerns regarding the potential toxicity of these materials and their adverse environmental effects when they accumulate in water supplies.

Interested? Read the full article at Chemistry World.

The original article can be read below:

Hydroxyapatite-Fe2O3 based material of natural origin as an active sunscreen filter
Clara Piccirillo, Catarina Rocha, David M Tobaldi, Robert Carlyle Pullar, Joao Antonio Labrincha, Marta Ferreira, Paula Castro and Manuela Pintado  
J. Mater. Chem. B, 2014, Accepted Manuscript
DOI: 10.1039/C4TB00984C

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An Interview with Professor Makoto Nakamura

International BIOPRINTING Congress

An Interview with Professor Makoto Nakamura

If you’re interested in the fascinating new field of bioprinting and biofabrication, you won’t want to miss the keynote presentation by University of Toyama’s Professor Makoto Nakamura. His presentation, The Concepts of the Challenges for the Developments of Bioprinting and Biofabrication, will examine the innovative printing techniques that are now being used in tissue engineering. In today’s blog, he shares some of the points he will cover in his keynote speech.

The inaugural International Bioprinting Congress will take place at the Biopolis, Singapore on 24-25 July 2014. The event will present the leading international scientists and thought leaders within the rapidly developing field of 3D bioprinting.

SELECTBIO: What are some of the challenges you’re finding in your research on bioprinting and biofabrication?

Nakamura: Our team has ever pursued several challenges on tissue engineering, towards the final goal of engineering biological artificial organs which can be used for clinical therapy for disease patients. Our challenges concerning to bioprinting and biofabrication are as follows.

First, we ask how can we position or assemble living cells directly onto arbitrary positions. Specifically, we’re examining high resolution as biological histology; respect cell-type onto respect cell positions; both 2D and 3D space, especially together with inner compositions; and, high speed positioning or fabrication.

Second, we ask what kind of machines or technologies are feasible to produce biological tissues and organs. Within this area, we find many advantages in printing technology, which forms the beginning of our research on bioprinting. Third, we ask how we can make effective perfusion systems such as capillary vessels in the fabricated large 3D tissues.

And, finally, we examine recent challenges such as searching suitable biomaterials for biofabrication and version-up of our 3D bioprinter. However, producing biological tissues–especially alternatives for transplantation- is not easy. Therefore many challenges must be addressed until our final goal can be achieved.

SELECTBIO: What are some of the limitations of mechanical artificial organs that biofabricated artificial organs resolve?

Nakamura: Mechanical artificial organs have contributed to saving many patients indeed, so I think they are necessary and they still need further development. I’d like to emphasize that it is important to understand that the research on mechanical artificial organs is very necessary. However, there are still no cues to compensate metabolic functions of biological cells and tissues by mechanical artificial organs, such as energy generation in vivo, hormone generation and detoxification in vivo. Therefore, energy must be transferred almost continuously from outside of the body for an artificial heart, while a dialysis patient must be connected to a machine that dilutes waters in the case of an artificial kidney. In addition, artificial organs never grow up along with children when they grow up. My hope is to develop a pediatric artificial heart to address one of the more serious problems in mechanical arti ficial organs.

SELECTBIO: Your research has involved the heart; is this really an organ that can be biofabricated?

Nakamura: Of course, I think so, but it is in future. Although it is indeed a very difficult theme, I believe it can be achieved through science and technology some day.

SELECTBIO: You have been closely involved with the International Society For Biofabrication (ISBF) as an inaugural board member. What are the goals of the ISBF?

Nakamura: As far as I understand, the goal of ISBF is as follows:

1. The most important purpose of ISBF is to promote the research and development of biofabrication worldwide. However, why is such biofabrication research necessary? The most essential point of fabricating biological products is to fabricate and produce human tissues and organs to contribute to the development of the medicine, not only basic but also clinical medicine. This is essentially the same as tissue engineering. Therefore, ISBF aims at this final goal.

2. To achieve this, interaction or collaboration with different disciplines in other different fields is necessary, because biofabrication is a new approach. Hence, ISBF actively searches for synergies with other fields.

3. In addition, application of biofabricated products to basic and clinical medicine, and all of the life science areas, is important, as well as interaction and collaboration. Moreover, industry is also important, because basic technologies must be connected to industrial applications to produce practical products. While a non-profit organization, ISBF nevertheless promotes interactions for contributing to biofabrication applications.

4. ISBF is an academic society. Therefore, ISBF is active in the education of young scientists and students.

These are not the official position of the ISBF, but my understanding as a member of ISBF.

SELECTBIO: What do you consider your greatest success in this field?

Nakamura: My great success? It is difficult to evaluate my works by myself! I have proposed that printing technologies are a promising avenue to develop 3D tissue engineering by showing 3D bioprinting using an inkjet technique. Although other researchers are also working on bioprinting solutions, our works on bioprinting and biofabrication have influenced many Japanese engineers and researchers to work in the field of printing technologies, MEMS technologies and mechatronics technologies, as well as regenerative medicine.

SELECTBIO: How do you envision bioprinting and biofabrication evolving in the future?

Nakamura: I hope and believe that the time when human tissues and organs can be produced by computer-aided machine technologies and process engineering will come some day.

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International BIOPRINTING Congress

Biopolis, Singapore, 24-25 July 2014

This congress presents the leading international scientists within the rapidly developing field of bioprinting.  The Chair of the School of Mechanical and Aerospace Engineering, Nanyang Technological University, Professor Chua Chee Kai, Director Nanyang Additive Manufacturing Centre, Singapore and Professor Makoto Nakamura, Graduate School of Science and Engineering for Research, University of Toyama, Japan are the conference chairs for this event.

This congree will provide attendees with a detailed insight into the latest developments and techniques in bioprinting covering additive manufacturing of tissues and biofabrication, scaffolds and biomaterials for tissue engineering, biological laser printing, biological inkjet printing, search for the synergy by fusion of bio-additive manufacturing and micro manufacturing, cell and tissue patterning for lab-on-a-chip and tissue models plus additive manufacturing and medical devices from the keynote speakers, Professor Chua Chee Kai, Nanygang Technological University and Professor Makoto Nakamura, The University of Toyama.

Register here  to attend this congress.  Deadline for poster submission is the 3rd of July.

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Superelastic battery

Written by Jennifer Newton for Chemistry World

Lithium ion batteries that can be stretched by 600% have been unveiled by scientists in China. In the future, the fibre shaped batteries could be woven into textiles to satisfy the ever-growing requirement for wearable devices.

Huisheng Peng and colleagues at Fudan University made the superelastic batteries by winding two carbon nanotubes–lithium oxide composites yarns, which served as the positive and negative electrodes, onto an elastomer substrate and covering this with a layer of gel electrolyte. The batteries owe their stable electrochemical performance under stretching to the twisted structure of the fibre electrodes and the stretchability of the substrate and gel electrolyte, with the latter also acting as an anchor. When the batteries were stretched, the spring-like structure of the two electrodes was maintained.

The full article can be read at Chemistry World.

A link to the original article can be found below:

Super-stretchy lithium-ion battery based on carbon nanotube fiber
Ye Zhang, Wenyu Bai, Jing Ren, Wei Weng, Huijuan Lin, Zhitao Zhang and Huisheng Peng
J. Mater. Chem. A, 2014, Advance Article
DOI: 10.1039/C4TA01878H

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MACRO 2015

The International Conference on Polymer Science and Technology

The 2015 International Conference on Polymer Science and Technology is a biannual international symposia held in India under The Society of Polymer Science India  and offers a unique opportunity for the international as well as national researchers working on the diverse areas of polymer science and technology to share and discuss the recent developments in:

  • Polymer synthesis
  • Polymer blends and composites
  • Supramolecular polymers and self assembly
  • Conducting polymers
  • Polymers in energy applications and sensors
  • Sustainable polymers and biological applications
  • Polymeric nanomaterials
  • Elastomers and rubbers

This meeting will comprise of several plenary sessions, key note lectures and talks by leading polymer scientists from around the globe and an opportunity for graduates and post doctoral researchers to participate in an extensive poster presentation session.

The meeting will be running from the 23rd – 26th January 2015 with registration opening in July 2014.

For more information please visit www.macro2015.org or via email.

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ISMC-2014

The 5th Interdisciplinary Symposium on Materials Chemistry

The  5th  Interdisciplinary  Symposium  on  Materials  Chemistry (ISMC–2014), is jointly organised by the  Society  for  Materials  Chemistry  (SMC)  and the Chemistry Division, Bhabha Atomic Research Centre (BARC), Trombay, Mumbai, India, during December 9th-13th, 2014.  The symposium is supported by the Board of Research in Nuclear Sciences (BRNS) and the Department of Atomic Energy (DAE). This Symposium will focus on contemporary  research in the field of  materials  chemistry. 

 The deliberations of the symposium  will  cover the following topics:

•  Nuclear materials
•  High purity materials
•  Nanomaterials and clusters
•  Carbon based materials
•  Fuel cell materials and other electro-ceramics
•  Biomaterials
•  Polymers and soft condensed matter
•  Materials for energy conversion
•  Thin films and surface chemistry
•  Magnetic materials
•  Catalysis
•  Chemical sensors
•  Organic and organometallic compounds
•  Computational material chemistry

Researchers working in the above mentioned areas are encouraged to participate in ISMC-2014.

Important Dates:

Last date for submission of papers     : August 20, 2014
Acceptance of papers                              : September 30, 2014
Payment of registration fees                 : October 20, 2014

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Hot Article: The role of material structure and mechanical properties in cell-matrix interactions

From the Journal of Materials Chemistry B Emerging Investigators Themed Issue

When thinking about movement of the human body it is often thought about it in terms of muscles contracting and relaxing, joints bending and straightening, but I don’t think I have ever thought about movement on a cellular level.

During movement cells in our bodies are subject to mechanical force and as a result they are stretched, sheared and compressed. Many cells passively experience this force and some have even evolved to be particularly sensitive to it and act as sensors – such as the tiny hairs present inside the human ear.

However, some cells are a bit more active and can actually exert their own mechanical force on the environment around them. This interaction is used to achieve various physiological functions like the healing of tissue, fighting infection and growth and differentiation of cells. In order to carry out these functions the cells must be able to sense and understand the mechanical context of the world around them.

This review summarises the evolution of the area of science focused on understanding the mechanobiology of cells and tissues and how different properties of their surrounding environment can be analysed both scientifically and by the cell itself. It also goes further to discuss of different material properties effect the mechanosensing of cells.  Whilst this is still a developing field this review gives a good overview of where our present understanding is at and what limitations there are to overcome in the future.

The role of material structure and mechanical propertie in cell-matrix interactions
Nicholas D. Evans and Eileen Gentleman
J. Mater. Chem. B, 2014, 2, 2345-2356. C3TB21604G

H. L. Parker is a guest web writer for the Journal of Materials Chemistry blog. She currently works at the Green Chemistry Centre of Excellence, the University of York.

To keep up-to-date with all the latest research, sign-up to our RSS feed or Table of contents alert.

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Can you treat cancer this way too?! Really?!!

Writers Choice: Amphiphilic chitosan modified upconversion nanoparticles for in vivo photodynamic therapy induced by near-infrared light

Imagine a scenario where one morning, a close friend of yours calls you and painfully conveys the news of him being diagnosed with cancer and you, instead of sitting horrified and helpless, casually say “Hey don’t worry man, we have PDT!” That sounds fascinating right?! Yes, Photodynamic therapy has shown potential to do that. With the same fascination towards the idea of photodynamic therapy, inventors of PDT pursued research on this therapy and shaped an unconventional out of box method of treating cancer.  The simple mechanism of working of this technique is widely known. Drugs used in this technique are light sensitive. In response to specific light irradiated on the drug molecule, it converts surrounding molecular oxygen into form of oxygen which kills nearby cancer cells. The reasons this therapy called as out of box here are multifold. First, there are many photosensitizers easily available approved by FDA which can easily respond to specific light and produced the effect explained above. Second it makes use of naturally available oxygen molecules surrounding cancer cells. Last and importantly all the conventional drugs/ therapies for the cancer are immunosuppressive meaning they suppress our immune system after treatment unlike PDT, which is immunostimulative which stimulates immune system of the patient after treatment.

Read more »

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NIR Luminescent Nanomaterials for Biomedical Imaging

Commonly in my household the phrase “you make a better door than you do a window” is often fired at whichever thoughtless member is blocking the latest episode of whatever intelligence diluting programme is being watched at the time. However, this same, seemingly mundane problem, of human solidity is also being suffered by scientists developing new techniques for biomedical imaging.

Luminescent labels have been widely used for biological applications, primarily bioimaging and assays. They offer advantages over tomographic imaging techniques (e.g. CT, PET and MRI) including fast feedback and high selectivity and resolution. Unfortunately, adsorption and scattering of the photos emitted by these labels caused by biological tissue and water inside the body create problems such as weak signals and limited depth of detection.

Luckily, there are some wavelengths of light that are not adsorbed by the body and fall into what is known as the “biological transparency window”. There are two ranges: NIR I 650 – 900 nm and NIR II 1000 – 1450 nm. Since the discovery of these NIR regions research has increased with the focus of developing nanomaterials that can be excited or emitted within these wavelengths. The main content of this review written by Wang and Zhang is an overview of these novel nanomaterials, divided into four main species: lanthanide based nanomaterials, carbon based nanomaterials, quantum dots and noble metal nanoparticles. Covering their fabrication and application and also their shortcomings and what challenges and opportunities there are in the future.

NIR Luminescent Nanomaterials for Biomedical Imaging
Rui Wang and Fan Zhang
J. Mater Chem. B, 2014, 2, 2422-2443. C3TB21447H


H. L. Parker is a guest web writer for the Journal of Materials Chemistry blog. She currently works at the Green Chemistry Centre of Excellence, the University of York.

To keep up-to-date with all the latest research, sign-up to our RSS feed or Table of contents alert.

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A good hair day for glowing nanoparticles

Written by Jennifer Newton for Chemistry World.

By raiding their local barber’s shop, scientists in China have found the ideal raw material for an emerging class of fluorescent nanoparticles.

The desirable optical properties, chemical inertness and biocompatibility of carbon dots has led researchers to explore their application in anti-counterfeiting fields and flat panel displays…

Interested? Read the full article at Chemistry World.

Photographs of carbon dot ink patterns under UV light

Photographs of carbon dot ink patterns under UV light

The original article can be read below:

Hair-Derived Carbon Dots toward Versatile Multidimensional Fluorescent Hybrid Materials
Si-Si Liu, Cai-Feng Wang, Chen-Xiong Li, Jing Wang, Li-Hua Mao and Su Chen
J. Mater. Chem. C, 2014, Accepted Manuscript
DOI: 10.1039/C4TC00636D

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