New and improved right to the last drop

Now, researchers writing in the latest issue of Advanced Materials have developed a way to trap these biomolecules in tiny silica gel beads that could help get your clothes cleaner still by swelling to release the biomolecule at the appropriate time in the wash cycle. The gel beads could also extend the shelf life of countless consumer products so that they continue working well right to the last drop.

Bakul Dave and colleagues at Southern Illinois University Carbondale and Genencor International in Palo Alto, California, have come up with a "new and improved" way of making detergents and other cleaning and conditioning products that really does work. They used tiny beads of silica gel to trap biomolecules, such as enzymes known as alkaline proteases, which are commonly used in liquid detergents and washing powders to help remove proteins and other stains from dirty clothes.

The gel beads act as microscopic reservoirs for the biomolecules, releasing their contents only when the conditions are right in the wash. This means that the fragile enzymes, which can stop working after being exposed to heat, air and light for too long on the shelf, are protected from the outside world until they are needed in the washing machine. This means the product will continue to work as well as the manufacturer intended until the very last drop is poured from the bottle.

The microscopic gel beads are synthesised from the precursor bis[3-(trimethoxysilyl)propyl] ethylenediamine (enTMOS). The researchers demonstrated that these beads can swell and contract depending on the chemical conditions in which they find themselves. In concentrated form, the gel beads remain concentrated and tightly sealed. However, add water and the concentration drops and they are free to expand. It is this swelling process that is key to protecting the biomolecules until they are needed. The biomolecules can be trapped inside the beads during manufacture and will only be released promptly by adding water so that they remain isolated and protected until they are needed.

The team tested their swell gels as an additive to two different detergents: the first was a generic detergent ingredient, concentrated sodium dodecyl sulfate (SDS), while the second was a commercial laundry product with its enzyme content destroyed by heating to 90 °C for one hour. They then added the swell gels containing a test enzyme to each detergent.

The gels remained tight and contracted in the detergents, but as water was added, they began to swell and release their contents "into the wash". The researchers also tested shelf-life of the gels in detergent and found that very little enzyme leached out of the gel beads during storage–just about one percent from their swell gels. Also, they found that the enzyme in the swell gels was much more stable and was able to function even after heating to 80 °C as opposed to total loss of activity with a control experiment using a standard enzyme solution.

The swell gels have obvious applications in laundry detergents and fabric care applications, say the researchers. They add that the unique mechanism they have created with these materials which swell and contract depending on their environment bears a "rather striking resemblance" to the way living cells maintain water content and could provide biologists with a simple model for studying this process.

Citation: Bakul C. Dave, Osmoresponsive Glasses: Osmotically Triggered Volume Changes of Organosilica Sol-Gels as a Means for Controlled Release of Biomolecules, Advanced Materials 2006, 18, No. 15, doi: 10.1002/adma.200600852

Source: Advanced Materials

Videos Extract Mechanical Properties of Liquid-Gel Interfaces
Blood coursing through vessels, lubricated cartilage sliding against joints, ink jets splashing on paper—living and nonliving things abound with fluids meeting solids. However important these liquid/solid boundaries may be, conventional methods cannot measure basic mechanical properties of these interfaces in their natural environments. Now, researchers at the National Institute of Standards and Technology and the University of Minnesota have demonstrated a video method that eventually may be able to make measurements on these types of biological and industrial systems.
Extra-large 'atoms' allow Penn physicists to solve the riddle of why things melt
Physicists at the University of Pennsylvania have experimentally discovered a fundamental principal about how solid materials melt. Their studies have shown explicitly that melting begins at defects within the crystalline structure of solid matter, beginning along the cracks, grain boundaries and dislocations that are present in the otherwise orderly array of atoms. Their findings, which will appear today in the journal Science, answer longstanding fundamental questions about melting and will likely influence research in physics, chemistry, materials science and engineering, as well as studies of biological importance.
How chromosomes meet in the dark -- Switch that turns on X chromosome matchmaking
A research group lead by scientists at the University of Warwick has discovered the trigger that pulls together X chromosomes in female cells at a crucial stage of embryo development. Their discovery could also provide new insights into how other similar chromosomes spontaneously recognize each other and are bound together at key parts of analogous cell processes. This is an important mechanism as the binding togetgher of too many of too few of a particular chromosome can cause a number of medical conditions such as Down's Syndrome or Turner's Syndrome.
Scientists watch membrane fission in real time
Researchers at The Scripps Research Institute have solved one of biology's neatest little tricks: they have discovered how a cell's outer membrane pinches a little pouch from itself to bring molecules outside the cell inside—without making holes that leak fluid from either side of the membrane.
Scans show immune cells intercepting parasites
Researchers may have identified one of the body's earliest responses to a group of parasites that causes illness in developing nations.
Researchers focus on building telescope at South Pole
It's 40 degrees F below zero (with the wind chill) at the South Pole today. Yet a research team from the University of Delaware is taking it all in stride.
Magnetic nanotags allow sensitive detection of cancer biomarkers
(PhysOrg.com) -- The detection of cancer-associated proteins, or biomarkers, in blood samples is a potentially powerful tool for early diagnosis of cancer and monitoring of cancer treatment. A team led by researchers at Stanford University and the University of California, Santa Cruz, has developed a compact prototype detector that uses magnetic nanotechnology to spot cancer-associated proteins in a human blood serum sample with much higher sensitivity than current detectors.
New holographic method could be used for lab-on-a-chip technologies
Researchers at Purdue University have developed a technique that uses a laser and holograms to precisely position numerous tiny particles within seconds, representing a potential new tool to analyze biological samples or create devices using nanoassembly.

New and improved right to the last drop

Related stories:

News discussion: