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Subject Area & Keyword selection during your manuscript submission

Our new peer review process for RSC Advances means that you can be sure your work will be in the safe hands of an expert, every step of the way.

To help ensure that your manuscript will be assigned to an appropriate Associate Editor, we’re now asking you, our authors, to select a Subject Area and Keyword during the manuscript submission process online.

During the submission of your manuscript, simply use the drop-down menu, as shown below, to pick the Subject Area and Keyword that best describes your work.

Subject Area and Keyword selection

Submit your manuscript online now!

For pre-submission queries, please feel free to send us an email.

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Stencilling self-propulsion engines

Researchers in the US have designed and made millimetre-sized motors in the shape of fish that could be produced on an enormous scale and used to purify water.

Catalytic fish in action

Nano- and micro-sized machines that convert chemical reactions into motion have been on the drawing board for many years. However, they are complicated and expensive to make. Now, researchers led by Joseph Wang at the University of California San Diego have developed a simple way to print 2D millimetre-sized motors. The motors are shaped like fish, swim autonomously while performing specific functions and avoid the costs and complications of more traditional fabrication processes, such as electrodeposition, sputtering and lithography.

To read the full article please visit Chemistry World.

Self-propelled screen-printable catalytic swimmers
Rajan Kumar, Melek Kiristi, Fernando Soto, Jinxing Li, Virendra V. Singh and Joseph Wang �
RSC Adv., 2015,5, 78986-78993
DOI: 10.1039/C5RA16615B, Paper

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Molecular container mops up tricaine to reverse anaesthesia in fish

A lack of clinically available antidotes for general anaesthesia has prompted a team of researchers in China and Canada to explore the potential of a macrocyclic compound for halting anaesthesia in zebrafish. General anaesthetics put patients into reversible comas before surgery, but their effects can linger beyond their usefulness, resulting in neurotoxicity and cardiotoxicity, or in death, so if an equivalent molecule could be developed for humans it could save lives.

Cucurbit[n]urils are macrocycles that can inhibit the bioactivity of certain drugs by complexing and encapsulating them to neutralise their effects. Now, Ruibing Wang and co-workers at the University of Macao, China, and Queen’s University in Kingston, Canada, have shown that cucurbit[7]uril can encapsulate the anaesthetic tricaine within its lipophilic cavity. Tricaine acts as a general anaesthetic in cold-blooded animals and fish; in zebrafish it blocks ion channels within nerve membranes. Cucurbit[7]uril acts as a competitive receptor to remove tricaine from these channels and inhibit its anaesthetic properties. The resulting concentration gradient encourages any remaining tricaine to migrate away from the ion channel junction and into the plasma, to be snapped up by further host macrocycles.

To read the full article visit Chemistry World.

In vivo reversal of general anesthesia by cucurbit[7]uril with zebrafish models
Huanxian Chen, Judy Y. W. Chan, Shengke Li, Jessica J. Liu, Ian W. Wyman, Simon M. Y. Lee, Donal H. Macartney and Ruibing Wang
RSC Adv., 2015,5, 63745-63752
DOI: 10.1039/C5RA09406B

 

 

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What a pain in the piezoelectrics

What is pain? It can be described as a feeling. It alerts us to damage, and its onset can help to protect us from hurting ourselves again or further.

According to the T-800 of the Terminator series, pain is data, and there are many scientists out there who would agree; however, it would have been an entirely different film if Arnold Schwarzenegger had threatened people with processing proteomics analyses.

While making robots ‘feel’ pain may seem the stuff of sci-fi movies, Yeri Jeong and co-workers show us in their recent publication in RSC Advances, that it is a very legitimate line of research. If robots can feel pain, it can improve their range of applications, especially in harsh environments as they may engage a protective mode.

The research team, based in Korea and the UK, have created a nanowire array that can detect signals based on pattern analysis and pressure, for example, the sharp point of a pencil would be more painful than the soft end with the eraser. The electromechanical structure used comprising flexible ZnO nanowires can mimic the different deformations of the skin to generate a signal. Once that signal goes above a threshold pressure level, it yields an artificial pain signal based on both pattern analysis and force.

They tested the array with a variety of different objects and pressure levels with an earplug and a pen lid, amongst other objects of torture. The array produced a ‘pain’ signal when stabbed with a sharp object at high force, in a quick response time. Yeri Jeong said ‘I’ll be back’ with more sensors – ok, I made that bit up but they do write that the simple design may find application in various devices and the robot industry.

To find out more, click below to read the full article in RSC Advances.

Psychological tactile sensor structure based on piezoelectric nanowire cell arrays
, Yeri Jeong, Minkyung Sim, Jeong Hee Shin, Ji-Woong Choi, Jung Inn Sohn, Seung Nam Cha, Hongsoo Choi, Cheil Moon and Jae Eun Jang, RSC Adv., 2015, 5, 40363-40368 (DOI: 10.1039/C5RA05744B)


Sarah Brown Sarah Brown is a guest web-writer for RSC Advances. Sarah hung up her lab coat after finishing her PhD and post-doctorate in nanotechnology for diagnostics and therapeutics and now works in academic publishing. When not trying to explain science through ridiculous analogies, you can often find her crocheting, baking or climbing, but not all at once.

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Mineral analysis surveys shark smile evolution

The team compared dinosaur and prehistoric shark teeth with those from great white sharks (Carcharodon carcharias)

New research by scientists in Germany has uncovered a curious difference between present-day shark teeth and those of their prehistoric relatives. Although the tooth structure of extinct sharks, like the giant Megalodon, was remarkably similar to great whites and other modern-day sharks, the material they were made from bore a closer resemblance to dinosaur teeth and hints that this change in composition might be down to a dramatic environmental change.

Most animal teeth contain a layer of hard enamel, a soft dentin middle and inner pulp. Dentin and enamel are usually composed of the mineral hydroxyapatite but modern-day sharks differ; their enamel equivalent uses fluoroapatite.

To read the full article visit Chemistry World.

Dental lessons from past to present: ultrastructure and composition of teeth from plesiosaurs, dinosaurs, extinct and recent sharks
A. Lübke, J. Enax, K. Loza, O. Prymak, P. Gaengler, H.-O. Fabritius, D. Raabe and M. Epple  
RSC Adv., 2015,5, 61612-61622
DOI: 10.1039/C5RA11560D, Paper

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Leather gets a new perfume

At a time when materials are increasingly having dual functions, researchers at the Central Leather Research Institute in India are developing ‘smart leathers’. Now, a team there has established a method for imparting leather with a long-lasting lemongrass scent.

Raghava Rao and colleagues used emulsion polymerisation to encapsulate lemongrass oil because of its speed and scalability. Despite the volatile nature of essential oils, when encapsulated in a biopolymer made from chitosan and acrylic acid, the lemongrass scent persists for up to three years. With an average diameter of 117nm, the nanospheres were uniformly distributed within spaces across the leather matrix, and the resulting hydrophilicity and lipophilicity suggests the oils penetrated into the leather.

The nanospheres diffused into the leather matrix and deposited on the collagen fibres

To read the full article visit Chemistry World.

Development of smart leathers: incorporating scent through infusion of encapsulated lemongrass oil
Punitha Velmurugan, Nishad Fathima Nishter, Geetha Baskar, Aruna Dhathathreyan and Jonnalagadda Raghava Rao  
RSC Adv., 2015,5, 59903-59911
DOI: 10.1039/C5RA05508C, Paper

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Announcing our new peer review process for RSC Advances

Since we launched RSC Advances in 2011, the response from you – our authors and readers – has been overwhelmingly positive. Thanks to you, the journal continues to go from strength to strength, publishing only high quality work that is well conducted and adds to the development of the field, across the breadth of the chemical sciences.

So, we are excited to tell you that – to support this success and our commitment to publishing high-quality research, and to ensure we continue to provide the standard of author service you expect – RSC Advances will shortly be adopting a new Associate Editor peer review process.

What does an Associate Editor peer review process mean?

First and foremost, it means that you can be sure that your work will be in the safe hands of an expert, every step of the way.

Phase 1: Your manuscript will be assigned to an Associate Editor, matching its subject area to the Associate Editor’s knowledge and expertise.

Phase 2: Expertise from an extended Reviewer Panel will be utilised; reviewers will assess your article and submit a report to the Associate Editor. In parallel, the Associate Editor will prepare a report on your paper.

Phase 3: The Associate Editor assigned to your work will make a decision about your manuscript based on both their report and the reviewer’s report.

RSC Advances Editor-in-Chief Mike Ward will continue in his position, helping to guide and develop the journal. Both he and the Editorial Board have provided their full support to the new process, which, in the coming months, will see the appointment of additional Associate Editors, all experts in their field, and an extended specialist Reviewer Panel.

Leading the way in innovation

On launch in 2011, RSC Advances’ sophisticated topic modelling provided users with enhanced browsing, enabling you to search for articles under one or more of 12 main subject categories. This search capability was soon extended by more than 100 additional sub-categories. In November 2013, the capacity to sign up to subject-based alerts, taking you straight to the content that is most relevant to you, again made RSC Advances stand out from the crowd.

Now, the journal is proud to once again be leading the way with an innovative new peer review process that will ensure we continue to publish only quality research, whilst providing the best customer service for our authors.

Submit your article now, and see the benefits for yourself.

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Bacteria redefine reinforced concrete

Let’s talk good bacteria, and I don’t mean the kind in your yoghurt. No, I’m talking the kind in your concrete. Fear not, it is not a new breakfast craze. E. coli-based bioconcrete materials have been around for some time now, imbuing properties that allow cracks in the concrete to heal, improving the strength and durability of this material and also all lovely and green – reducing the overall energy cost and carbon dioxide generated in comparison to conventional processes.

Writing in RSC Advances, Manas Sarkar and co-workers have made the good bacteria even better by taking a gene from a bacterium that survives in hot springs, thriving at around 65 ˚C, amplifying it by PCR and implanting it in E. coli bacteria, engineering a unique strain. The gene in question is a silica leaching gene, which has previously been reported to impart higher compressive strength and durability. They add the gene into E. coli as these bacteria are easy to handle, effective at ambient temperatures and more efficient economically.
Development of an improved E. coli bacterial strain for green and sustainable concrete technology

Concrete samples with the modified bacteria were shown to be 30% stronger than the control, thought to be in part a result of the protein producing a new silicate phase that fills the matrices of micropores in the material.

So, while you may think it a good idea to slather that crack in your ceiling with some probiotic yoghurt from the fridge – stand fast. The smarter bioconcrete is coming.

To find out more, click below to read the full article in RSC Advances.

Development of an improved E. coli bacterial strain for green and sustainable concrete technology
Manas Sarkar, Nurul Alam, Biswadeep Chaudhuri, Brajadulal Chattopadhyay and Saroj Mandal
RSC Adv., 2015, 5, 32175-32182


Sarah Brown Sarah Brown is a guest web-writer for RSC Advances. Sarah hung up her lab coat after finishing her PhD and post-doctorate in nanotechnology for diagnostics and therapeutics and now works in academic publishing. When not trying to explain science through ridiculous analogies, you can often find her crocheting, baking or climbing, but not all at once.

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Graphene oxide diversifies soil bacteria

Soil bacteria communities become richer and more diverse on exposure to graphene oxide, new research shows.1 This unexpected finding, unearthed by scientists in China, highlights that despite graphene oxide’s potential for widespread environmental release, little is known about its ecological impact.

Digging deeper into the environmental impact of nanomaterial contamination © Shutterstock

Graphene oxide’s abundance of surface oxygen-containing groups makes it a useful precursor to the graphene-based materials poised to revolutionise electronics and nanoproduct industries. Soil ecosystems will likely bear the brunt of nanomaterial contamination and while previous studies have looked at graphene oxide’s effect in pure bacterial cultures, soil is a much more complicated medium with diverse microbial communities that demand closer investigation. Now a team led by Xiangang Hu and Qixing Zhou’s of Nankai University has studied the effects of graphene oxide in the soil for 90 days using high-throughput sequencing analysis.

To read the full article visit Chemistry World.

Graphene oxide regulates the bacterial community and exhibits property changes in soil
Junjie Du, Xiangang Hu and Qixing Zhou  
RSC Adv., 2015,5, 27009-27017
DOI: 10.1039/C5RA01045D, Paper

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Engineered bacteria synthesise palladium biosorbent

Although catalytic converters are crucial in the fight against air pollution, they do release palladium into the environment © Shutterstock

Genetically modified Escherichia coli can synthesise a protein that could work as a palladium biosorbent to recover the precious metal from polluted water, new research shows. 

Catalytic converters are hugely important for controlling car exhaust fumes but small amounts of the palladium, and other platinum group elements, that form their main active component are leaking into and contaminating the environment. ‘Global palladium resources are scarce,’ warns sustainability expert Magdalena Titirici, of Queen Mary University of London, UK, who was not involved in the study. ‘Therefore recovering noble metals such as palladium from the urban environment using low cost and environmentally friendly adsorbents is of major importance.’

To read the full article visit Chemistry World.

Designed biomolecule–cellulose complexes for palladium recovery and detoxification
Ian Sofian Yunus and Shen-Long Tsai  
RSC Adv., 2015,5, 20276-20282
DOI: 10.1039/C4RA16200E, Paper

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