Super-Sensor Spots Cancer Markers

Logan Streu, ECS Content Associate & Assistant to the CCO, recently came across this article detailing an electrochemical device’s life saving potential in cancer treatment.

A new electrochemical sensor is paving the way for quick and affordable “liquid biopsies,” opening the possibility of detecting deadly cancer markers in minutes. This new development could help tailor treatments to specific patients and improve the accuracy of initial diagnosis.

Personalized medicine is a huge part of a new, promising future in cancer treatment. With the ability to tailor treatment to each individual tumor, treatments can become more effective and yield less side-effects.

In an effort to get closer to the ultimate goal of tailored cancer treatment, Shana Kelley and her team at the University of Toronto joined forces with a researcher from the Montreal Children’s Hospital in Quebec to develop the new electrochemical super-sensor.

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Graphene Fights Cancer

Graphene oxide is stable in water and has shown potential in biomedical applications.Image: Oncotarget

Graphene oxide is stable in water and has shown potential in biomedical applications.
Image: Oncotarget

They don’t call it the wonder material for nothing. Since its inception, graphene has shown an amazing array of possibilities – from its potential in renewable resources to its ability to revolutionize electronics. Now, it may even be able to aid in the fight against cancer.

Scientists at the University of Manchester have used graphene to target and neutralize cancer stem cells without harming non-cancerous cells. By taking a modified form of graphene called graphene oxide, the researchers have discovered a quality in the material that acts as an anti-cancer agent that selectively targets cancer stem cells.

The graphene oxide formulations show the potential to treat a broad range of cancers with non-toxic material, including: breast, pancreatic, lung, brain, ovarian, and prostate cancer. The scientist state that if the new treatment were to be combined with existing treatment, it could eventually lead to tumor shrinkage as well as stop the spread of cancer and its reassurance after treatment.

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The nanotubes can be tumor-targeted and have a central 'hollow' core that can be loaded with a therapeutic payload.Image: Jing Claussen (iThera Medical, Germany)

The nanotubes can be tumor-targeted and have a central ‘hollow’ core that can be loaded with a therapeutic payload.
Image: Jing Claussen (iThera Medical, Germany)

Gold nanotubes have multiple applications in fighting cancer, including internal nanoprobes for high-resolution imaging and drug delivery vehicles. With new research from the University of Leeds, we’re discovering that these gold nanotubes may also be able to give doctors the chance to treat cancer as soon as they spot it.

“Gold nanotubes – that is, gold nanoparticles with tubular structures that resemble tiny drinking straws – have the potential to enhance the efficacy of these conventional treatments by integrating diagnosis and therapy in one single system,” said Professor at the University of Leeds Institute for Biomedical and Clinical Science Sunjie Ye in a release.

The new study shows the first successful demonstration of biomedical use of gold nanotubes in a mouse model of human cancer. The researchers hope that these results will aid in the treatment of cancer and address the issue of high recurrence rates of tumors after surgical removal.

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Electrochemistry Fights World Cancer

SA10519_WCD_Logo_4cCancer is among the leading causes of mortality worldwide. According to the World Health Organization, approximately 14 million new cases and 8.2 million cancer related deaths were recorded in 2012. If no major breakthroughs are made in the field, that number is expected to rise by 70 percent over the next two decades. In honor of World Cancer Day, we’re taking a look at a few ways electrochemical and solid state science aids in the fight against cancer.

Electrochemical Biosensing for Cancer Detection
By taking biopsy slices for colon cancer, researchers were able to use electrochemical biosensors to distinguish between cancerous and normal epithelial tissues. This development helped promote rapid cancer detection by eliminating pretreatment and providing results obtained within minutes of biopsy removal. Read the full paper here.

Polymer Based Sensors to Diagnose Breast Cancer
There are many issues that mammography faces, including the uncomfortableness of the screening and exposure to radiation. In order to solve this issues, electrochemical scientists developed an Electrical Impedance Tomography (EIT) system. This radiation-less technique aims to enhance early detection capabilities by generating a 3-D map of the breast. Read the full paper here.

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Helping Medicine with Graphene Quantum Dots

Researchers from the University of Sydney have recently published their findings that quantum dots made of graphene can improve bio-imaging and LEDs.

The study was published in the journal Nanoscale, where the scientists detailed how activating graphene quantum dots produced a dot that would shine nearly five times bright than the conventional equivalent.

Essentially, the dots are nano-sized semiconductors, which are fluorescent due to their surface properties. However, this study introduces the utilization of graphene in the quantum dot, which produces an extra-bright dot that has the potential to help medicine.

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Innovative device detects prostate cancer and kidney disease on the spot.
Credit: Brigham Young University

Scientists from Brigham Young University have developed a remarkably simple device that has the potential to save lives.

The innovative device, created by chemist Adam Woolley and his students, can detect prostate cancer and kidney disease on the spot, all by simply dropping a urine sample into a tiny tube and seeing how far it goes.

This from Brigham Young University:

The tube is lined with DNA sequences that will latch onto disease markers and nothing else. Urine from someone with a clean bill of health would flow freely through the tube (the farther, the better). But even at ultra-low concentrations, the DNA grabs enough markers to slow the flow and signal the presence of disease.

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