Sunday, May 25, 2014

artemesia annua l.,huaya,chaya

hello m . everything fine ?From the point off view off herbal medicine i recapitulate¨, the wormwood extract from artemisia annua l was originally used as an infusion for the treatment off malaria , after the archeologicial recovery off the recipe in china it became used and produced in africa and asia from the seventies on,. alcoholic solutions -tincture- give a higher compound concentration, the tablets used on the base off the dry extract in some cases suggests allergic deadly reactions in tanzania one text mentioned-as a cancer treatment for breastcancer it can be very effective with the extracted component artemisinin in watery solution and pumping up the iron content off cancer cells at the same time with holotransferrin, in herbal medicin context , there has to be looked to natural ways to enhance the iron content off cancer cells , which naturally is higher than healthy cells, and so the artemisinin does its work very efficient, that artemisinin part could be done with the infusion or an alcoholic tincture from the point off view off natural medicin, for the pumping up off the iron content off cancer cells a remedy can posibly be found....it just needs some more random literature research at its best, the dried extract is very high in concentration so the tincture or the infusion could sail around most alergic reactions i guess....so far so good...wish you all the best

,wormwood originally used to combat malaria, the recipe was undigged in an archeological dig in the 70ties



This is an archived article.

November 26, 2001



Ancient Chinese folk remedy may hold key to non-toxic cancer treatment

Rob Harrill



Posted under: Archive





Two bioengineering researchers at the University of Washington have discovered a promising potential treatment for cancer among the ancient arts of Chinese folk medicine.



Research Professor Henry Lai and assistant research Professor Narendra Singh have exploited the chemical properties of a wormwood derivative to target breast cancer cells, with surprisingly effective results. A study in the latest issue of the journal Life Sciences describes how the derivative killed virtually all human breast cancer cells exposed to it within 16 hours.



“Not only does it appear to be effective, but it’s very selective,” Lai said. “It’s highly toxic to the cancer cells, but has a marginal impact on normal breast cells.”



The compound, artemisinin, isn’t new. It apparently was extracted from the plant Artemesia annua L., commonly known as wormwood, thousands of years ago by the Chinese, who used it to combat malaria. However, the treatment was lost over time. Artemisinin was rediscovered during an archaeological dig in the 1970s that unearthed recipes for ancient medical remedies, and has become widely used in modern Asia and Africa to fight the mosquito-borne disease.



The compound helps control malaria because it reacts with the high iron concentrations found in the malaria parasite. When artemisinin comes into contact with iron, a chemical reaction ensues, spawning charged atoms that chemists call “free radicals.” The free radicals attack cell membranes, breaking them apart and killing the single-cell parasite.



About seven years ago, Lai began to hypothesize that the process might work with cancer, too.



“Cancer cells need a lot of iron to replicate DNA when they divide,” Lai explained. “As a result, cancer cells have much higher iron concentrations than normal cells. When we began to understand how artemisinin worked, I started wondering if we could use that knowledge to target cancer cells.”



Lai devised a potential method and began to look for funding, obtaining a grant from the Breast Cancer Fund in San Francisco. Meanwhile, the UW patented his idea.



The thrust of the idea, according to Lai and Singh, was to pump up the cancer cells with maximum iron concentrations, then introduce artemisinin to selectively kill the cancer. To accommodate a rate of iron intake greater than normal cells, cancer cell surfaces feature greater concentrations of transferrin receptors — cellular pathways that allow iron into a cell. Breast cancer cells are no exception. They have five to 15 times more transferrin receptors on their surface than normal breast cells.



In the current study, the researchers subjected sets of breast cancer cells and normal breast cells to doses of holotransferrin (which binds with transferrin receptors to transport iron into cells), dihydroartemisinin (a more water-soluble form of artemisinin) and a combination of both compounds. Cells exposed to just one of the compounds showed no appreciable effect. Normal breast cells, exposed to both compounds, exhibited a minimal effect. But the response by cancer cells when hit with first holotransferrin, then dihydroartemisinin, was dramatic.



After eight hours, just 25 percent of the cancer cells remained. By the time 16 hours had passed, nearly all the cells were dead.



An earlier study involving leukemia cells yielded even more impressive results. Those cells were eliminated within eight hours. A possible explanation might be the level of iron in the leukemia cells.



“They have one of the highest iron concentrations among cancer cells,” Lai explained. “Leukemia cells can have more than 1,000 times the concentration of iron that normal cells have.”



The next step, according to Lai, is animal testing. Limited tests have been done in that area. In an earlier study, a dog with bone cancer so severe it couldn’t walk made a complete recovery in five days after receiving the treatment. But more rigorous testing is needed.



If the process lives up to its early promise, it could revolutionize the way some cancers are approached, Lai said. The goal would be a treatment that could be taken orally, on an outpatient basis.



“That would be very easy, and this could make that possible,” Lai said. “The cost is another plus — at $2 a dose, it’s very cheap. And, with the millions of people who have already taken artemisinin for malaria, we have a track record showing that it’s safe.”



Whatever happens, Lai said, a portion of the credit will have to go to unknown medical practitioners, long gone now.



“The fascinating thing is that this was something the Chinese used thousands of years ago,” he said. “We simply found a different application.”



###



For more information, contact Lai at (206) 543-1071 or http://www.elsevier.com/locate/lifescie







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Related StoriesAncient Chinese remedy shows potential in preventing breast cancer December 19, 2005

UW licenses potential cancer treatment derived from ancient Chinese folk remedy October 14, 2004

An ancient remedy reborn: UW licenses potential wormwood treatment for cancer

Ancient Chinese remedy proves effective against cancer cells November 29, 2001

 http://www.washington.edu/news/2001/11/26/ancient-chinese-folk-remedy-may-hold-key-to-non-toxic-cancer-treatment/



Saturday, May 24, 2014

planta para tratamiento de cancer-cancertreatment

This Little Known Chinese Herb Kills 12,000 Cancer Cells For Every Healthy Cell


March 26, 2014 by Arjun Walia. 26 Comments.

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Seleccionar idioma​▼Today, odds are that you have had/have cancer, or know somebody who does. In Canada, approximately one million Canadians that were alive at the beginning of 2009 have had a cancer diagnosis in the previous 10 years. Two out of every five Canadians will develop cancer within their life time, and one in every four will die.(3) In the United States, one out of every two men, and one out of ever three women will become infected with cancer.



These rates have continued to skyrocket since we started recording them and more people are starting to ask questions and observe the environment we choose to surround ourselves with on a daily basis.



Despite these statistics, new research is emerging everyday that puts into question the only two approved treatments for cancer, which are radiation and chemotherapy. It seems we are approaching a time where the medical community will be forced to open up to new options when it comes to cancer treatment. After all, scientists have discovered that chemotherapy fuels cancer growth and kills the patient more quickly, yet nothing has been changed, both are extremely toxic to the human body.



A little known Chinese herb might be eligible for the growing list of cancer killers via alternative methods of treatment. According to studies published in Life Sciences, Cancer Letters and Anticancer Drugs, artemesinin, a derivative of the wormwood plant commonly used in Chinese medicine, can kill off cancer cells, and do it at a rate of 12,000 cancer cells for every healthy cell. (0)



Henry Lai and his team of researchers from the University of Washington synthesized the compound, which uses a cancer cells appetite for iron to make them the target. The great thing about artemisinin is that alone it can selectively kill cancer cells while leaving normal cells unharmed.



“By itself, artemisinin is about 100 times more selective in killing cancer cells as opposed to normal cells. Artemisinin is 34,000 times more potent in killing the cancer cells as opposed to their normal cousins. So the tagging process appears to have greatly increased the potency of artemisinin’s cancer-killing properties.” - Henry Lai



Despite the compound being licensed to Holley Pharmaceuticals, it has yet to be used for cancer treatment in humans.



“We call it a Trojan horse because the cancer cell recognizes transferrin as a natural, harmless protein. So the cell picks up the compound without knowing that a bomb (artemisinin) is hidden inside.” - Henry Lai





The wormwood extract was used many centuries ago in China for healing purposes. The treatment became lost over time and has now been rediscovered thanks to an ancient manuscript containing medical remedies. It kills 12,000 cancer cells for every healthy cell, which means it could be turned into a drug with minimal side effects.



“The compound is currently being licensed by the University of Washington to Artemisia Biomedical Inc., a company that Lai, Sasaki and Narendra Singh, UW associate professor of bioengineering, founded in Newcastle, Washington for development and commercialization. Human trials are at least several years away. Artemisinin is readily available, Sasaki said, and he hopes their compound can eventually be cheaply manufactured to help cancer patients in developing countries.” (0)



The abstracts read:



“Artemisinin reacts with iron to form free radicals that kill cells. Since cancer cells uptake relatively larger amounts of iron than normal cells, they are more susceptible to the toxic effect of artemisinin. In previous research, we have shown that artemisinin is more drawn to cancer cells than to normal cells. In the present research, we covalently attached artemisinin to the iron-carying plasma glycoprotein transferrin.Transferrin is transported into the cells via receptor-mediated endocytosis and cancer cells express significantly more transferrin receptors on their cell surface and endocytose more transferrin than normal cells. Thus, we hypothesize that by tagging artemisinin to transferrin, both iron and artemisinin would be transported into cancer cells in one package. Once inside a cell, iron is released and can readily react with artemisinin close by tagged to the transferrin. This would enhance the toxicity and selectivity of artemisinin towards cancer cells. We found that holotransferrin-tagged artemisinin, when compared with artemisinin, was very potent and selective in killing cancer cells. Thus, this ‘tagged-compound’ could potentially be developed into an effective chemotherapeutic agent for cancer treatment.” (1)



Another abstract reads:



“Our results demonstrate that the artemisinin disruption of E2F1 transcription factor expression mediates the cell cycle arrest of human breast cancer cells and represents a critical transcriptional pathway by which artemisinin controls human reproductive cancer cell growth.” (2)



Artemisinin is currently FDA approved for the treatment of malaria, it’s very safe and easy to use. It’s inexpensive and works on all cancers but has yet to find it’s way into the mainstream. It’s really time to move beyond just radiation, surgery and chemotherapy for the treatment of cancer.

Monday, March 24, 2014

botellas de plastico reciclando en cajas









http://www.revistaartesanato.com.br/geral/aprenda-a-fazer-caixas-com-garrafas-pet-recicle/09

A dica de hoje é extremamente interessante. Vamos mostrar como fazer uma caixinha com garrafas pet. Além de ter um objeto exclusivo e muito útil, você ajuda a evitar que garrafas pet vão parar em rios, nas ruas, entupindo bueiros e causando problemas.
caixa garrafa pet1
1) Você vai precisar de tesoura, alicate, fita crepe, quatro garrafas PET cortadas em tiras de 2cm de largura, elásticos e um molde de 10x10x10cm
2) Corte uma tira em um comprimento que permita cobrir dois lados mais o fundo da caixa, deixando ainda 4cm de sobra em cada ponta
3) Ajuste a fita ao molde, cobrindo dois lados e o fundo. Vinque as sobras de 4cm para facilitar o trabalho
caixa garrafa pet2
4) Passe elásticos em torno do molde a fim de fixar melhor as fitas
5) Corte mais quatro fitas e ajuste-as ao molde como explicado nos passos 2 e 3
6) Corte mais cinco fitas para cobrir os dois outros lados do molde
caixa garrafa pet3
7) Quando for passar a primeira fita dessa segunda etapa, será necessário entrelaçá-la, na parte de baixo, com as fitas que já estão fixas. Para isso, basta realizar tecelagem simples, passando a fita ora por baixo, ora por cima das fitas já dispostas
8) Faça o mesmo com as demais fitas da segunda etapa. Lembre-se de que, ao fazer o entrelaçamento, onde a fita anterior passou por baixo da trama, a fita atual deve passar por cima e vice-versa. A etapa seguinte será fazer as laterais da caixa. Para isso, corte cinco fitas em comprimento suficiente para cobrir quatro lados e deixar uma sobra de cerca de 10cm.
9) Quando for entrelaçar a primeira fita, cuide para que ela fique desencontrada com a fita paralela a ela no fundo da caixa. Isto é, onde a fita do fundo passa por baixo da trama, a fita da lateral deve passar por cima e vice-versa. Começe tecendo da direita para a esquerda, parando a ponta da fita na última posição em que ela fique por cima da trama. Segure a fita nessa posição, pegue a outra extremidade e começe a tecer da esquerda para a direita, avançando para o lado seguinte.
caixa garrafa pet4
10) Entrelaçe a fita em volta de toda a caixa
11) Quando chegar a hora de arrematar, sobreponha a sobra de fita ao trecho já tramado. A extremidade da fita deve ficar por baixo da trama
12) Repita, com outras três fitas, o procedimento descrito nos passos de 9 a 11. Não utilize, por enquanto, a quinta fita
caixa garrafa pet5
13) Pegue a fita restante e corte-a no meio no sentido do comprimento
14) Passe as fitas finas pela trama normalmente, seguindo o mesmo procedimento utilizado para as demais
15) Agora é ncessário arrematar as sobras na parte de cima da caixa. Para as fitas verticais que estiverem por baixo das horizontais, dobre a sobra para fora, rente à borda da caixa
caixa garrafa pet6
16) Corte as sobras na altura da terceira fita de cima para baixo. Arremate as pontas encaixando-as nas terceira fita. Dobre as demais sobras para fora e corte-as na altura da terceira fita. Retire a caixa do molde e arremate estas últimas sobras para dentro, encaixando-as na terceira fita
17) Reforçe os vincos. Utilize o alicate para vincar bem as bordas (protegendo a peça com um pedaço de fita de PET dobrada)
18) Pronto! A caixa de fitas de PET que você acabou de confeccionar é ideal para guardar miudezas ou mesmo embalar presentes. Utilizando a técnica mostrada aqui, você pode montar caixas no tamanho que quiser.
Fontes:


Saturday, July 06, 2013

Vida en ecoaldea espiral de luz




centraL HIDROELECTRICA casera y economica

Central hidroeléctrica casera y económica

10 comentariosmanzanaPor manzana El 29 de agosto de 2011
Navegando me encontré con este curioso diseño de turbina hidráulica hecha por muy bajo costo y de forma muy sencilla. Sam Redfield es el responsable de este brillante diseño donde con un cubo de plástico de unos 20l podría servir uno de pintura por ejemplo, y unas tuberías de PVC junto con un  alternador de imanes permanentes como generador eléctrico obtiene este pequeña fuente de energía limpia.
pico hydro 4 Central hidroeléctrica casera y económica
pico hydro Central hidroeléctrica casera y económica
Turbina funcionando en Guatemala.
Al generador se le instala un regulador de voltaje, una batería de automóvil y un inversor. La batería almacena la energía, el regulador controla el voltaje e impide la sobrecarga de la batería y el inversor transforma la corriente directa en alterna. Según el inventor se puede generar 60 Watts, capaz de cargar 10 teléfonos móviles al mismo tiempo sin que se reduzca la carga de la batería.
turbina pelton de pvc Central hidroeléctrica casera y económica
La turbina construida con codos de PVC
turbina pico hidro Central hidroeléctrica casera y económica
Detalle del interior donde se ve la correcta disposición para que funcione el sistema.
No es mucha energía, no obstante, es necesario considerar que este generador al contrario que otras alternativas como la eólica o solar dispone de su fuente de poder las 24 horas del día y en general, sin interrupciones y otra posibilidad es instalar varios generadores y cargar un sistema de baterías en serie con lo que se podría ampliar la potencia.
El costo entero del sistema es de unos 350 euros, la mayor parte por el motor, se podría convertir un alternador de coche, o utilizar un dinamo o hasta construir el motor en si, claro que seguramente no se lograría la misma potencia, eso si el costo seria mucho menor.
alternador pico hydro Central hidroeléctrica casera y económica
Alternador colocado en su sitio.
Este tipo de sistemas hidroeléctricos que generan menos de 1 kW (1000 vatios) son conocidos como pico-hydro (en inglés) o pico-hidroenergía. Permiten producir energía eléctrica aprovechando pequeños riachuelos con caídas de agua como fuente energía. Algo muy bueno para las comunidades rurales que se encuentran cerca a estos riachuelos, ya que habitualmente no tienen acceso a la electricidad, de tal forma que este tipo de pico-turbinas de bajo costo ofrecen una excelente oportunidad para proveer electricidad.
turbina pico hidraulica Central hidroeléctrica casera y económica
Sam Redfield con la turbina ya montada y funcionando en Guatemala.
Para mas información y la lista completa de materiales necesarios para construir este generador hidráulico en la pagina de AIDG(Appropiate Infrastructure Development Group).
Te gusto, ayúdanos y compártelo:



Work continues. One of the issues that we face in deploying the system is cost. The Permanent Magnet Alternator that generates the electricity in the system costs more than $300.00 US and has to be imported from the States. As part of my program with AIDG in Guatemala, I investigated the possibility of rebuilding a Toyota alternator to function as a Permanent Magnet Alternator. After investigating several possibilities, I am happy to report that we now have a working prototype, which is being integrated into the system. Other improvements include integrating the voltage regulator into the device and improvements in turbine performance. In the coming months trials will continue and no doubt improvements in economy and performance will be made. My work with AIDG Guatemala was invaluable to me in understanding the energy issues people face in the developing world and provided me an excellent opportunity to develop my technology in an environment that fosters innovation in a setting where people’s lives are positively effected. Thanks AIDG!




Tech Update: Pico-hydro system developments

Sam Redfield, Project Manager of AIDG’s pico-hydro program in Guatemala was just accepted for MIT’s International Development Design Summit in Ghana this summer! Here is an account of some of his work at our new facility in Guatemala. Keep an eye out for the build manual he is producing for the Five Gallon Bucket Generator!
Sam Redfield
Hi everyone. I’m back in Xela, home of AIDG’s offices and research facility in Central America. Big things are happening down here. This January we moved into a beautiful new compound. Rising above the neighboring buildings, the new office resembles a pagoda. Its red corrugated roof flanking three stories of golden clapboard walls is something of an enigma in a neighborhood dominated by low concrete block houses. In addition to much needed additional office space, we now have a new fabrication shop, electronics and water lab and, under construction, housing to accommodate several interns and visiting researchers. The new office is full of light and the staff and interns that work here are noticeably happier with the new work space. In what can be chilly mornings in a city perched at roughly 7000 ft., it’s nice to work in a place where the brilliant morning sun comes in through the windows and warms the space.
New AIDG Compound
I have returned to Xela to continue my work on the pico-hydro system that I field tested in La Florida last year. Pico-hydro systems are small hydroelectric generators that produce less than one kilowatt of power. We are looking at using the generator to provide basic lighting, cell phone charging and ultra violet water purification in under served communities. Housed in a five gallon bucket, and employing a modified car alternator driven by a turbine, the generator promises the potential of cheap clean energy to those without access to the electricity grid.
Pico-hydro test in La Florida in 2008
Pico-hydro test in La Florida in 2008

The Permanent Magnet Alternator

Last year, we established that the generator was viable as a single point power source that could be installed quickly with limited resources and could produce consistent power with modest water usage. Still unresolved were issues of cost, longevity of service and overall performance for electrical output. The generator was built using a rather expensive modified GM alternator produced in the States for the home brew wind turbine market. This modified alternator, called a permanent magnet alternator (PMA) produces energy at low RPM’s and works well in small-scale hydroelectric systems. In addition to the price, (more that $300.00 U.S.), the alternator would have to be shipped to its destination country, adding additional cost. The PMA was by far the generator’s most expensive component and the only element in the system that would need to be imported, so we looked to it to reduce the generator’s overall cost.
My solution was to modify the Nippo Denso alternator produced for Toyota’s 22R engine. They key was using low-tech mods that could be cheaply and easily reproduced in a basic machine shop. The Nippo Denso alternator, found in most Toyota pickup trucks and many sedans in developing countries, might just be the most common alternator in the world. They are often shipped to developing countries to be rebuilt for the market in the US and other developed countries. Where in the States these alternators are simply replaced with rebuilt alternators when they fail, in developing countries there is extensive infrastructure to rebuild them. They are available in quantity in Guatemala and are cheap.
My design for the Toyota based PMA uses only the alternator casing and the stator (the wire coils that surround the rotor inside the alternator). For the conversion, the rotor is completely rebuilt with powerful neodymium magnets and the stator is rewound with thinner gage wire. Non-functioning Toyota alternators can be had for about $20.00 US in Guatemala if bought in bulk. The magnets are the only part of the new alternator that may need to be imported.
Left: rebuilt rotor with permanent magnets. Right: Toyota rotor.
Left: Rebuilt permanent magnet rotor. Right: Toyota rotor.
Toyota based permanent magnet alternator
Toyota based permanent magnet alternator

Our new hydro test bench

Last year we lacked the facilities to do extensive testing of the PMA and could only determine that, yes, it worked and that it produced energy at low RPM’s. But we couldn’t determine which gauge windings of the stator would produce the most power given the bucket generator’s RPM ranges. We needed more controlled study conditions, particularly as field tests were difficult to repeat (distance to test site, variability of water flow, etc.).
This past month, we set up both a hydro and a PMA test bench. The hydro test bench simulates the head and water flow rate that determine the output of a small hydroelectric system. By varying the head and flow in the test bench, we can simulate the various conditions under which the bucket generator operates and rate its performance under different loads.
Bucket generator connected to hydro test bench
Bucket generator connected to hydro test bench
We can’t directly measure the RPMs of the bucket generator when it is hooked up to the hydro test bench, but we can estimate this number using the PMA test bench. Simply put, we find the number of RPMs in the PMA test bench that replicates the current produced by our bucket generator in the hydro test bench, and thereby get an estimate of the bucket generator RPMs. Using the PMA test bench we can only investigate which windings offer us the highest current at the appropriate RPMs for the system.
PMA test bench
PMA test bench
Direct comparison of the GM and Toyota PMAs is difficult due to differences in configuration, size and layout of the 2 systems. That said we were able to determine that the Toyota PMA offers performance in the same general range of the GM system and at a fraction of the cost. If manufactured in bulk, the Toyota PMA would come in at around $120.00 U.S. and the entire bucket generator could cost about $160.00 U.S.
Currently, we are trying to determine which wind of the Toyota PMA will give us the maximum current at the RPM ranges of the bucket generator system. At our maximum available head on the test bench, about 90’, we were able to produce over 1,200 RPMs and 90 watts. We expect to get more than 100 watts in the field at slightly higher heads. We don’t know yet what the maximum output will be.
This spring, we’ll be installing at least two of the bucket generators in Haiti to power ultra violet water purification equipment. A portion of the funding for this project was generously provided by St Peter’s Church in Weston. AIDG’s Haiti office is partnering with local NGOs, including our good friends at SOIL, to address the lack of clean potable water in their service areas. Each ultra violet purification device draws about 30 watts. With the generator, we expect to be able to power three or more UV devices at 100’ of head and 50 gallons a minute of flow. Currently, sites surveys are being conducted in Haiti to determine head and flow conditions and find suitable sites that provide year round consistent water. These long term test sites will provide data on performance as well as service and maintenance needs of the system.
Sam Redfield
AIDG
Quetzaltenango, Guatemala
Related posts:
Sam Redfield on Pico-hydro at La Florida
Parts List for Five Gallon Bucket Hydroelectric Generator
ddress will not be published. Required fields are marked *
https://www.engineeringforchange.org/static/content/Energy/S00070/5%20Gallon%20Bucket%20Build%20Manual.pdf