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Artemisia genipi


Botanical Name: Artemisia genipi
Family: Asteraceae
Tribes: Anthemideae
División: Magnoliophyta
Class: Magnoliopsida
Order: Asterales
Species : A. genipi

*Absinthium tanacetifolium (L.) Gaertn.
*All bocconei artemisia.
*Artemisia laciniata f. dissecta Pamp.
*Artemisia macrophylla Fisch. ex Besser
*Artemisia mertensiana Wallr.
*Artemisia mirabilis Rouy
*Artemisia orthobotrys Kitag.
*Artemisia racemosa Miégev.
*Artemisia rupestris Vill.
*Artemisia serreana Pamp.
*Artemisia spicata (Baumg.) Wulfen ex Jacq.
*Artemisia sylvatica Ledeb.
*All tanacetifolia artemisia.

Common Names: Black Wormwood,
Habitat : Artemisia genipi is native to Austria; France (France (mainland)); Italy (Italy (mainland)); Liechtenstein; Slovenia; Switzerland. It grows in the alpine environment, including moraines , cracks in rocks and scree at an altitude of between 2400 and 3500 m above sea level. It is very rare and is found in the Alps , especially in the western Alps.


Artemisia umbelliformis is a herbiculas perennial plant growing to high.  10-20 cm.  single rod.  Whitish plant, downy-silky, aromatic.  pinnatipartite basal leaves or 3-5 single divisions or tri-quadrifid.  Stem leaves pinnatisect, sup.  often undivided. Flower heads wide 2.5-4 mm, sessile, alone.  more inf.  briefly stalked arranged spiky occupying almost the entire stem and becoming denser up. bracts int.  membranous edge black to blackish brown.

The flowers are hermaphrodite (have both male and female organs) and are pollinated by Insects.Suitable for: light (sandy) and medium (loamy) soils, prefers well-drained soil and can grow in nutritionally poor soil. Suitable pH: acid, neutral and basic (alkaline) soils. It cannot grow in the shade. It prefers dry or moist soil and can tolerate drought.


Medicinal Uses:
Action is similar to that of wormwood only slightly less bitter and a little less efficacious. It stimulates gastric secretion. In medicine it may be replace by wormwood, which is better for sluggish digestion and stomach disturbances. Not often used because of scarcity.

Disclaimer : The information presented herein is intended for educational purposes only. Individual results may vary, and before using any supplement, it is always advisable to consult with your own health care prov



A Step Forward

The Jaipur foot is now even better, thanks to a dedicated group of students from the Massachusetts Institute of Technology.


Looking for a project to do in his third undergraduate year, Goutam Reddy was sure he would not do anything “fashionable”. He was studying electrical engineering and computer science at the Massachusetts Institute of Technology (MIT) in the US. “I wanted something that would find application in the developing world, not the next fast car,” he says.

Reddy grew up in Michigan State, but his parents were of Indian origin. During one of his visits to India, he came to know about the Jaipur foot, which was being fitted to patients by the Bhagwan Mahaveer Viklang Sahayata Samiti in New Delhi. He visited this organisation, trying to understand and improve the technology as part of his project. But he could not find anything to do immediately.

Anyone who sees the Jaipur foot being fitted to patients will never forget the experience. It was no different for Reddy. The Jaipur foot, developed in the 1970s by the late P.K. Sethi, an orthopaedic surgeon, and artisan Ram Chandra, is the one of the best options in the world if you lose your leg. It is lightweight and strong, made of easily available materials like rubber, and costs only $28. An artificial foot in the US would cost a few thousand dollars at least. It was popular among soldiers in war-ravaged countries like Afghanistan. Soldiers who lost their legs came to Jaipur to be fitted with this low-cost miracle. At least 250,000 of these have been fitted to poor people who have lost their legs.

The Jaipur foot (above) gave Sudha Chandran(a great dancer) a new lease of life after she lost a leg in a 1981 accident.

Yet the Jaipur foot is far from perfect. Reddy realised that the manufacturing methods needed improvement. Several devices used in the Jaipur foot could be improved as well. This was expected, because they were still using techniques developed 30 years ago. If the knee is also amputated, as often happens, the patient will not be able to bend his or her leg — in this case, the artificial foot. This is a common problem with most low-cost artificial legs. Although he could not develop a project immediately, Reddy realised that he could improve the Jaipur foot sometime in the future. The fitting process, in particular, seemed in need of betterment.

The traditional way of fitting was to use plaster of paris moulds. A year and a half ago, the Centre for International Rehabilitation in Chicago developed a new process. This consisted of making the amputees put their leg inside sand and then applying a vacuum. The vacuum made the sand rock solid, and the resulting impression a perfect mould. The vacuum is created using an air compressor, and this necessitated the use of a generator. Reddy, along with other MIT students, found a way to eliminate this generator. They also gave a new name to the Samiti: the Jaipur Foot Organisation (JFO).

After Reddy finished his master’s degree at MIT, he set up a non-profit organisation called Developing World Prosthetics. Other MIT students also joined him. These students were also studying engineering at MIT, and they chose improving the Jaipur foot as their undergraduate project. Some of them travelled to India — using a grant from MIT’s public Service Centre and a $7,500 prize from a competition — to work on this. Finally, they developed a method using a cycle pump and human power to generate a vacuum in the fitting process. The students returned with a better perspective of the developing world. “I want to work on developing world prosthetic projects,” says Philip Garcia, one of the students.

Meanwhile, Reddy has initiated a course at MIT on wheelchair design in developing countries. He remains deeply interested in robotic prosthetics, and in improving the Jaipur foot farther. Members of the JFO rarely get the time to improve the original invention. “Our primary aim is to make and fit the foot,” says Sanjeev Kumar, manager of the Delhi branch of the JFO. Reddy and his organisation will now attempt this task.

The dancer enthralls her audience in the hugely popular TV show Jhalak dikhla ja

For example, they are trying to improve the sand-casting system for adoption in rural areas. Another project is to improve the flexibility of the device. If the Jaipur foot is fitted above the knee, the patient has to walk with a straight leg — they can bend the “knee” only when they want to sit. The MIT students and Developing World Prosthetics are now working on this problem. The spring session at MIT has a course on developing world prosthetics, and solving the straight knee problem will be one of their primary tasks.

SourcesL : The Telegraph (Kolkata, India)