Study tracks gene changes during the introduction of farming in Europe

November 23, 2015

Harvard Medical School

Genomic analysis of ancient human remains identifies specific genes that changed during and after the transition in Europe from hunting and gathering to farming about 8,500 years ago. Many of the genes are associated with height, immunity, lactose digestion, light skin pigmentation, blue eye color and celiac disease risk.



Ancient DNA can provide insight into when humans acquired the adaptations seen in our genomes today.
Credit: Image courtesy of Harvard Medical School



The introduction of agriculture into Europe about 8,500 years ago changed the way people lived right down to their DNA.

Until recently, scientists could try to understand the way humans adapted genetically to changes that occurred thousands of years ago only by looking at DNA variation in today’s populations. But our modern genomes contain mere echoes of the past that can’t be connected to specific events.

Now, an international team reports in Nature that researchers can see how natural selection happened by analyzing ancient human DNA.

“It allows us to put a time and date on selection and to directly associate selection with specific environmental changes, in this case the development of agriculture and the expansion of the first farmers into Europe,” said Iain Mathieson, a research fellow in genetics at Harvard Medical School and first author of the study.

By taking advantage of better DNA extraction techniques and amassing what is to date the largest collection of genome-wide datasets from ancient human remains, the team was able to identify specific genes that changed during and after the transition from hunting and gathering to farming.

Many of the variants occurred on or near genes that have been associated with height, the ability to digest lactose in adulthood, fatty acid metabolism, vitamin D levels, light skin pigmentation and blue eye color. Two variants appear on genes that have been linked to higher risk of celiac disease but that may have been important in adapting to an early agricultural diet.

Other variants were located on immune-associated genes, which made sense because “the Neolithic period involved an increase in population density, with people living close to one another and to domesticated animals,” said Wolfgang Haak, one of three senior authors of the study, a research fellow at the University of Adelaide and group leader in molecular anthropology at the Max Planck Institute for the Science of Human History.

“Although that finding did not come fully as a surprise,” he added, “it was great to see the selection happening in ‘real time.'”

The work also supports the idea that Europe’s first farmers came from ancient Anatolia, in what is now Turkey, and fills in more details about how ancient groups mixed and migrated.

“It’s a great mystery how present-day populations got to be the way we are today, both in terms of how our ancestors moved around and intermingled and how populations developed the adaptations that help us survive a bit better in the different environments in which we live,” said co-senior author David Reich, professor of genetics at HMS. “Now that ancient DNA is available at the genome-wide scale and in large sample sizes, we have an extraordinary new instrument for studying these questions.”

“From an archaeological perspective, it’s quite amazing,” said co-senior author Ron Pinhasi, associate professor of archaeology at University College Dublin. “The Neolithic revolution is perhaps the most important transition in human prehistory. We now have proof that people did actually go from Anatolia into Europe and brought farming with them. For more than 40 years, people thought it was impossible to answer that question.”

“Second,” he continued, “we now have evidence that genetic selection occurred along with the changes in lifestyle and demography, and that selection continued to happen following the transition.”

Prying more from the past

Members of the current team and others have used ancient DNA in the past few years to learn about Neanderthals and the genes they passed to humans, identify ancestors of present-day Europeans, trace migrations into the Americas and probe the roots of Indo-European languages. Studying natural selection, however, remained out of reach because it required more ancient genomes than were available.

“In the past year, we’ve had a super-exponential rise in the number of ancient samples we can study on a genome scale,” said Reich, who is also an associate member of the Broad Institute of Harvard and MIT and a Howard Hughes Medical Investigator. “In September 2014, we had 10 individuals. In this study, we have 230.”

The DNA came from the remains of people who lived between 3,000 and 8,500 years ago at different sites across what is now Europe, Siberia and Turkey. That time span provided snapshots of genetic variation before, during and after the agricultural revolution in Europe.

Among the 230 ancient individuals were 83 who hadn’t been sequenced before, including the first 26 to be gathered from the eastern Mediterranean, where warm conditions usually cause DNA to degrade.

Members of the team used several technological advances to obtain and analyze the new genetic material. For example, they exploited a method pioneered by Pinhasi’s laboratory to extract DNA from a remarkably rich source: a portion of the dense, pyramid-shaped petrous bone that houses the internal auditory organs. In some cases, the bone yielded 700 times more human DNA than could be obtained from other bones, including teeth.

“That changed everything,” said Pinhasi. “Higher-quality DNA meant we could analyze many more positions on the genome, perform more complex tests and simulations, and start systematically studying allele frequency across populations.”

What made the cut

Although the authors caution that sample size remains the biggest limitation of the study, comparing the ancient genomes to one another and to those of present-day people of European ancestry revealed 12 positions on the genome where natural selection related to the introduction of farming in northern latitudes appears to have happened.

“Some of those specific traits have been studied before,” said Reich. “This work with ancient DNA enriches our understanding of those traits and when they appeared.”

Besides the adaptations that appear to be related to diet, pigmentation, immunity and height, the possible selective pressure on other variants was less clear.

“We can guess by looking at the function of the gene, but our power is limited,” said Mathieson. “It’s quite frustrating.”

It’s too early to tell whether some of the variants were themselves selected for or whether they hitched a ride with a nearby beneficial gene. The question pertains especially to variants that seem to be disadvantageous, like increased disease risk.

Being able to look at numerous positions across the genome also allowed the team to examine complex traits for the first time in ancient DNA.

“We can see the evolution of height across time,” said Mathieson.

Researchers had noticed that people from southern Europe tend to be shorter than those from northern Europe. The new study suggests that the height differential arises both from people in the north having more ancestry from Eurasian steppe populations, who seem to have been taller, and people in the south having more ancestry from Neolithic and Chalcolithic groups from the Iberian peninsula, who seem to have been shorter.

The team wasn’t able to draw conclusions about the other complex traits it investigated: body mass index, waist-hip ratio, type 2 diabetes, inflammatory bowel disease and lipid levels.

Reich, for one, hopes researchers will one day have thousands of ancient genomes to analyze. He would also like to see this type of study applied to non-European populations and even to other species.

“It will be interesting to study selection in domesticated animals and to see if there is coevolution between them and the people who were domesticating them,” said Mathieson.


This study was supported by U.S. National Science Foundation HOMINID grant BCS-1032255, U.S. National Institutes of Health grant GM100233, European Research Council (ERC) starting grants ADNABIOARC (263441) and APGREID, an Irish Research Council ERC support grant, the Irish Research Council for Humanities and Social Sciences, the Australian Research Council (DP130102158), the German Research Foundation (DFG) grants KR 4015/1-1 and AL 287/14-1, the Human Frontier Science Program (LT001095/2014-L), the Russian Foundation for Basic Research (5-06-01916), the Russian Foundation for the Humanities (15-11-63008), and a state grant from the Ministry of Education and Science of the Russian Federation (#33.1195.2014/k).

About Harvard Medical School

Harvard Medical School has more than 7,500 full-time faculty working in 10 academic departments located at the School’s Boston campus or in hospital-based clinical departments at 15 Harvard-affiliated teaching hospitals and research institutes: Beth Israel Deaconess Medical Center, Boston Children’s Hospital, Brigham and Women’s Hospital, Cambridge Health Alliance, Dana-Farber Cancer Institute, Harvard Pilgrim Health Care Institute, Hebrew SeniorLife, Joslin Diabetes Center, Judge Baker Children’s Center, Mass. Eye and Ear/Schepens Eye Research Institute, Massachusetts General Hospital, McLean Hospital, Mount Auburn Hospital, Spaulding Rehabilitation Hospital and VA Boston Healthcare System.

About University College Dublin

Founded in 1854, University College Dublin is Ireland’s largest university. It has over 32,000 students from some 120 countries around the world. Almost one quarter of its 1,700 academic staff are international.

It is the leading national institution for European research funding. Perhaps the best known of all its graduates is James Joyce, the author of Ulysses, who completed his Bachelor of Arts at the university in 1902.

UCD’s vision for 2020 is built on a foundation of excellent research, delivering answers to challenges of global significance in which UCD and Ireland can play a leading role.

Story Source:

The above post is reprinted from materials provided by Harvard Medical School. Note: Materials may be edited for content and length.

Journal Reference:

  1. Iain Mathieson, Iosif Lazaridis, Nadin Rohland, Swapan Mallick, Nick Patterson, Songül Alpaslan Roodenberg, Eadaoin Harney, Kristin Stewardson, Daniel Fernandes, Mario Novak, Kendra Sirak, Cristina Gamba, Eppie R. Jones, Bastien Llamas, Stanislav Dryomov, Joseph Pickrell, Juan Luís Arsuaga, José María Bermúdez de Castro, Eudald Carbonell, Fokke Gerritsen, Aleksandr Khokhlov, Pavel Kuznetsov, Marina Lozano, Harald Meller, Oleg Mochalov, Vyacheslav Moiseyev, Manuel A. Rojo Guerra, Jacob Roodenberg, Josep Maria Vergès, Johannes Krause, Alan Cooper, Kurt W. Alt, Dorcas Brown, David Anthony, Carles Lalueza-Fox, Wolfgang Haak, Ron Pinhasi, David Reich. Genome-wide patterns of selection in 230 ancient Eurasians. Nature, 2015; DOI:10.1038/nature16152


Source: Harvard Medical School. “How the introduction of farming changed the human genome: Study tracks gene changes during the introduction of farming in Europe.” ScienceDaily. ScienceDaily, 23 November 2015. <>.

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November 20, 2015

Cell Press

Although today’s pacemakers are lifesaving electronic devices, they are limited by their artificial nature. For example, the devices require regular maintenance, must be replaced periodically, and can only approximate the natural regulation of a heartbeat. A new article highlights the promise and limitations of new methods based on stem cell and reprogramming technologies to generate biological pacemakers that might one day replace electronic pacemakers.



This graphic shows examples of individual pacemaker cells.
Credit: Courtesy of Vasanth Vedantham.



Although today’s pacemakers are lifesaving electronic devices, they are limited by their artificial nature. For example, their parts can fail or they can become infected. In addition, the devices require regular maintenance, must be replaced periodically, and can only approximate the natural regulation of a heartbeat. A Review article published on November 20 in Trends in Molecular Medicine highlights the promise and limitations of new methods based on stem cell and reprogramming technologies to generate biological pacemakers that might one day replace electronic pacemakers.

“Theoretically, biological pacemakers, which are composed of electrically active cells that can functionally integrate with the heart, could provide natural heart rhythm regulation without the need for indwelling hardware,” says author Vasanth Vedantham, of the University of California, San Francisco.

To create biological pacemakers, one approach is to coax stem cells to become specialized cardiac pacemaker cells that are normally found within the sinoatrial node of the heart. These are then transplanted into an ailing heart to restore pacemaking function. Another promising approach is to directly reprogram supporting cells, already present in the heart–for instance, fibroblasts (e.g., connective tissue)–and convert them into pacemaker cells to restore cardiac function.

Vedantham states that initial large animal studies on biological pacemakers have generated promising results but that much more work remains ahead before biological pacing can be actually considered a clinically viable therapy. For example, researchers need to better understand the mechanisms controlling the development and maintenance of pacemaker cells in the sinoatrial node, just as they must develop ways to compare experimental biological pacemaker tissue with bona fide sinoatrial node tissue. Also, scientists will need to improve the methods used to deliver cells to desired locations within the heart, as well as the recovery of specific individual cells for detailed characterization and functional analyses.

“Biological pacemakers must meet a very high standard of performance to supplant electronic pacemakers,” Vedantham says. “Because even a few seconds without a heartbeat can lead to serious consequences, a biological pacemaker would need to exhibit very robust and reliable performance. It remains to be determined whether this will be technically feasible. Despite such challenges, the field is poised for rapid progress over the next few years,” he adds.

Story Source:

The above post is reprinted from materials provided by Cell Press. Note: Materials may be edited for content and length.

Journal Reference:

  1. Vasanth Vedantham. New Approaches to Biological Pacemakers: Links to Sinoatrial Node Development. Trends in Molecular Medicine, 2015; DOI: 10.1016/j.molmed.2015.10.002


Source: Cell Press. “Can stem cell technology be harnessed to generate biological pacemakers?.” ScienceDaily. ScienceDaily, 20 November 2015. <>.

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Target e*Informed Consent (Target e*ICF™)


The Clinical Trials Transformation Initiative (CTTI) is very active supporting the modernization of the informed consent process. Part of this effort is utilizing an electronic informed consent integrated with electronic signatures. Some solutions include the use of stand-alone dedicated tablets and others are web-based. As we live in a modern world where electronic devices are somewhat ubiquitous, there is a push to BYOD (bring your own device). As a result, we created a web-based solution fully integrated with Target e*CRF®.


A global clinical trial will begin in January with 3 languages. Study participants will first be registered in Target e*CRF® by the clinical site. Subjects will then be able to read the informed consent page by page, ask questions on line, receive answers online, and then sign online once the subject confirms that all questions have been answered. Authorized user at the clinical site will then sign the electronic Informed Consent and only then can the clinical site enter data. For flexibility, the system is also designed to allow for confirmation of the signing of a paper informed consent.


Target e*ICF™ can be used as a stand-alone application or fully integrated with Target e*CRF®. The benefits are huge and introductory programs are available.


Autumn In NY – View Form the 24th Floor at Target Health’s Corporate Headquarters




Autumn in NYC © Target Health Inc. 2015


ON TARGET is the newsletter of Target Health Inc., a NYC – based, full – service, contract research organization (eCRO), providing strategic planning, regulatory affairs, clinical research, data management, biostatistics, medical writing and software services to the pharmaceutical and device industries, including the paperless clinical trial.


For more information about Target Health contact Warren Pearlson (212 – 681 – 2100 ext. 104). For additional information about software tools for paperless clinical trials, please also feel free to contact Dr. Jules T. Mitchel or Ms. Joyce Hays. The Target Health software tools are designed to partner with both CROs and Sponsors. Please visit the Target Health Website.


Joyce Hays, Founder and Editor in Chief of On Target

Jules Mitchel, Editor


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Non-Surgical Method to Reverse Cataracts – HUGE !


Photo Credit: MedPageToday, PHANIE/ALAMY


As reported last week in Science, a naturally occurring steroid has dissolved cataracts in mice, a potentially “game changing“ development in the search for a nonsurgical treatment of the eye disease, cataracts. A new study using steroid eye 1) ___ to reverse cataracts could offer an alternative to invasive surgical treatments. The steroid eye drops were shown to reverse cataracts in 2) ___.


More than half of Americans over the age of 70 have cataracts, caused by clumps of proteins collecting in the eye lens. At present, the only way to remove them is 3) ___, an unavailable or unaffordable option for many of the 20 million people worldwide who are blinded by the condition. Now, a new study in mice suggests eye drops made with a naturally occurring steroid could reverse cataracts by teasing apart the protein clumps. “This is a game changer in the treatment of cataracts,“ says Roy Quinlan, a molecular biologist at Durham University in the United Kingdom who was not part of the study. “It takes decades for the 4) ___ to get to that point, so if you can reverse that by a few drops in the eye over a couple of weeks, that’s amazing.“


The proteins that make up the human lens are among the oldest in the body, forming at about 4 weeks after fertilization. The majority are crystallins, a family of proteins that allow the eye to focus and keep the lens 5) ___. Two of the most abundant crystallins, CRYAA and CRYAB, are produced in response to stress or injury. They act as chaperones, identifying and binding to damaged and misfolded proteins in the lens, preventing them from aggregating. But over the years, as damaged proteins accumulate in the lens, these chaperones become overwhelmed. The mutated proteins then clump together, blocking light and producing the tell-tale cloudiness of cataracts.


To treat cataracts without surgery – which is out of reach for many patients in developing nations – researchers have looked to 6) ___ treatments. Although boosting the function of CRYAA and CRYAB seems to be a good target, developing a therapeutic has been challenging. Most drugs that act on disease-related proteins work by changing how the protein functions, something scientists can measure by monitoring the protein’s enzymatic activity. CRYAA, CRYAB, and similar proteins are known as “undruggable“ because their activity can’t be 7) ___, says Jason Gestwicki, a biochemist at the University of California (UC), San Francisco, and a senior author of the new study, published in Science. Gestwicki’s team decided to use a technology called differential scanning fluorimetry, which allows scientists to measure the temperature at which a target protein begins to melt. They analyzed CRYAA and CRYAB and discovered that in one type of hereditary cataract, CRYAB takes on a mutant form with a much higher melting temperature than its normal version. If they could find a molecule that would bind to the mutant CRYAB protein and lower its melting 8) ___ back to that of a healthy CRYAB, they speculated, CRYAB should function normally and prevent damaged proteins from clumping in the lens. They then turned to a bank of 2450 molecules that exhibited similar properties to CRYAA and CRYAB. They added molecules to the mutant CRYAB, looking for one that would stabilize their target. They settled on compound 29, a steroid found naturally in the bloodstream but not in the lens, which has no blood supply. To test the concept, mice with age-related and hereditary cataracts received drops in the right eye, whereas the left eye went untreated. After just a few weeks, the treated eye was visibly clearer. Cataract severity is measured on a scale of zero to four, with four being the worst case. On average, mice in the study had about a one-grade improvement in cataract severity after 4 weeks of treatment. This is the second study this year to find that eye drops made from a class of 9) ___ called sterols can successfully reverse cataracts. In July, researchers from UC San Diego reported that lanosterol, a steroid found in the human eye, reversed cataracts in dogs.


One key difference between the two studies is the way the different steroids were administered. The dog study administered the drug both by injection into the eye and eye drops. The new study used only eye drops. There’s still a lot to uncover before either study can move into clinical trials. The lens in the human eye is very different from those in mice or dogs, and neither study explains how the steroids work on cataracts. Figuring out how the treatment reverses cataracts is the team’s next task, a key step toward 10) ___ trials, which Gestwicki hopes to launch in the next year. ViewPoint Therapeutics, a biotech company he co-founded in San Francisco, California, holds the license to the technology and will launch more animal studies soon. Source:


ANSWERS: 1) drops; 2) mice; 3) surgery; 4) cataracts; 5) clear; 6) drug; 7) measured; 8) temperature; 9) steroids; 10) clinical


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The exact cause of cataracts is unknown. While the risk grows as you get older, other factors may also contribute like: diabetes, smoking, excess alcohol use, eye injury. Source: WebMD



Photo: WebMD



Cataract surgery is easy today, but dissolving a cataract with steroid drops will be the easiest of all. Source: WebMD


Editor’s note: The reading done, for this week’s History of Medicine, was so interesting, that we’ve made this section a little longer than usual, in the hopes that our readers will be fascinated, as well. Ophthalmologists are really interesting people. Enjoy the longer read:


Couching is the earliest documented form of cataract surgery. As a cataract is a clouding in the lens of the eye, couching is a technique of dislodging the lens, thus removing the opacity. Although couching is nowadays routinely practiced merely in remote areas in third world countries, it was a precursor to modern cataract surgery and pars plana vitrectomy. Cataract surgery by “couching“ (lens depression) was, without a doubt, one of the oldest surgical procedures. This technique involved using a sharp instrument to push the cloudy lens to the bottom of the eye. Perhaps this procedure is that which is mentioned in the articles of the Code of Hammurabi (ca. 1792-1750 BCE).


Maharshi Sushruta, an ancient Indian surgeon, first described the procedure in “Sushruta Samhita, Uttar Tantra“, an Indian medical treatise from 800 BCE. Since that time the procedure seems to have been wide spread throughout the world. Evidence shows that couching was widely practiced in China, Europe, and Africa. After the 19th century, with the development of modern cataract surgery (Intra ocular extraction of lens (1748), couching fell out of fashion, though it is still used in parts of Asia and Africa. Couching continues to be popular in some developing countries where modern surgery may be difficult to access or where the population may prefer to rely on traditional treatments. It is commonly practiced in Sub-Saharan Africa. In Mali it remains more popular than modern cataract surgery, despite the fact that the cost of both methods is similar, but with much poorer outcome with couching. In Burkina Faso, a majority of patients were unaware of the causes of cataracts and believed it to be due to fate. It is not performed by ophthalmologists, but rather by local healers or “witch doctors“. A sharp instrument, such as a thorn or needle, was used to pierce the eye either at the edge of the cornea or the sclera, near the limbus. The opaque lens was pushed downwards, in the eye, out of the way of vision, allowing light to enter the eye. The cataract phlegm was then blown out of the nose. The eye would later be soaked with warm clarified butter and then bandaged. Once the patients saw shapes or movement, the procedure was stopped. The patient was left without a lens (aphakic), therefore, later in history, this couching procedure included a powerful lens to compensate for the lost one.


Couching, still done in the 21st Century, is a largely unsuccessful technique with abysmal outcomes. A minority of patients may regain the ability to sense light and some movement, but over 70% are left totally blind. A Nigerian study showed other complications include secondary glaucoma, hyphaema, and optic atrophy. Couching does not compare favorably to modern cataract surgery.


Here is translation from the original Sanskrit written around 800 BCE:


“vv.55-56: Now procedure of surgical operation of slai?mika lidganasa (cataract) will be described. It should be taken up (for treatment) if the diseased portion in the pupillary region is not shaped like half-moon, sweat drop or pearl: not fixed, uneven and thin in the center, streaked or variegated and is not found painful or reddish.“

“vv. 57-61ab: In moderate season, after unction and sudation, the patient should be positioned and held firmly while gazing at his nose steadily. Now the wise surgeon leaving two parts of white circle from the black one towards the outer canthus should open his eyes properly free from vascular network and then with a barley-tipped rod-like instrument held firmly in hand with middle, index and thumb fingers should puncture the natural hole-like point with effort and confidence not below, above or in sides. The left eye should be punctured with right hand and vice-versa. When punctured properly a drop of fluid comes out and also there is some typical sound.“

“vv. 61bc-64ab: Just after puncturing, the expert should irrigate the eye with breast-milk and foment it from outside with vata-[wind-]alleviating tender leaves, irrespective of dosa [defect] being stable or mobile, holding the instrument properly in position. Then the pupillary circle should be scraped with the tip of the instrument while the patient, closing the nostril of the side opposite to the punctured eye, should blow so that kapha [phlegm] located in the region be eliminated.“

“vv. 64cd-67: When pupillary region becomes clear like cloudless sun and is painless, it should be considered as scraped properly.

(If do?a [defect] can’t be eliminated or it reappears, puncturing is repeated after unction and sudation.)

When the sights are seen properly the salaka [probe] should be removed slowly, eye anointed with ghee (similar to butter) and bandaged. Then the patient should lie down in supine position in a peaceful chamber.

He should avoid belching, coughing, sneezing, spitting and shaking during the operation and thereafter should observe the restrictions, as after intake of sneha [oil].“

“v.68: Eye should be washed with vata-[wind-]alleviating decoctions after every three days and to eliminate fear of (aggravation of ) vayu [wind], it should also be fomented as mentioned before (from outside and mildly).“

“v.69: After observing restrictions for ten days in this way, post-operative measures to normalize vision should be employed along with light diet in proper quantity.“

The removal of cataract by surgery was also introduced into China from India, and flourished in the Sui (AD 581-618) and Tang dynasties (CE 618-907). The first references to cataract and its treatment in the West are found in 29 CE in De Medicinae, the work of the Latin philosopher and encyclopedist Aulus Cornelius Celsus, which also describes a couching operation.


Artifacts show, that the lens of the human eye can also be removed by suction through a hollow instrument. Bronze oral suction instruments have been unearthed that seem to have been used for this method of cataract extraction during the 2nd century CE. Such a procedure was described by the 10th-century Persian physician Muhammad ibn Zakariya al-Razi, who attributed it to Antyllus, a 2nd-century Greek physician. The procedure “required a large incision in the eye, a hollow needle, and an assistant with an extraordinary lung capacity.“ This suction procedure was also described by the Iraqi ophthalmologist Ammar ibn Ali of Mosul, in his Choice of Eye Diseases, also written in the 10th century. He presented case histories of its use, claiming to have had success with it on a number of patients.


Extracting the lens has the benefit of removing the possibility of the lens migrating back into the field of vision. A later variant of the cataract needle in 14th-century Egypt, reported by the oculist Al-Shadhili, used a screw to produce suction.


Couching continued to be used throughout the Middle Ages and is still used in some parts of Africa and in Yemen. However, couching is an ineffective and dangerous method of cataract therapy, and often results in patients remaining blind or with only partially restored vision. For the most part, it has now been replaced by extracapsular cataract surgery and, especially, phacoemulsification. In 1748, Jacques Daviel was the first modern European physician to successfully extract cataracts from the eye. Jacques Daviel (11 August 1696 – 30 September 1762) was a French ophthalmologist credited with originating the first significant advance in cataract surgery since couching was invented. Daviel performed the first extracapsular cataract extraction on April 8, 1747. Daviel earned his medical degree from the Medical School of Rouen, practiced in Marseille where he was affiliated with the medical school there, then restricted his practice to ophthalmology in 1728. He was on the staff of Hospital d’Invalides and became oculist to Louis XV. In March 1756 he was elected a Fellow of the Royal Society. In 1759, He was elected a foreign member of the Royal Swedish Academy of Sciences. Daviel died of apoplexy in 1762 while on a trip to Geneva, Switzerland.


In the 1940s Harold Ridley introduced the concept of implantation of the intraocular lens which permitted more efficient and comfortable visual rehabilitation possible after cataract surgery. The implantation of a foldable intraocular lens is the procedure considered the state-of-the-art. Sir Nicholas Harold Lloyd Ridley (10 July 1906 – 25 May 2001) was an English ophthalmologist who invented the intraocular lens and pioneered intraocular lens surgery for cataract patients. Nicholas Harold Lloyd Ridley was the son of Nicholas Charles Ridley and his wife Margaret, n?e Parker; he had a younger brother, Olden. Harold had a stammer which he largely managed to cure. As a child he met and sat on the lap of Florence Nightingale, a close friend of his mother. He was educated at Charterhouse School before studying at Pembroke College, Cambridge from 1924-1927, and completed his medical training in 1930 at St Thomas’ Hospital. Subsequently he worked as a surgeon at both St Thomas’ Hospital and Moorfields Eye Hospital in London, specializing in ophthalmology. In 1938 Ridley was appointed full surgeon and consultant at Moorfields Hospital and later appointed consultant surgeon in 1946. During World War II, Ridley saw Royal Air Force casualties with eye injuries and noticed that when splinters of acrylic plastic from aircraft cockpit canopies became lodged in the eyes of wounded pilots, they did not trigger rejection as glass splinters did, leading him to propose the use of artificial lenses in the eye to correct cases of cataracts. He had a lens manufactured using the same material – brand name Perspex made by ICI – and on 29 November 1949 at St Thomas’ Hospital, Harold Ridley achieved the first implant of an intraocular lens, although it was not until 8 February 1950 that he left an artificial lens permanently in place in an eye. The first lens was manufactured by the Rayner Company of Brighton & Hove, East Sussex, a company which continues to manufacture and market modern, small-incision intraocular lenses today. The first IOL implant in the United States was performed in 1952, a Ridley-Rayner lens implanted at the Wills Eye Hospital in Philadelphia. Ridley pioneered this treatment in the face of prolonged strong opposition from the medical community. He worked hard to overcome complications, and had refined his technique by the late 1960s. With his pupil Peter Choyce he eventually achieved worldwide support for the technique. The intraocular lens was finally approved as “safe and effective“ and approved for use in the US by the Food and Drug Administration in 1981. The first US Food and Drug Administration (FDA) approved lenses, (Choyce Mark VIII and Choyce Mark IX Anterior Chamber lenses) were manufactured by Rayner. Cataract extraction surgery with intraocular lens implantation is now the most common type of eye surgery. Ridley retired from NHS hospital service in 1971. In the 1990s he underwent successful bilateral intraocular lens implantation at St Thomas’s Hospital by surgeon Mr. Michael Falcon. Thus Harold Ridley benefitted from his own invention and the operational procedure he had pioneered but what was most pleasing to him was that he had it done in the same hospital where he performed the first operation. Sir Harold Ridley resided in Stapleford near Salisbury, Wiltshire until his death on 25 May 2001.



The Medical Maverick, “Grandfather of Small Incision Surgeries“ Charlie Kelman MD (1930-2004)




In 1967, American ophthalmologist, and a pioneer in cataract surgery, Charles D. Kelman, (1930-2004) introduced phacoemulsification, a technique that uses ultrasonic waves to emulsify the nucleus of the crystalline lens in order to remove the cataracts without a large incision. This new method of surgery decreased the need for an extended hospital stay and made the surgery ambulatory. Patients who undergo cataract surgery hardly complain of pain or even discomfort during the procedure. However patients who have topical anesthesia, rather than peribulbar block anesthesia, may experience some discomfort.


According to surveys of members of the American Society of Cataract and Refractive Surgery, approximately 2.85 million cataract procedures were performed in the United States during 2004 and 2.79 million in 2005, using Kelman’s procedure.


Kelman was born in Brooklyn, New York, on May 23, 1930, to Eva and David Kelman. After graduating from Forest Hills High School and Tufts University, he completed medical studies at the University of Geneva, Switzerland, an internship at Kings County Hospital, Brooklyn, and residency in ophthalmology at the Wills Eye Hospital, Philadelphia. He started a private practice in New York City in 1960. In 1962, Dr. Kelman devised the cryoprobe, a freezing instrument for the extraction of cataracts within their capsules. This became the most widely used method for cataract removal in the world until about 1978, when it was supplanted by extracapsular cataract extraction with irrigation and aspiration, also introduced by Dr. Kelman and still the technique used by a majority of cataract surgeons today. In 1963, Dr. Kelman pioneered the use of freezing for the repair of retinal detachments. Retinal cryopexy remains a frequent adjunct in retinal surgery to this day. Kelman phacoemulsification, introduced in 1967, reduced recovery from cataract surgery from a 10-day hospital stay to today’s outpatient cataract surgery, allowing the patient immediate return to activity. The procedure employs a small ultrasonic tip whose vibrations break up the mass of the cataractous lens within its capsule and suction it out through a small needle. An estimated 100 million such procedures have been performed worldwide. In 1975, Dr. Kelman began designing lens implants for use in conjunction with cataract surgery. Numerous companies including Allergan Medical Optics, IOLAB, Alcon Surgical, Domilens, and Storz Ophthalmics sought his services. Dr. Kelman became the world’s most successful intraocular lens designer. Neurosurgeons have adapted the Kelman phacoemulsification machine for use in the dissection of tumors from the delicate brain and spinal cord tissue in children. In this way, the device has saved hundreds of young lives. Phacoemulsification was the stimulus for small incision surgery.


Later in life, Kelman worked on several projects, including artificial blood vessels, artificial corneas, and a magnetic cataract extraction procedure which retains the patient’s normal ability to focus on near and distant objects. Other applications of the magnetic technique can be used to remove plaque from arteries and growths from the digestive tract, prostate, bladder, and other areas without invasive surgery.


Clinical Professor of Ophthalmology at New York Medical College, Dr. Kelman held the position of attending surgeon at the New York Eye and Ear Infirmary and Manhattan Eye, Ear and Throat Hospital. He was also a consultant surgeon at many hospitals throughout the world, and he received some of the highest honors in science and technological innovation. A past president of the American Society of Cataract and Refractive Surgeons, Dr. Kelman has written hundreds of articles, papers, and scientific books, as well as a lay book on cataracts and an autobiography entitled Through My Eyes.


Known as Charlie to his friends, Dr. Kelman found time to learn to pilot his own helicopter and avidly followed his hobbies of golf, music, and performing. He entertained on The Tonight Show, The David Letterman Show, The Oprah Winfrey Show, and numerous others. Charlie appeared in concert with Lionel Hampton and Dizzy Gillespie, and performed in concert at Carnegie Hall, Las Vegas, and Atlantic City with Regis Philbin, and others. Columbia Records also released an instrumental recording of “Moonlight Serenade“ in which all the reed parts were played by Charlie.


Dr. Kelman continued to teach his surgical techniques to doctors around the world, while devoting his spare time to writing lyrics and music for several musicals, “The Marrano“ and most passionately, “The Right Pair of Shoes“, until his death in 2004 from lung cancer. Posthumously, Dr. Kelman was honored with the Lasker Award, the nation’s highest award for medical science, among other accolades. Undoubtedly, Dr. Kelman’s impact is as unique as his personality and practices. Charlie Kelman’s phacoemulsification surgery has proven to be the rare technology with longevity – it is still the most common method used worldwide for the procedure. The program cites unheard of statistics for a 30-year-old innovation: nearly 100% of the almost 3 million cataract surgeries performed each year in the United States are done with phacoemulsification, and nearly 10 million each year worldwide. The procedure saves millions in healthcare costs both in the way the procedure is done and by the outcome of preventing blindness, thus allowing people to continue to contribute to society. Kelman spawned an empire that thrives to this day. Additionally, as his colleague Dr. Jack Dodick, chairman, department of ophthalmology, New York University Langone Medical Center and attending in ophthalmology at the Manhattan Eye, Ear, and Throat Institute, notes in the program, “When Charlie was first able to remove an unwanted tissue inside the human body through a small hole, he basically became the grandfather of all small incision surgery in the whole body.“


Dr. Kelman received some of the highest honors in science and technological innovation including the National Medal of Technology and Innovation (formerly known as the National Medal of Technology), the highest honor for technological achievement bestowed by the President of the United States on America’s leading innovators; and the American Academy of Ophthalmology’s prestigious Laureate Award, awarded six months before he died of cancer. Posthumously, Kelman was honored with the Lasker Award, the nation’s highest award for medical science, among other accolades. In 2013, a biographical profile of Dr. Kelman was included in a bestselling book called Saving Sight: An eye surgeon’s look at life behind the mask and the heroes who changed the way we see, by Andrew Lam (author), M.D. Dr. Kelman’s accomplishments and his gift for showmanship brought him unusual fame for an ophthalmologist, including many television appearances. But success was not immediate. In his memoir, ”Through My Eyes: The Story of a Surgeon Who Dared to Take On the Medical World” (Crown, 1985), Dr. Kelman described a low point in his research when, having spent $250,000 in grant money, he failed to find a solution. Among other approaches, he had tried small drills on lab animals; while they removed the cataract, they also destroyed the eye.


Then he went to a dentist have his teeth cleaned. ”I sat in his chair, as he reached over, took a long silver instrument out of its cradle and turned it on,” Dr. Kelman wrote. ”A fine mist came off the tip but the tip didn’t seem to be moving. He applied the tip to my teeth, and I felt an exquisite vibration and heard a high-pitched sound.” Dr. Kelman asked, ”What is that thing?” An ultrasonic probe, came the reply. ”I knew this was the moment,” Dr. Kelman wrote. In 1967, the phacoemulsification procedure was introduced. Instead of making a large incision in the eye and removing the lens, doctors could make a tiny one. Then they inserted an ultrasonic tip which, vibrating thousands of times a second, broke up the cataracts without damaging the surrounding tissue. The remains of the cataract were suctioned out. The procedure, which Dr. Kelman taught to thousands of doctors around the world, is now performed more than a million times a year in the United States alone. Artificial lenses that he developed in the 1970’s are now routinely implanted in patients’ eyes, making unnecessary the ultra-thick glasses that once were common after surgery. And his ultrasonic approach has been adopted in other fields of medicine, including neurosurgery. ”It was not evolutionary, it was revolutionary,” said Dr. Elliot Finkelstein, a past president of the American Academy of Ophthalmology. The discovery brought recognition to a man who had long wanted it, if not necessarily by this path.


Kelman dreamed of being a musician when he was a child, and, in fact, became a well-regarded amateur jazz saxophonist and clarinetist. He also did an occasional stand-up routine in nightclubs and helped produce several Broadway shows. The combination of his medical achievements, performing skills and robust self-confidence made him a natural for television. Dr. Kelman made numerous appearances with hosts like Johnny Carson, Merv Griffin, Barbara Walters, Oprah Winfrey and David Letterman. He also played with jazz stars like Lionel Hampton and Dizzy Gillespie, some of whom, like Hampton, were his patients. He rented Carnegie Hall to give a performance. And in his 40’s, he learned to fly a helicopter, landing it on the roof of a hospital in Long Island where he was working. Some of the more conservative members of his field were put off by the flamboyance of the man who sometimes referred to himself as ”the world’s No. 1 ophthalmologist.” Even his supporters agreed that bashfulness was not in his nature. ”Charlie was the ultimate extrovert,” Dr. Finkelstein said. ”But he was a guy who really produced.”


Even before adapting ultrasound for cataract surgery, Dr. Kelman devised a groundbreaking cataract-removal technique that became widely used. It involved an instrument called a cryoprobe, which he invented in 1962 and which made it easier to remove the lens and cataracts by freezing them first — a technique still used in retina surgery.


In a 1992 interview, Dr. Kelman recalled that when he was 17, his father asked him to take his saxophone to the basement. After the young man played a Jimmy Dorsey tune, his father asked if he had played it as well as Dorsey could. Charlie conceded that he had not. Mr. Kelman replied, ”You’ll be a doctor.” From the day his high school principal told him he wasn’t college material and ought to go to trade school, Charles Kelman upset conventional wisdom-with stunning success. Kelman was a pioneering ophthalmologist who bucked the medical establishment in his search for a less risky, less intrusive and more effective method of cataract removal. Thanks to his persistence and intelligence, millions of people can see again.


When he died, a Memorial Tribute to Charles D. Kelman, M.D. was held on September 13, 2004 at the St. James Theatre on Broadway and was a celebration of Dr. Kelman’s life. This very special Tribute was hosted by Dr. Frank Field and featured colleagues, family and friends, as well as video presentations and photo montages of Dr. Kelman as surgeon, performer, helicopter pilot and more. Broadway entertainers performed many of the songs that Dr. Kelman wrote.


Sources: The New York Times; Wikipedia;


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NIH Will No Longer Support Biomedical Research on Chimpanzees


The following is From Francis S. Collins, M.D., Ph.D., Director, National Institutes of Health


Research with non-human primates has and continues to be vital to helping us understand and improve human health in a multitude of ways, including the development of treatments and interventions. However, use of non-human primates needs to be supported by the science. It has been two and half years sinceNIH announced its decision  in June 2013 to significantly reduce the use of chimpanzees in agency-supported biomedical research and retain only a small population of chimpanzees for future biomedical research. As part of this decision, NIH indicated it would identify 50 chimpanzees that would be retained based on the characteristics necessary to support the research of the projects submitted, and periodically review this decision based on scientific needs. To be considered, projects would have to meet a strict set of principles and criteria, set forth by the Institute of Medicine and accepted by the NIH, after having cleared scientific review. Since June 2013, based on recommendations from the Council of Councils, NIH has phased out all previously active biomedical research protocols using chimpanzees that did not meet the IOM principles and criteria, and no new biomedical research projects have been approved.


Another major development occurred last summer. On June 16, 2015, the U.S. Fish and Wildlife Service announced that it has designated captive chimpanzees as endangered. Among other things, this designation requires that researchers apply for and obtain a permit to use captive chimpanzees in research if it could harm the animal. Up to this point, we are not aware of any permits that have been sought for this purpose. As a result of these numerous changes over the last few years and the significantly reduced demand for chimpanzees in NIH-supported biomedical research, it is clear that we’ve reached a tipping point. In accordance with NIH’s commitment in June 2013, I have reassessed the need to maintain chimpanzees for biomedical research and decided that effective immediately, NIH will no longer maintain a colony of 50 chimpanzees for future research. All NIH-owned chimpanzees that reside outside of the Federal Sanctuary System operated by Chimp Haven, Keithville, Louisiana, are now eligible for retirement. Relocation of the chimpanzees to the Federal Sanctuary System will be conducted as space is available and on a timescale that will allow for optimal transition of each individual chimpanzee with careful consideration of their welfare, including their health and social grouping.


These decisions are specific to chimpanzees. Research with other non-human primates will continue to be valued, supported, and conducted by the NIH.


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Batten Disease May Benefit From Gene Therapy


Target health is very active in 2 lysosomal storage disease programs. One is in Gaucher disease and the other is in Fabray disease. The Gaucher disease drug product was developed by Protalix Biotherapeutics (Israel) and is marketed by Pfizer.


Batten disease is a rare and fatal lysosomal storage disorder, a group of diseases that causes problems with a cell’s ability to breakdown specific molecules. Early symptoms may include vision loss, subtle changes in personality and behavior, slow learning, clumsiness, or stumbling. Eventually, the children become blind, bedridden and demented, and typically die within the first decade of their lives. Currently there are no effective treatments.


According to a study published online in Science Translational Medicine, (11 November 2015), it was shown that a new way to deliver replacement genes may be effective at slowing the development of childhood Batten disease. The key may be to inject viruses that carry the codes for the gene products into the ventricles, which are fluid-filled compartments in the center of the brain that serve as a plumbing system.


The study focused on the late infantile form of the disease that starts in children 2 to 4 years of age and is most often caused by mutations in the gene for the soluble lysosomal enzyme tripeptidyl peptidase 1 (TPP1), an enzyme which degrades proteins. The authors showed that if they treated dogs that have a similar disorder by injecting a safe virus containing the TPP1 gene code into the cerebrospinal fluid that fills ventricles, the dogs lived about twice as long as untreated dogs. Symptoms including problems with movement, pupil dilation and making decisions were delayed or, in some cases, did not occur. The treatment, however, did not fully improve the dogs’ vision suggesting that delivery to the eye itself may be necessary as well. When the authors inspected the dogs’ brains, they found that the treatment reduced the damage normally caused by the disease. In comparison with untreated dogs, the treated dogs had less reactive glial cells and stored lipofuscins, fatty deposits that are hallmarks of Batten disease and similar disorders, called neuronal ceroid lipofuscinoses.


Further inspections of the dogs’ brains confirmed the hypothesis about how the therapy worked. The results suggested that parenchymal cells that line the ventricles and surface of the brain took up the injected genes from the cerebrospinal fluid and made more TPP1 protein. These cells then secreted the protein that, in turn, spread throughout the brain. Initial experiments showed the importance treating the dogs with the immunosuppressant, mycophenolate mofetil, before injecting the TPP1 gene. The immunosuppressant prevented the production of antibodies that accelerated TPP1 clearance from the cerebrospinal fluid.


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FDA Approves Easy-to-Use Nasal Spray to Treat Opioid Overdose


Opioids are a class of drugs that include prescription medications such as oxycodone, hydrocodone, and morphine, as well as the illegal drug heroin. Drug overdose deaths, driven largely by prescription drug overdoses, are now the leading cause of injury death in the United States – surpassing motor vehicle crashes. In 2013, the Centers for Disease Control and Prevention reported the number of drug overdose deaths had steadily increased for more than a decade. When someone overdoses on an opioid, it can be difficult to awaken the person, and breathing may become shallow or stop – leading to death if there is no medical intervention. If naloxone is administered quickly, it can counter the overdose effects, usually within two minutes.


The FDA has approved Narcan nasal spray, the first FDA-approved nasal spray version of naloxone hydrochloride, a life-saving medication that can stop or reverse the effects of an opioid overdose. Until this approval, naloxone was only approved in injectable forms, most commonly delivered by syringe or auto-injector. Many first responders and primary caregivers, however, feel a nasal spray formulation of naloxone is easier to deliver, and eliminates the risk of a contaminated needle stick. As a result, there has been widespread use of unapproved naloxone kits that combine an injectable formulation of naloxone with an atomizer that can deliver naloxone nasally. Now, people have access to an FDA-approved product for which the drug and its delivery device have met the FDA’s high standards for safety, efficacy and quality.


Narcan nasal spray does not require assembly and delivers a consistent, measured dose when used as directed. This prescription product can be used on adults or children and is easily administered by anyone, even those without medical training. The drug is sprayed into one nostril while the patient is lying on his or her back, and can be repeated if necessary. However, it is important to note that it is not a substitute for immediate medical care, and the person administering Narcan nasal spray should seek further immediate medical attention on the patient’s behalf.


The FDA granted fast-track designation and priority review for Narcan nasal spray. Fast track is a process designed to facilitate development and expedite review of drugs intended to treat serious conditions and that demonstrate the potential to address an unmet medical need. The agency’s priority review program provides for an expedited review of drugs that offer a significant improvement in the safety or effectiveness of the treatment, prevention, or diagnosis of a serious condition. Narcan nasal spray was approved in less than four months, significantly ahead of the product’s prescription drug user fee goal date of January 20, 2016.


In clinical trials conducted to support the approval of Narcan nasal spray, administering the drug in one nostril delivered approximately the same levels or higher of naloxone as a single dose of an FDA-approved naloxone intramuscular injection, and achieved these levels in approximately the same time frame.


The National Institute on Drug Abuse played a critical role in the development of Narcan nasal spray as well, forming a public-private partnership by designing and conducting the clinical trials required to determine that the intranasal formulation delivered naloxone as quickly and as effectively as an injection. NIDA then worked with its private sector partners to obtain FDA approval. Increasing access to and the use of naloxone is part of the targeted strategy that Health and Human Services Secretary Sylvia M. Burwell put forward in March to address the opioid epidemic and save lives. In July, addiction and advocacy groups called for expanded availability of naloxone during an FDA-sponsored public workshop exploring the uptake and use of the drug.


The use of Narcan nasal spray in patients who are opioid dependent may result in severe opioid withdrawal characterized by body aches, diarrhea, increased heart rate (tachycardia), fever, runny nose, sneezing, goose bumps (piloerection), sweating, yawning, nausea or vomiting, nervousness, restlessness or irritability, shivering or trembling, abdominal cramps, weakness, and increased blood pressure.


Narcan nasal spray is distributed by Adapt Pharma, Inc., of Radnor, Pennsylvania.


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Thanksgiving Sweet Potato Rounds with Sticky Pecan Topping


This is a de-lish dish and easy to make. Jules loves these sweet potato-pecan rounds and gives them a top score (1 to 5) of 5+++++. He can’t stop eating them. Just one or two of these, per person, lights up the whole table. They are perfect for any holiday. ©Joyce Hays, Target Health Inc.




6 Tablespoons unsalted butter (important, no salt)

1 cup packed dark brown sugar (not light brown)

3/4 cup golden syrup (this is NOT corn syrup, got it on Amazon)

1 tiny pinch sea salt, and no more (optional)

2 cups pecan halves

1 teaspoon apple cider vinegar

2 Tablespoons bourbon

2 teaspoons vanilla extract

3 large eggs




Just a few ingredients, for a successful Thanksgiving or holiday dish. ©Joyce Hays, Target Health Inc.




Preheat oven to 350 degrees.


Toast the pecans first, on an oiled baking sheet (or pan), then set aside. This will only take a few minutes. You can toast them when you bake the sweet potatoes. After toasting the pecans, chop them a little . . . not a lot. You want to have recognizable pieces of these nuts.




Toasting the pecans, on the stove or in the oven. ©Joyce Hays, Target Health Inc.



After toasting, chop the pecans, but not too much. ©Joyce Hays, Target Health Inc.



Bake the sweet potatoes. ©Joyce Hays, Target Health Inc.



Bake the sweet potatoes, in 350 degree, pre-heated oven for 20 to 30 minutes. Use foil to cut the baking time a little. Each oven is different, so test the potatoes after baking for 20 minutes. Put back, if needed, etc.


Next, with skins on, cut them into rounds about 1 to 1.5 inches thick. Into a bowl, scoop out a small amount of potato from the top of each round. Be careful, not to damage the skins. You need the intact skins to hold everything together. Put each round onto a well-oiled baking dish and set aside. Save the scooped out potato, to be used a little later.


In a medium saucepan, combine butter, brown sugar, golden syrup and very tiny pinch of salt (or no salt). Bring to a simmer over medium heat and cook for 2 minutes, stirring, the whole time. Remove from heat and stir in pecans, (that have been toasted), cider vinegar, vanilla and bourbon. After 2 minutes, with a spatula, scrape all of this mixture out of the hot pan and into a bowl and set the mixture aside to cool for about 10 minutes.


Here, over a medium flame, the butter, brown sugar, syrup, pinch salt, are being stirred. ©Joyce Hays, Target Health Inc.



Flame is off and chopped pecans were added. Next, vanilla, cider vinegar and bourbon will be added and mixture moved, to cool down. After cooling, eggs will be added. ©Joyce Hays, Target Health Inc.



When the mixture has cooled down, into the bowl, whisk the eggs in, but one at a time. Stir to combine all the ingredients well. Add the scooped out potato to this mixture and stir it in.


Onto each potato round, add a heaping spoonful of mixture. Don’t worry if some of the mixture drips down, it will taste even better.


Bake these potato rounds, for about 40 minutes, until the topping gets crispy and crunchy and serve nice and warm. Let the potatoes cool down just a bit and then serve.




Here the sweet potato rounds are going into the oven. The kitchen smells so good! ©Joyce Hays, Target Health Inc.



Just coming out of the oven. See how the brown sugar has caramelized a little. Oh-h the aroma! ©Joyce Hays, Target Health Inc.



There will be nothing left-over, of these warm and crunchy pecan/potato rounds. ©Joyce Hays, Target Health Inc.


For people coming to the Big Apple for Thanksgiving, and looking for interesting theater, there is plenty of it.


This past weekend, we saw one of the world’s worst plays, “Night is a Room,“ and encourage you to avoid it.


Of the theater we’ve seen recently, what stands out is, “Fool For Love“ by Sam Shepard. If you like theater of the absurd, Shepard’s work represents for me, the latest in a long continuum, beginning with Albert Camus, Samuel Beckett, Harold Pinter, David Mamet and Sam Shepard.


The term, Theater of the Absurd, is derived from an essay by the French philosopher Albert Camus, who defined the human situation as meaningless and absurd, where human existence is out of step with the rest of the universe. This existential philosophy/thinking was strongly influenced by the horrors of the Second World War, which highlighted the precariousness of human life and its fundamental meaninglessness and arbitrariness. WW2 cruelty and uncertainty was followed by the trauma of living after1945 under threat of nuclear annihilation, referred to as “the cold war.“ Is it any wonder that in a world so filled with barbarism, (including the banality of evil) the arts would mirror back, theater of the absurd, and pop art?


As I wrote, a few weeks ago, Fool For Love, is superbly acted and directed, with excellent sets, sound and lighting design. It has now been hailed by the critics and has been extended for a few more weeks.




A toast for a Happy Thanksgiving to all of our friends and colleagues!


From Our Table to Yours!


Bon Appetit!


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November 19, 2015

University of Queensland

A new form of secret light communication used by marine animals has been discovered by scientists. The findings may have applications in satellite remote sensing, biomedical imaging, cancer detection, and computer data storage.



This image shows a mantis shrimp in a defensive position, on its back with its legs, head and heavily armored tail closed over. The red color indicates areas of reflected circular polarizing light.
Credit: Credit Yakir Gagnon/QBI



Researchers from the Queensland Brain Institute at The University of Queensland have uncovered a new form of secret light communication used by marine animals.

The findings may have applications in satellite remote sensing, biomedical imaging, cancer detection, and computer data storage.

Dr Yakir Gagnon, Professor Justin Marshall and colleagues previously showed that mantis shrimp (Gonodactylaceus falcatus) can reflect and detect circular polarising light, an ability extremely rare in nature. Until now, no-one has known what they use it for.

The new study shows the shrimp use circular polarisation as a means to covertly advertise their presence to aggressive competitors.

“In birds, colour is what we’re familiar with; in the ocean, reef fish display with colour. This is a form of communication we understand. What we’re now discovering is there’s a completely new language of communication,” said Professor Marshall.

Linear polarised light is seen only in one plane, whereas circular polarised light travels in a spiral — clockwise or anti-clockwise — direction.

The team determined that mantis shrimp display circular polarised patterns on the body, particularly on the legs, head and heavily armoured tail; these are the regions most visible when when they curl up during conflict.

“These shrimp live in holes in the reef,” said Professor Marshall. “They like to hide away; they’re secretive and don’t like to be in the open.”

Researchers dropped a mantis shrimp into a tank with two burrows to hide in: one reflecting unpolarised light and the other, circular polarised light. The shrimp chose the unpolarised burrow 68% of the time — suggesting the circular polarised burrow was perceived as being occupied by another mantis shrimp.

“If you essentially label holes with circular polarising light, by shining circular polarising light out of them, shrimps won’t go near it,” said Professor Marshall. “They know — or they think they know — there’s another shrimp there.

The findings may help doctors to better detect cancer. “Cancerous cells do not reflect polarised light, in particular circular polarising light, in the same way as healthy cells,” said Professor Marshall. So cameras equipped with circular polarising sensors may detect cancel cells long before the human eye can see them.

Another study involving Professor Marshall, published in the same edition ofCurrent Biology, showed that linear polarised light is used as a form of communication by fiddler crabs.

Fiddler crabs (Uca stenodactylus) live on mudflats, a very reflective environment, and they behave differently depending on the amount of polarisation reflected by objects, the researchers found.

“It appears that fiddler crabs have evolved inbuilt sunglasses, in the same way as we use polarising sunglasses to reduce glare,” Professor Marshall said.

The crabs were able to detect and identify ground-base objects base on how much polarised light was reflected. They either moved forward in a mating stance, or retreated back into their holes, at varying speeds.

“These animals are dealing in a currency of polarisation that is completely invisible to humans,” Professor Marshall said. “It’s all part of this new story on the language of polarisation.”

Both studies will be published in the print edition of Current Biology in December 2015.

Story Source:

The above post is reprinted from materials provided by University of Queensland. Note: Materials may be edited for content and length.

Journal References:

  1. Yakir Luc Gagnon, Rachel Marie Templin, Martin John How, N. Justin Marshall. Circularly Polarized Light as a Communication Signal in Mantis Shrimps. Current Biology, 2015; DOI: 10.1016/j.cub.2015.10.047
  2. Martin J. How, John H. Christy, Shelby E. Temple, Jan M. Hemmi, N. Justin Marshall, Nicholas W. Roberts. Target Detection Is Enhanced by Polarization Vision in a Fiddler Crab. Current Biology, 2015; DOI:10.1016/j.cub.2015.09.073


Source: University of Queensland. “Marine animals use new form of secret light communication.” ScienceDaily. ScienceDaily, 19 November 2015. <>.

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