Pros and Cons of the business side of Science

Read the article below (I know its long), and list one pro and one con of scientists being able to patent genes and genetic discoveries.

Supreme Court weighs whether human genes can be patented

Published April 15, 2013

Associated Press

DNA may be the building block of life, but can something taken from it also be the building block of a multimillion-dollar medical monopoly? 

The Supreme Court grapples Monday with the question of whether human genes can be patented. Its ultimate answer could reshape U.S. medical research, the fight against diseases like breast and ovarian cancer and the multi-billion dollar medical and biotechnology business. 

"The intellectual framework that comes out of the decision could have a significant impact on other patents -- for antibiotics, vaccines, hormones, stem cells and diagnostics on infectious microbes that are found in nature," Robert Cook-Deegan, director for genome ethics, law & policy at Duke University, said in a statement. 

"This could affect agricultural biotechnology, environmental biotechnology, green-tech, the use of organisms to produce alternative fuels and other applications," he said. 

The nine justices' decision will also have a profound effect on American business, with billions of dollars of investment and years of research on the line. The U.S. Patent and Trademark Office has been awarding patents on human genes for almost 30 years. 

And Myriad Genetics alone has $500 million invested in the patents being argued over in this case. Without the ability to recoup that investment, breakthrough scientific discoveries needed to combat all kind of medical maladies wouldn't happen, the company says. 

"Countless companies and investors have risked billions of dollars to research and develop scientific advances under the promise of strong patent protection," said Peter D. Meldrum, the president and CEO of Myriad Genetics, in a statement. 

But their opponents argue that allowing companies like Myriad to patent human genes or parts of human genes will slow down or cripple lifesaving medical research like in the battle against breast cancer. 

"What that means is that no other researcher or doctor can develop an additional test, therapy or conduct research on these genes," said Karuna Jagger, executive director of Breast Cancer Action. 

The Supreme Court has already said that abstract ideas, natural phenomena and laws of nature cannot be given a patent, which gives an inventor the right to prevent others from making, using or selling a novel device, process or application. 

Myriad's case involves patents on two genes linked to increased risk of breast and ovarian cancer. Myriad's BRACAnalysis test looks for mutations on the breast cancer predisposition gene, or BRCA. Those mutations are associated with much greater risks of breast and ovarian cancer. 

Women with a faulty gene have a three to seven times greater risk of developing breast cancer and a higher risk of ovarian cancer. Men can also carry a BRCA mutation, raising their risk of prostate, pancreatic and other types of cancer. 

The mutations are most common in people of eastern European Jewish descent. 

Myriad sells the only BRCA gene test. 

The American Civil Liberties Union challenged Myriad's patents, arguing that genes couldn't be patented, and in March 2010 a New York district court agreed. But the U.S. Court of Appeals for the Federal Circuit has now twice ruled that genes can be patented. In Myriad's case, it's because the isolated DNA has a "markedly different chemical structure" from DNA within the body. 

Mark C. Capone, president of Myriad Genetics Laboratories, Inc., a subsidiary of Myriad, said some of the concerns over what they have patented are overblown and some simply incorrect. 

"Myriad cannot, should not and has not patented genes as they exist in the human body on DNA," Capone said in an interview. "This case is truly about isolated DNA molecules which are synthetic chemicals created by the human ingenuity of man that have very important clinical utilities, which is why this was eligible for a patent." 

But the ACLU is arguing that isolating the DNA molecules doesn't stop them from being DNA molecules, which they say aren't patentable. 

"Under this theory, Hans Dehmelt, who won the Nobel Prize for being the first to isolate a single electron from an atom, could have patented the electron itself," said Christopher A. Hansen, the ACLU's lawyer in court papers. "A kidney removed from the body (or gold extracted from a stream) would be patentable subject matter." 

The Obama administration seems to agree. Artificially created DNA can be patented, but "isolated but otherwise unmodified genomic DNA is not patent-eligible," Solicitor General Donald Verrilli said in court papers. 

That was the ruling of the original judge who looked at Myriad's patents after they were challenged by the ACLU in 2009.  U.S. District Judge Robert Sweet said he invalidated the patents because DNA's existence in an isolated form does not alter the fundamental quality of DNA as it exists in the body or the information it encodes. But the federal appeals court reversed him in 2011, saying Myriad's genes can be patented because the isolated DNA has a "markedly different chemical structure" from DNA within the body. 

The Supreme Court threw out that decision and sent the case back to the lower courts for rehearing. This came after the 

high court unanimously threw out patents on a Prometheus Laboratories, Inc., test that could help doctors set drug doses for autoimmune diseases like Crohn's disease, saying the laws of nature are unpatentable. 

But the federal circuit upheld Myriad's patents again in August, leading to the current review. The court will rule before the end of the summer. 

"The key issue now for the court will therefore be whether the scientist working in the lab to isolate a particular gene innovated in a way that allows for that isolated gene to be patented," said Bruce Wexler, a lawyer with the law firm Paul Hastings, who advises pharmaceutical and biotech companies on patent issues. 

The case is 12-398, Association for Molecular Pathology v. Myriad Genetics, Inc.

Read more: http://www.foxnews.com/politics/2013/04/15/supreme-court-weighs-whether-human-genes-can-be-patented/print#ixzz2QYFoNXVz

3-D Printers Again, But Way Different!

Hear, Hear to the 3-D Printer!

If you liked the 3D printer than made the wrench, you'll love this.  
You must respond with to this video. 
 What impacts would you see this printer having on today's society?  
What do you think the next step of 3-D printing should be?

Would you want one?  They look like the image below.

Read and Respond!

Read and respond to the following article.  What parts of this technology concern you?  What parts do you think are beneficial?

3D printer spits out human embryonic stem cells

By

Published February 06, 2013

| LiveScience

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Imagine if you could take living cells, load them into a printer, and squirt out a 3D tissue that could develop into a kidney or a heart. Scientists are one step closer to that reality, now that they have developed the first printer for embryonic human stem cells.

In a new study, researchers from the University of Edinburgh have created a cell printer that spits out living embryonic stem cells. The printer was capable of printing uniform-size droplets of cells gently enough to keep the cells alive and maintain their ability to develop into different cell types. The new printing method could be used to make 3D human tissues for testing new drugs, grow organs, or ultimately print cells directly inside the body.

Human embryonic stem cells (hESCs) are obtained from human embryos and can develop into any cell type in an adult person, from brain tissue to muscle to bone. This attribute makes them ideal for use in regenerative medicine — repairing, replacing and regenerating damaged cells, tissues or organs. [Stem Cells: 5 Fascinating Findings]

In a lab dish, hESCs can be placed in a solution that contains the biological cues that tell the cells to develop into specific tissue types, a process called differentiation. The process starts with the cells forming what are called "embryoid bodies." 

Cell printers offer a means of producing embryoid bodies of a defined size and shape.

In the new study, the cell printer was made from a modified CNC machine (a computer-controlled machining tool) outfitted with two "bio-ink" dispensers: one containing stem cells in a nutrient-rich soup called cell medium and another containing just the medium. These embryonic stem cells were dispensed through computer-operated valves, while a microscope mounted to the printer provided a close-up view of what was being printed.

The two inks were dispensed in layers, one on top of the other to create cell droplets of varying concentration. The smallest droplets were only two nanoliters, containing roughly five cells.

The cells were printed onto a dish containing many small wells. The dish was then flipped over so the droplets now hung from them, allowing the stem cells to form clumps inside each well. (The printer lays down the cells in precisely sized droplets and in a certain pattern that is optimal for differentiation.)

Tests revealed that more than 95 percent of the cells were still alive 24 hours after being printed, suggesting they had not been killed by the printing process. More than 89 percent of the cells were still alive three days later, and also tested positive for a marker of their pluripotency — their potential to develop into different cell types.

Biomedical engineer Utkan Demirci, of Harvard University Medical School and Brigham and Women's Hospital, has done pioneering work in printing cells, and thinks the new study is taking it in an exciting direction. "This technology could be really good for high-throughput drug testing," Demirci told LiveScience. One can build mini-tissues from the bottom up, using a repeatable, reliable method, he said. Building whole organs is the long-term goal, Demirci said, though he cautioned that it "may be quite far from where we are today."

Others have created printers for other types of cells. Demirci and colleagues made one that printed embryonic stem cells from mice. Others have printed a kind of human stem cells from connective tissues, which aren't able to develop into as many cell types as embryonic stem cells. The current study is the first to print embryonic stem cells from humans, researchers report in the Feb. 5 issue of the journal Biofabrication.

Copyright 2013 LiveScience, a TechMediaNetwork company. All rights reserved. This material may not be published, broadcast, rewritten or redistributed.

Read more: http://www.foxnews.com/science/2013/02/06/3d-printed-human-embryonic-stem-cells/print#ixzz2K81nHpY5

The Possibilities of Chemistry!!

Watch the video below.  After viewing the entire video you must explain what impact this could have on a person's everyday life if they owned one.  YOU MAY NOT REPEAT WHAT ANYONE ELSE WROTE.  REPEATS WILL NOT RECIEVE CREDIT!!

 

 

 

Welcome to Chem Comm Blog

Chemistry is everywhere.  Pick two things you encounter every single day and explain how Chemistry has an impact on those things.  Be clear and specific (repeat answers will not receive credit).