An 'attractive' man-machine interface

Don Ingber, MD, PhD, and Robert Mannix, PhD, of Children’s program in Vascular Biology, in collaboration with Mara Prentiss, PhD, a physicist at Harvard University, devised a way to get tiny beads – 30 nanometers (billionths of a meter) in diameter – to bind to receptor molecules on the cell surface. When exposed to a magnetic field, the beads themselves become magnets, and pull together through magnetic attraction. This pull drags the cell’s receptors into large clusters, mimicking what happens when drugs or other molecules bind to them. This clustering, in turn, activates the receptors, triggering a cascade of biochemical signals that influence different cell functions.

The technology could lead to non-invasive ways of controlling drug release or physiologic processes such as heart rhythms and muscle contractions, says Ingber, the study’s senior investigator. More importantly, it represents the first time magnetism has been used to harness specific cellular signaling systems normally used by hormones or other natural molecules.

“This technology allows us to control the behavior of living cells through magnetic forces rather than chemicals or hormones,” says Ingber. “It may provide a new way to interface with machines or computers in the future, opening up entirely new ways of controlling drug delivery, or making detectors that have living cells as component parts. We’ve harnessed a biological control system, but we can control it at will, using magnetic forces.”

In a demonstration involving mast cells (a kind of cell in the immune system), Ingber and Mannix showed that the beads, when bound to cell receptors and exposed to a magnetic field, were able to stimulate an influx of calcium into the cells. (Calcium influx is a fundamental signal used by nerve cells to initiate nerve conduction, by heart and muscle cells to stimulate contractions and by other cells for secretion.) Magnetic fields alone, without the beads, had no effect.

The beads’ 30-nm size (with an inner 5-nm particle) provides the optimal crystal geometry to make them “superparamagnetic” – able to be magnetized and demagnetized over and over, notes Mannix, who shares first authorship of the paper with Sanjay Kumar, MD, PhD of Children’s. (Kumar is now a faculty member in Bioengineering at the University of California at Berkeley.) To give a sense of scale, one nanometer is to a meter (about a yard) as one blueberry is to the diameter of the Earth.

The beads were made to attach to the mast-cell receptors by pre-coating them with antigens; these antigens then bound to antibodies that coated the receptors, similar to the way antibodies bind to antigens in the immune system. “Our goal was to have one antigen coating each bead, so that each bead would bind to just one receptor,” Mannix says.

As an accompanying News & Views article notes, “scaling down the interactions to single receptors demonstrates unprecedented control at the individual protein level.”

Electrical stimuli have been used to influence the activity of nerve cells, but isn’t effective in cells that aren’t electrically excitable by nature, the researchers note. The advantage of a “nanomagnetic” control system is that it can be used in a broad range of cell types and provides a near-instantaneous on-off switch, unlike hormones and chemicals that can take minutes to hours to act and then may linger in the body. In addition, magnets can be portable and have low power requirements, allowing their use in the military and other mobile situations.

Ingber envisions a kind of pacemaker that would involve an injection of nanoparticles into the heart that could then be controlled magnetically. “You could make those cells responsive to magnetic forces that work through the skin, rather than having to do surgical implants or place wires,” he speculates.

“You could also have a pacemaker for muscles in different parts of your body, or a pacemaker for producing hormones or insulin,” Ingber adds. “If you’re a diabetic, you could have cells that produce insulin put under your skin, and then inject nanoparticles that go to those cells. Then, when you have a meal and need more insulin, you could just use a magnet to cause the cells to produce more. So you wouldn’t have to keep buying the drug and injecting it.”

The nanomagnetic system could also interface with external instruments and computer controls that take in information from the body or the surrounding environment and activate the magnet as needed, Ingber adds.

A diabetic, for example, could have a transdermal glucose sensor that controls the magnet, which then controls the insulin production by itself. In the neonatal intensive care unit, sick newborns could have their heart and breathing rates monitored and their cells rigged to respond through magnetic stimulation, without a tangle of wires and probes. Or, on the battlefield, the magnet could trigger production of an antidote when a toxin or infectious agent is sensed in the environment.

But these examples are just theoretical. “The applications are hard to define because we’re opening up a whole new area of control that never existed before,” Ingber says.

Source: Children's Hospital Boston

Study: New way to spot breast cancer shows promise
(AP) -- A radioactive tracer that "lights up" cancer hiding inside dense breasts showed promise in its first big test against mammograms, revealing more tumors and giving fewer false alarms, doctors reported Wednesday. The experimental method - molecular breast imaging, or MBI - would not replace mammograms for women at average risk of the disease.
Loneliness undermines health as well as mental well-being
Feeling connected to others is vital to a person's mental well-being, as well as physical health, research at the University of Chicago shows.
New stem cell tools to aid drug development
SCIENTISTS have designed, developed and tested new molecular tools for stem cell research to direct the formation of certain tissue types for use in drug development programmes.
Age-related memory loss tied to slip in filtering information quickly
Scientists have identified a way in which the brain's ability to process information diminishes with age, and shown that this break down contributes to the decreased ability to form memories that is associated with normal aging.
World first: Lasers used in keyhole surgery for brain cancer
In a ground-breaking advance, French neurosurgeons on Friday said they had successfully treated brain tumours through ultra-keyhole surgery, using a tiny fibre-optic laser to destroy cancerous cells.
Cell removal technique could lead to cheaper drugs
Researchers at the University of Edinburgh have pioneered a simple way to remove dead cells from cell cultures used to make protein-based drugs, which are increasingly prescribed to treat a range of illnesses.
Normalizing tumor vessels to improve cancer therapy
Chemotherapy drugs often never reach the tumors they're intended to treat, and radiation therapy is not always effective, because the blood vessels feeding the tumors are abnormal—"leaky and twisty" in the words of the late Judah Folkman, MD, founder of the Vascular Biology program at Children's Hospital Boston.
Carnegie Mellon MRI technology that non-invasively locates, quantifies specific cells in the body
Magnetic resonance imaging (MRI) isn't just for capturing detailed images of the body's anatomy. Thanks to novel imaging reagents and technology developed by Carnegie Mellon University scientist Eric Ahrens, MRI can be used to visualize — with "exquisite" specificity — cell populations of interest in the living body. The ability to non-invasively locate and track cells, such as immune cells, will greatly aid the study and treatment of cancer, inflammation, and autoimmune diseases, as well as provide a tool for advancing clinical translation of the emerging field of cellular regenerative medicine, by tracking stem cells for example.

An 'attractive' man-machine interface

Related stories:

News discussion: