Tag Archive: Cells

University of Florida researchers have moved a step closer to treating diseases on a cellular level by creating a tiny particle that can be programmed to shut down the genetic production line that cranks out disease-related proteins. In laboratory tests, these newly created “nanorobots” all but eradicated hepatitis C virus infection. The programmable nature of the particle makes it potentially useful against diseases such as cancer and other viral infections. The research effort, led by Y. Charles Cao, a UF associate professor of chemistry, and Dr. Chen Liu, a professor of pathology and endowed chair in gastrointestinal and liver research in the UF College of Medicine, is described online this week in the Proceedings of the National Academy of Sciences. “This is a novel technology that may have broad application because it can target essentially any gene we want,” Liu said. “This opens the door to new fields so we can test many other things. We’re excited about it.”

During the past five decades, nanoparticles — particles so small that tens of thousands of them can fit on the head of a pin — have emerged as a viable foundation for new ways to diagnose, monitor and treat disease. Nanoparticle-based technologies are already in use in medical settings, such as in genetic testing and for pinpointing genetic markers of disease. And several related therapies are at varying stages of clinical trial. The Holy Grail of nanotherapy is an agent so exquisitely selective that it enters only diseased cells, targets only the specified disease process within those cells and leaves healthy cells unharmed.

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Scientists have invented artificial pores as small as the ones in your cells—something unimaginable until now. These sub-nanometer synthetic pores are so tiny that they can distinguish between ions of different substances, just like a real cell. It’s an amazing engineering feat. Once they tune them to detect different substances, researchers claim that this seemingly miraculous matter would be able to do truly incredible things, from “purifying water to kill tumors and diseases by regulating the substances inside of cells.”

The scientists used the Advanced Photon Source at Argonne National Laboratory to create the pores, gluing donut-shaped molecules—called rigid macrocycles—on top of each other using hydrogen bonding. According to one of the senior authors of the study, University of Nebraska-Lincoln Ameritas University’s chemistry professor Xiao Cheng Zeng—”this nanotube can be viewed as a stack of many, many rings. The rings come together through a process called self-assembly, and it’s very precise. It’s the first synthetic nanotube that has a very uniform diameter.” They are about 8.8 angstroms thick, just one tenth of a nanometer.

They are now capable of passing potassium ions and water, but not other ions, like sodium and lithium ions. Basically, this means that you could pass salt water through a fabric made of this wonder material and make it drinkable—instantly. Lead researcher Dr. Bing Gong—a chemistry professor at University of Buffalo—says that “the idea for this research originated from the biological world, from our hope to mimic biological structures, and we were thrilled by the result. We have created the first quantitatively confirmed synthetic water channel. Few synthetic pores are so highly selective.” Gong says that they now have to experiment with the pores’ structure to find out how the materials are transported through the pores and tune it to select which substances they want to filter and which ones they want to let through. If they are successful, this material has an incredible potential to change almost everything.

The Birth of Brain Cells

This might look like a distant web of galaxies captured by a powerful telescope, but it’s actually a microscopic image of a newborn nerve cell. The human brain contains more cells than there are stars in our galaxy, and the most important cells are neurons, which are nerve cells responsible for transmitting and processing electro-chemical signals at up to 320 km/h. This chemical signalling occurs through synapses—specialised connections with other cells, like wires in a computer. Each cell can receive input from thousands of others, so a typical neuron can have up to ten thousand synapses—i.e., can communicate with up to ten thousand other neurons, muscle cells, and glands. Estimates suggest that adult humans have approximately 100 billion neurons in their brain, but unlike most cells, neurons don’t undergo cell division, so if they’re damaged they don’t grow back—except, apparently, in the hippocampus (associated with memory) and the olfactory bulb (associated with sense of smell). The process by which this occurs is unclear, and this image was taken during a project to determine how neurons are born—it actually depicts newborn nerve cells in an adult mouse’s brain.

The Inner Life of the Cell

Harvard University selected XVIVO to develop an animation that would take their cellular biology students on a journey through the microscopic world of a cell, illustrating mechanisms that allow a white blood cell to sense its surroundings and respond to an external stimulus.

Your body will assemble 30 million new cells in the time it takes to read this. Each has the complexity of a medium-sized city.

Scientist say they have managed to turn patients’ own skin cells into healthy heart muscle in the lab. Ultimately they hope this stem cell therapy could be used to treat heart failure patients. As the transplanted cells are from the individual patient this could avoid the problem of tissue rejection, they told the European Heart Journal. Early tests in animals proved promising but the experimental treatment is still years from being used in people.

Experts have increasingly been using stem cells to treat a variety of heart problems and other conditions like diabetes, Parkinsons disease or Alzheimer’s. Stem cells are important because they have the ability to become different cell types, and scientists are working on developing ways to get them to repair or regenerate damaged organs or tissues. More than 750,000 people in the UK have heart failure. It means the heart is not pumping blood around the body as well as it used to.

Researchers are looking at ways of fixing the damaged heart muscle. In the latest study, the team in Israel took skin cells from two men with heart failure and mixed the cells up with a cocktail of genes and chemicals in the lab to create the stem cell treatment. The cells that they created were identical to healthy heart muscle cells. When these beating cells were transplanted into a rat, they started to make connections with the surrounding heart tissue.

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Chemists have created artificial self-assembling cell membranes that could help shed light...

The cell membrane is one of the most important components of a cell because it separates the interior from the environment and controls the movement of substances in and out of the cell. In a move that brings mankind another step closer to being able to create artificial life forms from scratch, chemists from the University of California, San Diego (UCSD), and Harvard University have created artificial self-assembling cell membranes using a novel chemical reaction. The chemists hope their creation will help shed light on the origins of life.

As the basic structural and functional unit of all known living organisms, the cell is the smallest unit of life that is classified as a living thing. Although there are various theories – meteorites, deep-sea vents, lightning – there is still no scientific consensus regarding the origin of the first cell.

“We don’t understand this really fundamental step in our existence, which is how non-living matter went to living matter,” said Neal Devaraj, assistant professor of chemistry at UCSD. “So this is a really ripe area to try to understand what knowledge we lack about how that transition might have occurred. That could teach us a lot – even the basic chemical, biological principles that are necessary for life.”

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A pore cluster

Scientists at The University of Nottingham are leading an ambitious research project to develop an in vivo biological cell-equivalent of a computer operating system.
The success of the project to create a ‘re-programmable cell’ could revolutionise synthetic biology and would pave the way for scientists to create completely new and useful forms of life using a relatively hassle-free approach.Professor Natalio Krasnogor of the University’s School of Computer Science, who leads the Interdisciplinary Computing and Complex Systems Research Group, said: “We are looking at creating a cell’s equivalent to a computer operating system in such a way that a given group of cells could be seamlessly re-programmed to perform any function without needing to modifying its hardware.”

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