Tag: ‘Health’

Artificial bones made with 3D inkjet printers

13 Aug 2007

Custom artificial bone made on 3D inkjet printer -- Researchers from the Tissue Engineering Department at the University of Tokyo Hospital and venture company Next 21 are using 3D inkjet printers to produce tailor-made artificial bones for use in facial reconstructive surgery. Following initial trials performed on a Welsh corgi and 10 people over the past year and a half, the researchers are set to begin a more extensive second round of human testing this autumn.

To make an artificial bone with this technology, a 3D computer model of the bone is first created based on the patient's X-ray and CT scan data. The computer model is then sliced into a large number of cross-sections and the data is sent to a special 3D inkjet printer, which works sort of like an ordinary inkjet printer by transferring tiny droplets of liquid onto a surface. However, unlike ordinary printers that print on paper, this one prints onto thin layers of powdered alpha-tricalcium phosphate (alpha-TCP). The "ink" is a water-based polymer adhesive that hardens the alpha-TCP it comes into contact with. By repeatedly laying down the powder and printing successive layers on top of one another, the printer is able to physically reproduce the desired bone to an accuracy of one millimeter.

Strong, lightweight and porous, the printed bones have characteristics similar to natural bone, and because they are tailored to fit exactly where they need to go, they are quick to integrate with the surrounding bone. The printed bone is also designed to be resorbed by the body as the surrounding bone slowly grows into it and replaces it.

In initial human trials conducted between March 2006 and July 2007, the effectiveness and safety of the artificial bones were tested in plastic surgery operations performed on 10 male and female patients between the ages of 18 and 54. In the second round of trials beginning this autumn at 10 medical institutions across Japan, the researchers plan to print up and implant synthetic bones in 70 volunteer patients with face or skull bones that have been damaged or removed due to injury or surgery.

While the printed bones are still not considered strong enough to replace weight-bearing bones, they are ten times stronger than conventional artificial bones made from hydroxylapatite, a naturally occurring mineral that is also the main component of natural bone. The printed bones are also cheaper and easier to make than hydroxylapatite implants, which must be sintered, or heated to a high temperature to get the particles to adhere to each other. In addition to taking longer to produce, sintered implants also take longer for the body to resorb.

The next round of human trials will be conducted at Dokkyo Medical University, Saitama Medical University, Tokyo Dental College, University of Tokyo, Juntendo University, Tsurumi University, Kyoto University, Osaka Medical College, Kobe University and Osaka City General Medical Center.

The researchers hope to make the technology commercially available by 2010.

[Source: Fuji Sankei, The Chemical Daily]

Fourth-generation pig clones born

07 Aug 2007

Fourth-generation clone piglets ---

In a development that brings us one step closer toward the mass-cloning of animals for use in regenerative medicine, researchers from Meiji University have succeeded in creating the world's first fourth-generation pig clones.

Since creating a pair of pig clones in April 2004, professor Hiroshi Nagashima, the research team leader, has been recloning the clones using cells from their salivary glands. The fourth-generation piglets -- three of them born on July 23 -- are clones of clones of clones of clones, so they share the exact DNA as the original pig.

Scientists have been seeking to advance pig cloning technology because pig organs are physiologically similar to human organs, meaning they could be the key to alleviating the worldwide shortage of organs for transplant.

Past examples of animals that have been cloned through multiple generations include mice, which have been recloned up to the sixth generation, and cows, which have been recloned to the second generation. While recloning technology may promise to boost the productivity of cloning operations, there are some drawbacks. For instance, in somatic cell nuclear transfer -- a reproductive cloning technique where the nucleus from a donor adult cell (somatic cell) is transferred to a nucleus-free egg cell, which is then transferred into the uterus of a surrogate mother -- DNA damage accumulates with each generation that is cloned. After a number of generations, the cumulative damage to the DNA could result in an animal that is significantly different from the original.

So far, however, the fourth-generation pig clones show no signs of abnormalities, and the researchers are planning to reclone them again.

In addition to creating the world's first fourth-generation pig clones, Nagashima's team also reported success in using a combination of gene transfer technology and cloning technology to create transgenic diabetic pigs -- pigs with human genes that exhibit symptoms of diabetes mellitus. The researchers worked with BIOS Inc., a venture company based in Kanagawa prefecture, to engineer the pigs.

While we have seen transgenic diabetic mice in the past, these transgenic diabetic pigs are reportedly the first of their kind. With the anatomical similarities between man and swine, transgenic diabetic pigs could lead to a cure for diabetes by helping scientists develop transplant technology involving the use of pig pancreatic tissue, a potential source of insulin. In addition, the pigs can also serve as models for observing the complications associated with diabetes, such as arteriosclerosis, and they could help researchers develop new medicines.

Professor Nagashima suggests that in addition to serving as model animals for human diseases, individuals will be able to use their own cells in these bioengineered pigs to test the effectiveness and safety of regenerative medicine therapies.

[Source: Yomiuri, Jiji]

Nandemo Microscope provides USB-powered ear, teeth and skin checks

04 Jul 2007

Nandemo Microscope by Thanko --

Want to know how you really look? USB gadget maker Thanko is planning to release a USB-powered microscope called the "Nandemo Microscope," which ships with four separate attachments, each specifically designed to provide close-up views of different parts of the anatomy. In addition to the standard attachment, the three other attachments allow users to perform oral exams, check inside ears and get close-ups of skin and hair.

With a 1.3 megapixel CMOS sensor, 640 x 480 (VGA) resolution, adustable LED lighting and software for viewing and saving video and still images, you're only a USB connection away from hooking your computer screen up with a very intimate picture of yourself. Whether or not you would actually want to look at it is another question.

The Nandemo Microscope, which is compatible with Windows 2000 Professional/XP/Vista, goes on sale in mid-July at a price of 12,800 yen (slightly more than $100).

[Source: Nandemo Microscope page via IT Media]

Giant jellyfish eyed as commercial mucin source

05 Jun 2007

Echizen kurage, Nomura's jellyfish -- In the latest development in Japan's war against giant jellyfish invaders, scientists studying the biochemistry of echizen kurage (Nomura's jellyfish) have discovered a previously unknown type of mucin in the sea creatures.

Mucins, the main structural components of mucus, are complex proteins found in human saliva, gastric juice and the lining of the stomach, all of which play a key role in the digestive process. The recently discovered jellyfish mucin, according to the researchers from the Institute of Physical and Chemical Research (RIKEN) and science equipment manufacturer Shinwa Chemical Industries, can be put to use in a variety of pharmaceutical, medical, food and cosmetic products.

While the researchers have yet to release the details about the molecular structure of the jellyfish mucin, they claim it has a simple structure similar to a type of glycoprotein (organic molecule composed of protein and sugar chains) found in human digestive fluid, suggesting it could be used as a digestive supplement for elderly people with weak gastric juice. In addition, the researchers see potential uses for jellyfish mucin in products such as eyedrops, artificial saliva and surgical adhesives.

At least 12 types of mucins are known to exist in various locations in the human digestive tract, as well as in saliva and in the mammary glands. While mucins are also known to exist in animals and in some plants such as okra, lotus root and yams, only a few sources of the slimy substance have been tapped for large-scale commercial production.

To harvest the jellyfish, RIKEN says it is investigating the possibility of enlisting the help of Japan's fisheries to catch the giant echizen kurage, which can grow up to 2 meters (6 ft 7 in) in diameter and weigh up to 200 kg (440 lb) each. The group is also considering harvesting moon jellyfish, the culprits responsible for disrupting output at nuclear power plants last year after they clogged seawater coolant intake pipes.

Business negotiations are now underway between 20 organizations, including pharmaceutical companies, medical institutions and food and cosmetics manufacturers.

[Source: Fuji Sankei]

Walkman-style brain scanner

23 May 2007

Portable brain scanner ---

Hitachi has successfully trial manufactured a lightweight, portable brain scanner that enables users to keep tabs on their mental activity during the course of their daily lives. The system, which consists of a 400 gram (14 oz) headset and a 630 gram (1 lb 6 oz) controller worn on the waist, is the result of Hitachi's efforts to transform the brain scanner into a familiar everyday item that anyone can use.

The rechargeable battery-operated mind reader relies on Hitachi's so-called "optical topography" technology, which interprets mental activity based on subtle changes in the brain's blood flow. Because blood flow increases to areas of the brain where neurons are firing (to supply glucose and oxygen to the tissue), changes in hemoglobin concentrations are an important index by which to measure brain activity. To measure these hemoglobin concentrations in real time, eight small surface-emitting lasers embedded in the headset fire harmless near-infrared rays into the brain and the headset's photodiode sensors convert the reflected light into electrical signals, which are relayed to the controller.

The real-time brain data can either be stored in Flash memory or sent via wifi to a computer for instant analysis and display. A single computer can support up to 24 mind readers at a time, allowing multiple users to monitor brain activity while communicating or engaging in group activities.

In addition to health and medical applications, Hitachi foresees uses for the personal mind reader in fields such as psychology, education and marketing. Although it is unclear what neuromarketing applications the company has in mind, it is pretty clear that access to real-time customer brain data would provide marketers with a better understanding of how and why shoppers make their purchasing decisions. One can also imagine interactive campaigns that, for example, ask customers to think positive thoughts about a certain product in exchange for discount coupons or the chance to win a prize.

The technology could also be used in new forms of entertainment such as "mind gaming," where the player's physical brain activity becomes a part of game play. It is also feasible to integrate the brain scanner with a remote control brain-machine interface that would allow users to operate electronic devices with their minds.

Hitachi has yet to determine when the personal mind reader will be made commercially available.

[Source: Tech-On!]

Sick robot takes med training to the uncanny valley

15 May 2007

Robo-patient -- Researchers at Gifu University's Graduate School of Medicine have developed a robotic patient that can respond verbally to questions about how it feels and move its body in ways that exhibit the symptoms of its ailment. The researchers, who developed a less sophisticated "sick" droid last year, claim this robot patient is the world's first to exhibit symptoms in the way it moves.

Modeled after an adult female and equipped with body parts that move in a smooth, human-like way, the android is designed to provide students with valuable hands-on experience in diagnosing rare medical conditions. For example, when suffering from myasthenia gravis -- an often misdiagnosed neuromuscular disease leading to muscle weakness and fatigue -- the robot tells the doctor its eyelids are heavy, and it changes its facial expression, slowly relaxes its shoulders and hunches forward.

"It was difficult to get the shoulder joints and shoulder blades to move like a human," says researcher Yuzo Takahashi. "In the future, we want to program the robot with more symptoms and create a very realistic learning tool." If all goes well, the robot will become part of the curriculum next year.

[Source: Yomiuri]

Android shows off people-lifting skills

29 Mar 2007

Android lifts 60-kg dummy out of bed ---

In a public demonstration held in Tokyo on March 28, a human-sized android showed off its weightlifting skills by successfully picking up a 30-kilogram (66-pound) package from a desk and lifting a 66-kilogram (145-pound) humanoid doll out of bed.

University of Tokyo professor Yasuo Kuniyoshi and his team of engineers developed the 155-centimeter (61-inch) tall, 70-kilogram (154-pound) robot last year. A recent software upgrade allows the robot to move more like a human by constantly adjusting the power of its arm movements based on data received from 1800 tactile sensors embedded in its artificial skin.

It is this system of sensor-based control -- and not large motors -- that gives the robot its strength. "Large motors are not safe for use in household robots," explains Kuniyoshi. "Only a small amount of power is applied at each of this robot's joints, but it can successfully move heavy objects by using the tactile sensors to regulate how it lifts and carries things."

The droid demonstrated different maneuvers for different situations. To lift the 30-kilogram package, the robot used one arm to slowly slide it to the edge of the desktop, where it grabbed the package with its other arm to pick it up. To remove the 66-kilogram dummy from bed, the android slid its arms under the body, lifted it slightly and backed away.

Kuniyoshi says this robot's ability to lift such heavy objects with ease is unusual, and he hopes further improvements will earn the robot a job in nursing care or in the moving industry.

[Sources: Nikkei Net, Mainichi]

Bionic hand with can-crushing grip

22 Mar 2007

Bionic hand crushes CC Lemon can --- A team of researchers from the Tokyo Institute of Technology (TIT) claim to have developed the world's first electromechanical prosthetic hand with a grip strong enough to crush an empty beverage can.

This bionic hand weighs a little more than 300 grams and has a grip strength of around 15 kg (33 lbs), which is about half that of the average adult male. The hand also features four quick, nimble fingers that take as little as 1 second to flex and extend. When used in combination with the hand's opposable thumb, each finger can deftly pinch and pick up small objects of various shapes.

Researchers have long considered it a great challenge to design an electric prosthetic hand with a strong grip. Toru Omata, a graduate school professor at TIT, explains that until now, electromechanical hands have relied solely on motors for their grip. The secret to this bionic hand's strong grip, he explains, is the system of pulleyed cables that run through the fingers and attach at the fingertips.

One day in the future, the proud owner of this bionic hand will be able to crush cans at will. For that to happen, though, the researchers need to outfit the hand with a system of myoelectric control technology, which would allow the user to control the hand by flexing other muscles.

(Watch video of the hand crushing a CC Lemon can.)

[Source: Japan News Network]

Artificial blood vessels made from salmon skin

12 Mar 2007

Artificial blood vessels made from salmon skin --- Researchers from Hokkaido University have created artificial blood vessels using collagen derived from the skin of salmon. The researchers, who replaced the aortas of rats with the artificial blood vessels, claim to be the first to create and successfully test artificial blood vessels made using collagen derived from marine animals.

The researchers decided to use salmon skin for regenerative medicine applications after seeing large amounts of the skin go to waste in local seafood processing operations. On Japan's northern island of Hokkaido, seafood processors discard about 2,000 tons of salmon skin each year -- enough to yield an estimated 600 tons of collagen. In addition, there are no known viruses transmitted from salmon to humans, so the use of salmon collagen is regarded as relatively safe. Scientists have created artificial tissue from bovine (cow) and porcine (pig) collagen in the past, but there have always been concerns over the possible transmission of infectious diseases such as BSE (mad cow disease).

One problem the researchers faced early on was the salmon collagen's poor resistance to heat. Because salmon collagen ordinarily melts at about 19 degrees Celsius (66 degrees Fahrenheit), it could not be used as a tissue replacement in humans. But by developing a process that forms the collagen into fibers and strengthens the bonds between molecules, the researchers were able to raise the melting point of the collagen to 55 degrees Celsius (131 degrees Fahrenheit).

The heat-resistant collagen was used to create blood vessels with an internal diameter of 1.6 mm and a wall thickness of 0.6 mm. When grafted into rats, the artificial blood vessels demonstrated the ability to expand and contract along with the heartbeat, and they were shown to be as strong and elastic as the original aortas.

Nobuhiro Nagai, from Hokkaido University, says the researchers plan to test the blood vessels in larger animals such as dogs. One day they hope to see their biomaterial used in humans as a replacement for damaged blood vessels, he says.

The research results are set to be announced at a meeting of the Japanese Society for Regenerative Medicine (JSRM), which is scheduled to begin in Yokohama on March 13.

[Source: Mainichi]