Courage Marine Ascending Triangle Chart Pattern

Ascending triangle is bullish chart pattern used in technical analysis that is easily recognizable by the distinct shape created by two trendlines. In an ascending triangle, one trendline is drawn horizontally at a level that has historically prevented the price from heading higher, while the second trendline connects a series of increasing troughs. Traders enter into long positions when the price of the asset breaks above the top resistance. Horizontal resistance is 40.5 to 41 cents resistance band. Need to clear 41 cents resistance to proceed to next resistance at 44.5 cents. Immediate support is the internal uptrend dashed red line. Main ascending triangle uptrend support is the red bold line. Key support to monitor is the 200 days EMA support line.

Stem cell Treatments

Medical researchers believe that stem cell therapy has the potential to dramatically change the treatment of human disease. A number of adult stem cell therapies already exist, particularly bone marrow transplants that are used to treat leukemia.^[25] In the future, medical researchers anticipate being able to use technologies derived from stem cell research to treat a wider variety of diseases including cancer, Parkinson's disease, spinal cord injuries, and muscle damage, amongst a number of other impairments and conditions.^[26][27] However, there still exists a great deal of social and scientific uncertainty surrounding stem cell research, which could possibly be overcome through public debate and future research, and further education of the public.

Stem cells, however, are already used extensively in research, and some scientists do not see cell therapy as the first goal of the research, but see the investigation of stem cells as a goal worthy in itself

http://en.wikipedia.org/wiki/Stem_cell

Scientists uncover the potential to control adult stem cells

Research being presented today (10 April) at the UK National Stem Cell Network Annual Science Meeting in Edinburgh represents a step towards the use of Adult Stem Cells (ASCs) to repair damaged tissue. Speaking at the conference in Edinburgh, Professor Cay Kielty of the University of Manchester describes how she and her team have uncovered a messaging system that instructs ASCs to contribute to tissue repair in response to chemical signals in the body. This work, funded by the Medical Research Council, holds great hope for the development of techniques by which ASCs could be instructed to repair damaged tissues.

ASCs have potential for therapeutic use and avoid many of the ethical issues associated with embryonic stem cells. However, at present it is necessary to gain a better understanding of how, from first principles, ASCs can be controlled based on signalling systems that normally give instructions within the body. There is the potential in the future to apply such understanding to the generation of cells for transplant.

Professor Kielty’s team study stem cells that are found in human bone marrow called mesenchymal stem cells (MSCs). MSCs have the ability to relocate and develop into several different types of cells and tissue and are very promising as a source of cells for transplant in tissue repair. As well as offering the potential for bespoke treatments derived from a person’s own cells, MSCs are unlikely to trigger a severe immune response, and may be suitable for “off-the-shelf” treatments for tissue repair. This research focuses on the details of a messaging system that leads to the development of blood vessels from MSCs in the body. This system is called ‘PDGF receptor signalling’.

In PDGF receptor signalling, receptors on the surface of the MSCs receive messages in the form of molecules that are involved in directing human growth and development – ‘growth factors’. It has been found that there is a complex messaging system that relays and coordinates the signals from certain growth factors to the MSCs, which encourage their recruitment to new blood vessels. This involves cooperation between two types of receptor called ‘PDGF receptor’ and ‘neuropilin-1’ that respond to growth factors called PDGF and VEGF-A arriving at the cell surface, as well as sensing close proximity to other cells that make up the blood vessel.

As well as offering insights into the use of ASCs for tissue repair therapies, a better knowledge of how blood vessels develop is crucial to understanding and treating a huge range of diseases such as cancer, diabetic retinopathy and cardiovascular disease.

Professor Kielty said: “What we have shown is that adult stem cells respond in particular ways to some of the chemical signals in the body. The next stage will be to understand how this messaging system regulates relocation of the MSCs and instructs them to become blood vessel cells. After that, we can look at applying our understanding to develop stem-cell derived therapies for tissue repair.”

http://www.eurekalert.org/pub_releases/2008-04/babs-sut040808.php

Where are adult stem cells found and what do they normally do?

adult stem cells have been identified in many organs and tissues. One important point to understand about adult stem cells is that there are a very small number of stem cells in each tissue. Stem cells are thought to reside in a specific area of each tissue where they may remain quiescent (non-dividing) for many years until they are activated by disease or tissue injury. The adult tissues reported to contain stem cells include brain, bone marrow, peripheral blood, blood vessels, skeletal muscle, skin and liver.

Scientists in many laboratories are trying to find ways to grow adult stem cells in cell culture and manipulate them to generate specific cell types so they can be used to treat injury or disease. Some examples of potential treatments include replacing the dopamine-producing cells in the brains of Parkinson's patients, developing insulin-producing cells for type I diabetes and repairing damaged heart muscle following a heart attack with cardiac muscle cells.

http://stemcells.nih.gov/info/basics/basics4.asp