Chagas World

The simple answer to this one is that nature likes to take the path of least resistance. Soap bubbles are round because spheres are the smallest possible shape nature can create to enclose the gas inside a bubble.

Ebola Edits Its Messages Deep sequencing of viral mRNAs reveals that Ebola and Marburg viruses produce multiple versions of some transcripts.

The Ebola and Marburg viruses, both members of the filovirus family, wreak havoc on host cells with just seven open reading frames (ORFs) encoded by a 19-kilobase RNA genome. But a comprehensive examination of viral messenger RNAs, published yesterday (November 4) in mBio, has uncovered hidden variation in some of the transcripts produced by Ebola and Marburg when they infect animal cells.

Researchers at the Icahn School of Medicine at Mount Sinai in New York City and their colleagues infected monkey and human cell lines with both viruses, and performed Illumina sequencing on RNA isolated from the cells at different time points after infection.

An analysis of the viral transcripts identified sites where the viral polymerase inserted nucleotides, likely leading to previously undescribed proteins. The messenger RNA (mRNA) encoding the Ebola glycoprotein was the most commonly edited, while transcripts for the Marburg virus nucleoprotein and polymerase were also altered.

Investigating variability in the Ebola glycoprotein could be particularly important for the development of vaccines and treatments, since this protein plays a role in virulence and mediates the attachment of the virus to host cells.

“The bottom line is we know these changes occur but we don’t yet know what it really means in the biology of the virus,” study coauthor Christopher Basler said in a press release. Basler added that the life cycles of filoviruses are not well understood, “so we need a complete description of how they grow to develop new strategies used to treat the infections.”

Penn Study Shows Bed Bugs Can Transmit Parasite that Causes Chagas Disease

The bed bug may be just as dangerous as its sinister cousin, the triatomine, or “kissing” bug. A new study from Penn Medicine researchers in the Center for Clinical Epidemiology and Biostatistics demonstrated that bed bugs, like the triatomines, can transmit Trypanosoma cruzi, the parasite that causes Chagas disease, one of the most prevalent and deadly diseases in the Americas.

The role of the bloodsucking triatomine bugs as vectors of Chagas disease—which affects 6 to 8 million worldwide, mostly in Latin America, and kills about 50,000 a year—has long been recognized. The insects infect people not through their bite but feces, which they deposit on their sleeping host, often around the face, after feeding. Bed bugs, on the other hand, are usually considered disease-free nuisances whose victims are left with only itchy welts from bites and sleepless nights.

Dennis Aabo was able to feel what was in his hand via sensors connected to nerves in his upper arm

Scientists have created a bionic hand which allows the amputee to feel lifelike sensations from their fingers.

A Danish man received the hand, which was connected to nerves in his upper arm, following surgery in Italy.

Dennis Aabo, who lost his left hand in a firework accident nearly a decade ago, said the hand was “amazing”.

In laboratory tests he was able to tell the shape and stiffness of objects he picked up, even when blindfolded.

The details were published in the journal Science Translational Medicine.

Implant

An international team carried out the research project, which included robotics experts from Italy, Switzerland and Germany.

"It is the first time that an amputee has had real-time touch sensation from a prosthetic device" said Prof Silvestro Micera from the Ecole Polytechnique Federale de Lausanne and Scuola Superiore Sant’Anna, Pisa.

The scientific advance here was not the hand itself, but the electronics and software that enabled it to give sensory feedback to the brain.

Micera and his team added sensors to the artificial hand which could detect and measure information about touch. Using computer algorithms, the scientists transformed the electrical signals they emitted into an impulse that sensory nerves could interpret.

During an operation in Rome, four electrodes were implanted onto nerves in the patient’s upper arm. These were connected to the artificial sensors in the fingers of the prosthetic hand, so allowing touch and pressure feedback to be sent direct to the brain.

Mr Aabo, 36, a property developer, spent a month doing laboratory tests, firstly to check the electrodes were functioning, and then with these fully connected to the bionic hand.

He said: “The biggest difference was when I grabbed something I could feel what I was doing without having to look. I could use the hand in the dark.

"It was intuitive to use, and incredible to be able to feel whether objects were soft or hard, square or round."

Hero

The bionic hand is still a prototype, and due to safety restrictions imposed on clinical trials, Mr Aabo required a second operation to remove the sensors.

"He is a hero," said Professor Paolo Rossini, neurologist, University Hospital Agostino Gemelli, Rome.

"He gave a month of his life and had two operations to test this device.

"We are all very grateful to him."

Prof Rossini said a lot of pre-training was done involving surgery on pigs, and with human cadavers, to ensure they knew exactly how to attach electrodes to the tiny peripheral nerves in the upper arm.

Another member of the team, Dr Stanisa Raspopovic said: “It was a very exciting moment when after endless hours of testing….Dennis turned to us and said with disbelief, ‘This is magic! I can feel the closing of my missing hand!’”

Those working in the field in the UK were also enthusiastic.

"This is very interesting work, taking research in upper limb prosthetics into the next stage by adding sensory feedback, said Dr Alastair Ritchie, Lecturer in Biomaterials and Bioengineering, University of Nottingham.

"This technology would enable the user to know how firmly they are gripping an object, which is vital for handling fragile objects - imagine picking up an egg without any feeling in your fingers."

The international team is now working on how to miniaturise the technology so that it could be used in the home.

"We must get rid of the external cables and make them fully implantable" said Prof Thomas Stieglitz, University of Frieburg, Germany, whose laboratory created the ultra-thin implantable electrodes.

Recently, scientists in Cleveland, Ohio released a video of a patient using the fingers of a prosthetic hand to pull the stalks from cherries while blindfolded. But the research has not yet been published in a peer-reviewed journal.

There is no precise timetable, but scientists think it could be a decade before a sensory feedback bionic hand is commercially available.

And they believe it may pave the way for more realistic prosthetic devices in the future which can detect texture and temperature.

'Bring it on'

But it will undoubtedly be very expensive, well beyond the means of most patients. And artificial hands still lack the precision and dexterity of the real thing.

The super-functioning bionic hand of science fiction films remains the stuff of fiction.

Nonetheless, Dennis Aabo, who now has his old prosthesis back, is ready to swap it for the bionic hand in any future trial.