Global & Disaster Medicine

Archive for July, 2017

M 7.7 – 199km ESE of Nikol’skoye, Russia

ShakeMap Intensity image


The effects of ORT in this sequence of photos of a dehydrated Egyptian child

Beginning of ORT sequence. Image courtesy of Norbert Hirschhorn

Second step in ORT sequence. Image courtesy of Norbert Hirschhorn

Third step in ORT sequence. Image courtesy of Norbert Hirschhorn

Fourth step in ORT sequence. Image courtesy of Norbert Hirschhorn

Final step in ORT sequence

“……You can see the effects of ORT in this sequence of photos below of a dehydrated Egyptian child treated entirely with ORT. These pictures, taken by me, were made into large posters for use by NGOs in Goma.”

Sincerely,

Norbert Hirschhorn, MD
London

 

 

NIH

Oral Rehydration Therapy: A Top Medical Advance of the 20th Century

History of Oral Rehydration Therapy (ORT)

A man being treated for cholera.

Credit: CDC
A man being treated for cholera.

Without treatment, the diarrhea caused by cholera infection can quickly lead to severe dehydration and death. The fluid loss is so rapid that half of those who will die of the disease succumb within 12 hours of developing symptoms. In the 1800s, many physicians believed that cholera destroyed the intestine and that medical intervention was futile. At the time, physicians had little knowledge of microbiology and human physiology, and since the disease was so aggressive, early efforts to rehydrate patients were not successful. There was some experimentation with intravenous (IV) methods to treat the most severely ill patients, but the chemical solutions that were administered tended to be non-sterile and dangerously unbalanced. Oral rehydration treatment was also confounded by immediate reflexive vomiting.

Finding the Right IV Formulation

Progress was slow, but after many years of fine-tuning IV formulations for cholera patients, this method began to reduce mortality. By 1965, improved understanding of physiology and the administration of sterile, well-balanced IV fluids prevented death in almost every case.

However, there were a number of practical limitations to IV administration in cholera-endemic areas such as Bangladesh and India. During seasonal epidemics, for example, hospitals had to admit hundreds of patients each day. The logistical challenges left many patients untreated at home or by the roadside on their way to treatment facilities. With each patient requiring up to 40 liters of sterile IV fluid, supplies quickly ran out.

Exploring Oral Fluid Administration

In the 1960s, a number of physicians began to explore oral fluid administration as a supplemental treatment for cholera patients once IV fluid rehydration had blunted the reflexive vomiting. Pioneering the field was retired Navy Captain Dr. Robert A. Phillips, the third director of the NIAID-funded Cholera Research Laboratory that later became the International Centre for Diarrhoeal Disease Research, Bangladesh (link is external) (ICDDR,B). Dr. Phillips, a pathophysiologist with many years’ experience in cholera research and treatment, had helped to refine IV rehydration methods, but like many physicians, was attracted to the theoretical simplicity and ease of oral rehydration—if it could be accomplished.

The main challenge with oral rehydration was that fluids were not absorbed, and any ingested liquids simply added to the volume of diarrhea. But Dr. Phillips had an idea. Guessing that the strength of the oral fluids was inadequate, he tried adding glucose to the fluids. He immediately noticed that patients drinking glucose-supplemented electrolytes passed less diarrhea, indicating that fluid was being absorbed. Dr. Phillips cautiously reported the phenomenon, and in so doing opened the door to one of the 20th century’s most important medical advances.

Soon afterward, research teams in what are now Dhaka, Bangladesh, and Kolkata, India, conducted careful clinical trials and established that oral rehydration fluids with balanced salts and glucose did indeed result in decreased diarrhea, rapid rehydration and surprisingly quick recovery.

The first clinical trials of what would become known as Oral Rehydration Therapy (ORT) took place in 1968. Patients who were given an oral solution containing glucose and electrolytes were found to need 79 percent less IV rehydration for full recovery than those who did not receive the oral solution. A follow-up study found that patients with mild and moderate cholera cases could be treated with ORT alone. Not only did most patients recover quickly, but the treatment was inexpensive and could be administered by family members in the home, and by other untrained individuals, increasing its effectiveness in emergency and low-resource situations.

Separate studies supported by NIAID showed that administration of the antibiotic tetracycline reduced the need for rehydration fluids by 60 percent. Pathophysiological studies revealed that in contrast to the understanding of earlier years, the cholera pathogen did not destroy the intestine, but used a toxin to alter the transport of solutes across the intestinal membrane. Oral rehydration with the correct fluids sped up recovery by compensating for the activity of the toxin.

ORT Saves Lives Today

ORT remains the current treatment of choice due to its safety, effectiveness, low cost, simple preparation, and easy administration. According to the World Health Organization, up to 80 percent of cholera patients can be successfully treated by ORT alone, the remaining severe cases requiring preliminary IV rehydration before transitioning to ORT. ORT is estimated to save over one million lives per year, and was described in the British Medical Journal’s “Medical Milestones” series as one of the most significant medical advances of the 20th century.

NIAID Research and Future Challenges

Emerging cholera pathogens present a challenge to the power of rehydration therapy and antimicrobials. For example, antimicrobial resistance can affect the ability of the cheap and widely available antibiotic tetracycline to reduce the duration and intensity of disease. In addition, novel cholera pathogens are emerging that possess a particularly active version of the cholera toxin. These strains result in a higher proportion of severe cases that must be immediately rescued with aggressive IV rehydration before receiving ORT. Finally, modern cholera strains are powerfully competitive in the environment, replacing endemic strains and occupying the natural waters upon which hundreds of millions of people depend.

Recent research has shown that these aggressive cholera strains have spread across Asia and Africa, and have recently appeared in Haiti. Cholera remains a fierce pathogen that ruthlessly exploits poverty, inequity, natural and man-made disaster, and poor access to health care. NIAID sponsors a robust research program to understand cholera evolution, develop new therapeutics and vaccines, and collaborate with international partners to continue the fight against this ancient and modern disease.

References

Carpenter CCJ, Sack RB, Mitra PP, Mondal A. Tetracycline therapy in cholera (link is external)Journal of the Indian Medical Association. 43:309-312 (1964).

Chatterjee HN. Reduction of cholera mortality by the control of bowel symptoms and other complications. (link is external) Postgraduate Medical Journal. 33(380):278-284 (1957).

Chin CS, Sorenson J, Harris JB, Robins WP, Charles RC, Jean-Charles RR, Bullard J, Webster DR, Kasarskis A, Peluso P, Paxinos EE, Yamaichi Y, Calderwood SB, Mekalanos JJ, Schadt E, Waldor MK. The origin of the Haitian cholera outbreak strain (link is external)New England Journal of Medicine. 364(1):33-42 (2011).

Fontaine O, Garner P, Bhan MK. Oral rehydration therapy: The simple solution for saving lives. (link is external) British Medical Journal. 334(supp1):s14 (2007).

Nalin DR, Cash RA, Islam R, Molla M, Phillips RA. Oral maintenance therapy for cholera in adults. (link is external) Lancet. 2(7564):370-373 (1968).

Nalin DR, Cash RA, Rahman M. Oral (or nasogastric) maintenance therapy for cholera patients in all age-groups. (link is external) Bulletin of the World Health Organization. 43(3):361-363 (1970).

Phillips RA. Water and electrolyte losses in cholera (link is external)Federation Proceedings. 23:705-712 (1964).

Savarino SJ. A legacy in 20th century medicine: Robert Allan Phillips and the taming of cholera (link is external)Clinical Infectious Diseases. 35(6):713-720 (2002).

Ruxin JN. Magic bullet: The history of oral rehydration therapy. (link is external) Medical History. 38(4):363-397 (1994).

World Health Organization. Fact Sheet No. 107: Cholera (link is external) (2010).


Yemen: Worst cholera outbreak in the world

ReliefWeb

• 332,658 suspected cholera cases and over 1,759 cholera deaths reported between 27 April and 13 July.

• Two million people more need assistance, bringing the number of people in need to 20.7 million from 18.8 million in January.

  • Children under 15 account for 40% of suspected cases and 1/4 of the deaths

 


The microgravity conditions of the International Space Station (ISS) may hold the key to improving our understanding of how to combat sarin and VX.

NIH

Monday, July 17, 2017

Space station project seeks to crystalize the means to counteract nerve poisons

NIH-supported experiment could lead to improved antidotes.

The microgravity conditions of the International Space Station (ISS) may hold the key to improving our understanding of how to combat toxic nerve agents such as sarin and VX. That is the hope of Countermeasures Against Chemical Threats (CounterACT) project that is part of an initiative at the National Institutes of Health aimed at developing improved antidotes for chemical agents.

“With increasing worldwide concern about the use of chemical weapons, there is significant interest in developing better counteragents,” said David A. Jett, Ph.D., director of the CounterACT program, National Institute of Neurological Disorders and Stroke (NINDS), a part of NIH.

Organophosphates (OPs), a family of chemicals that includes several pesticides as well as sarin and VX nerve agents, block the activity of the enzyme acetylcholinesterase (AChE). This enzyme is critical for allowing muscles to relax after they have been stimulated by the nervous system. When the activity of AChE is blocked (for example, by OPs), muscles cannot relax, leading to paralysis and eventually death.

Developing antidotes to this type of poisoning requires detailed knowledge about the structure of the AChE enzyme. Until now, the forces of gravity on Earth have posed a challenge to this area of research. That’s where traveling into space comes in.

In June of this year, samples of the human AChE enzyme were sent to the International Space Station U.S. Laboratory by a team of CounterACT scientists led by Andrey Kovalevsky, Ph.D., Oak Ridge National Laboratory in Oak Ridge, Tennessee, and Zoran Radić, Ph.D., University of California, San Diego. Using these samples, astronauts are currently growing large crystals of pure enzyme of a size that cannot be formed on Earth due to interference from gravity.

“By taking advantage of the microgravity conditions of the International Space Station, we hope to grow better, more uniform crystals that we are unable to grow on Earth,” said Dr. Kovalevsky.

Once the crystals are grown to a large enough size, they will be returned to Earth and analyzed by a sophisticated imaging method called neutron diffraction that can provide an atomic-level view of the enzyme.

“Using this technique, we will be able to get a closer look at how the enzyme interacts with pesticides and nerve agents and learn about how the bond between the two can be chemically reversed,” said Dr. Radić. “This method would not work on the smaller enzyme crystals that can be grown here.”

Antidotes to OP exposure reactivate AChE by directly breaking its chemical bond with the OP. However, the speed at which the countermeasures available today are able to do this is too slow to be fully effective. This project will help researchers to develop antidotes that break the AChE-OP bond more quickly and that can also be delivered orally, which is another key to dealing with large-scale exposure to nerve poisons.

“Developing better countermeasures against these sorts of nerve agents is a major thrust of our overall program,” said Dr. Jett. “This project is the kind of cutting-edge science we envisioned when we established the CounterACT program.”

This project is made possible through a partnership with NASA’s Center for the Advancement of Science in Space and is part of a larger UCSD-led CounterACT-funded effort that, in addition to Drs. Kovalevsky and Radić, also includes biophysicist Donald Blumenthal, PhD., University of Utah, Salt Lake City. Their goal is to use advanced biophysical techniques to overcome limitations in defining the atomic structure of AChE and develop more effective antidotes against OP-induced inhibition.

The CounterACT program is a trans-NIH effort that is led by the NINDS in close partnership with multiple NIH institutes including the National Institute of Allergy and Infectious Diseases, which provides oversight of the program, National Institute of Environmental Health Sciences, National Institute of Arthritis and Musculoskeletal and Skin Diseases, National Eye Institute, and other NIH Institutes and Centers.

This project is funded in part by the NIH Office of the Director through the NIH CounterACT program and managed by NINDS (NS083451).

The NINDS is the nation’s leading funder of research on the brain and nervous system. The mission of NINDS is to seek fundamental knowledge about the brain and nervous system and to use that knowledge to reduce the burden of neurological disease.

The NIH CounterACT Program supports research to understand fundamental mechanisms of toxicity caused by chemical threat agents and the application of this knowledge to develop promising therapeutics for reducing mortality and morbidity caused by these agents.

About the National Institutes of Health (NIH): NIH, the nation’s medical research agency, includes 27 Institutes and Centers and is a component of the U.S. Department of Health and Human Services. NIH is the primary federal agency conducting and supporting basic, clinical, and translational medical research, and is investigating the causes, treatments, and cures for both common and rare diseases. For more information about NIH and its programs, visit www.nih.gov.

NIH…Turning Discovery Into Health®

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Central Great Lakes sector loop

Northeast sector loop

National Weather Outlook


Grilling safely: CDC

 

Get Ready to Grill Safely

important to keep meat, fish and poultry separated from other food in the grocery cart and shopping bags.keep meat, poultry, and seafood refrigerated until ready to grill wash hands with soap before and after handling raw meat, poultry, and seafood. Also, wash work surfaces, utensils, and the grill before and after cooking. Cook to correct temperature 145 for beef, pork, lamb, veal, fish. 160 F for hamburgers and other ground meat. 165 F for poultry throw out marinades and sauces that have touches raw meat juices, and put cooked meat on a clean plate.

Food poisoning peaks in the summer months when warmer temperatures cause foodborne germs to flourish. Follow these steps for a safe and enjoyable grilling season.

Separate

When shopping, pick up meat, poultry, and seafood last, right before checkout. Separate them from other food in your shopping cart and grocery bags. To guard against cross-contamination, put packages of raw meat and poultry into individual plastic bags.

Chill

Keep meat, poultry, and seafood refrigerated until ready to grill. When transporting, keep below 40°F in an insulated cooler.

Clean

Wash your hands with soap before and after handling raw meat, poultry, and seafood. Wash work surfaces, utensils, and the grill before and after cooking.

Check your grill and tools

Use a moist cloth or paper towel to clean the grill surface before cooking. If you use a wire bristle brush, thoroughly inspect the grill’s surface before cooking. Wire bristles from grill cleaning brushes may dislodge and stick into food on the grill.

Don’t cross-contaminate

Throw out marinades and sauces that have touched raw meat juices, which can spread germs to cooked foods. Use clean utensils and a clean plate to remove cooked meat from the grill.

Cook

Use a food thermometer to ensure meat is cooked hot enough to kill harmful germs. When smoking, keep temperatures inside the smoker at 225°F to 300°F to keep meat a safe temperature while it cooks.

  • 145°F – whole cuts of beef, pork, lamb, and veal (stand-time of 3 minutes at this temperature)
  • 145°F – fish
  • 160°F – hamburgers and other ground beef
  • 165°F – all poultry and pre-cooked meats, like hot dogs

Smoking:

After Grilling:

  • 140°F or warmer – until it’s served

Refrigerate

Divide leftovers into small portions and place in covered, shallow containers. Put in freezer or fridge within two hours of cooking (one hour if above 90°F outside).

Learn More:

 


WHO: To combat cholera in South Sudan

WHO

10 July 2017

Cholera contributes substantially to the disease burden in South Sudan, where outbreaks have been confirmed every year since 2014. Thus, cholera is endemic in South Sudan and requires an integrated and comprehensive approach that entails surveillance, patient care, optimal access to safe drinking water, sanitation, and hygiene (WASH); social mobilization and complementary use of oral cholera vaccines.

During the week ending 2 July 2017, a total of 304 new cholera cases and 0 deaths (Case Fatality Rate –CFR 0%) were reported across South Sudan. As of 2 July 2017, the cumulative total number of cases since the start of the current outbreak on 18 June 2016 is 17, 242 cases and 320 deaths (CFR 1.8%). The counties with active cholera transmission include Tonj East, Juba, Lankien, Pieri, Panyijar, Yirol East, Yirol West, Kapoeta East, Kapoeta South, and Kapoeta North. Suspect cholera cases are being investigated in Torit and Terekeka.

The integrated and comprehensive approach is core to the current cholera response in South Sudan. The cholera response strategy in South Sudan includes; case management, improving access to safe drinking water and sanitation; health promotion, risk communication, and community engagement; surveillance; patient care; and complementary use of oral cholera vaccines.

As a result, cholera transmission in Bor, Mingkaman, Duk, Ayod, Bentiu, Leer, Aburoc, Malakal Town, and several other areas has been controlled. The National cholera taskforce chaired by the Ministry of Health and co-chaired by WHO is leading the current response through its coordination, surveillance, case management, WASH, and social mobilization working groups.

Coordination

Overall coordination of the cholera response at the national level is coordinated by the National cholera taskforce.

At the sub-national level, cholera taskforce committees are coordinating the cholera response in locations with active transmission including Yirol East and Yirol West, Bor, Duk, Tonj East, Kapoeta South, Kapoeta North, and Kapoeta East. Other non-affected states have also initiated cholera preparedness meetings in Aweil, Torit, Wau, Yambio, and Rumbek.

Health cluster support in coordination with the humanitarian partners responding to cholera outbreak and donors to fund cholera response in different locations.

Case Management

At least 50 cholera treatment facilities including cholera treatment centers and units; and oral rehydration points are currently operational in the areas with active cholera transmission. The cholera case management working group is coordinating patient care activities that are driven by the need to ensure timely access to rehydration at household level and at designated cholera treatment facilities. Ministry of Health-led and WHO supported rapid response teams have been deployed to support the cholera response in Kapoeta, Tonj, Jonglei, Eastern Lakes, and Northern Upper Nile states. The teams are evaluating transmission dynamics among the nomadic migratory communities in Kapoeta and devising appropriate epidemiological structures to break the chain and pattern of cholera transmission in this group. WHO, UNICEF, and health cluster partners have delivered cholera kits for patient care in areas with active transmission.

Water, Sanitation and Hygiene (WASH)

The WASH response is led by the WASH cluster and its partners and with interventions delivered as part of the integrated comprehensive approach in affected and at-risk areas. Point of use water treatment using PuR and water treatment tablets, hygiene promotion, distribution of other WASH NFIs, and repair of hand pumps are core to the current emergency WASH response in affected and high-risk areas. WHO is enhancing WASH capacities in cholera treatment facilities through training, deployment of public health officers, and water quality surveillance in affected and at-risk areas. Arrangements have been finalized for an intercountry planning meeting between South Sudan, Uganda, and Kenya to mitigate the risk of cross-border cholera spread.

Surveillance

With support from WHO, the Ministry of Health has rolled out electronic and mobile reporting of cholera alerts as well as cholera case based line listing in all affected locations. This has enhanced the transmission and accuracy, analysis, and dissemination of cholera situation reports to inform the response. Rapid response teams have been activated and supported with cholera investigation kits to facilitate timely verification and investigation of suspect cholera cases. Out of the 624 cholera samples tested by the National Public Health Laboratory, 247 (39.6%) have been confirmed by culture since 18 June 2016.

Social Mobilization

Partners have supported the Ministry of Health to intensify Social mobilization in the affected communities through community social mobilizers, and use of educational materials. WHO in collaboration with UNICEF and MOH has reactivated Cholera hotline (1144) Vivacell Telecom hotline to respond to calls, inquiries, alerts and as well as provide education on cholera prevention and control.

Oral cholera vaccination

As part of the ongoing cholera response, cholera vaccines have been deployed in Leer, Bor PoC, Malakal Town, Bentiu PoC, Mingkaman IDP settlement, Aburoc IDPs, Bentiu/Rubkona Town, Ayod (Pagil, Tar, Jiech, Karmun, Padek, and Kandak), and Juba (Don Bosco IDPs). Out of the 544 140 doses secured by WHO in 2017, a total of 384 971 doses have been deployed. There are no cholera cases reported from any of the sites where the oral cholera vaccines have been deployed in 2017.

An additional two million doses of oral cholera vaccines are required to mitigate the risk of cholera in high risk areas and to interrupt transmission in the areas with ongoing transmission. WHO is in the final stages of securing these additional doses to complement the ongoing cholera response.

WHO’s contribution to the cholera response

WHO provides overall technical guidance to MOH and health partners towards the cholera response. We also support to surveillance and cholera investigation as well as case management by deployment of Rapid Response Teams (RRTs), Clinicians, and support to WASH in Cholera Treatment Centers (CTCs) and monitoring standards of care.

WHO and partners conducting an assessment at Don Bosco Gumbo Oral Rehydration Point
WHO and partners conducting an assessment at Don Bosco Gumbo Oral Rehydration Point

WHO: Some 3 in 10 people worldwide, or 2.1 billion, lack access to safe, readily available water at home, and 6 in 10, or 4.5 billion, lack safely managed sanitation

WHO

Global-water-sanitation-graphic_2017

2.1 billion people lack safe drinking water at home, more than twice as many lack safe sanitation
News release
12 July 2017 | GENEVA | NEW YORK – Some 3 in 10 people worldwide, or 2.1 billion, lack access to safe, readily available water at home, and 6 in 10, or 4.5 billion, lack safely managed sanitation, according to a new report by WHO and UNICEF.

The Joint Monitoring Programme (JMP) report, Progress on drinking water, sanitation and hygiene: 2017 update and Sustainable Development Goal baselines, presents the first global assessment of “safely managed” drinking water and sanitation services. The overriding conclusion is that too many people still lack access, particularly in rural areas.

“Safe water, sanitation and hygiene at home should not be a privilege of only those who are rich or live in urban centres,” says Dr Tedros Adhanom Ghebreyesus, WHO Director-General. “These are some of the most basic requirements for human health, and all countries have a responsibility to ensure that everyone can access them.”

Billions of people have gained access to basic drinking water and sanitation services since 2000, but these services do not necessarily provide safe water and sanitation. Many homes, healthcare facilities and schools also still lack soap and water for handwashing. This puts the health of all people – but especially young children – at risk for diseases, such as diarrhoea.

As a result, every year, 361 000 children under 5 years of age die due to diarrhoea. Poor sanitation and contaminated water are also linked to transmission of diseases such as cholera, dysentery, hepatitis A, and typhoid.

“Safe water, effective sanitation and hygiene are critical to the health of every child and every community – and thus are essential to building stronger, healthier, and more equitable societies,” said UNICEF Executive Director Anthony Lake. “As we improve these services in the most disadvantaged communities and for the most disadvantaged children today, we give them a fairer chance at a better tomorrow.”

Significant inequalities persist
In order to decrease global inequalities, the new Sustainable Development Goals (SDGs) call for ending open defecation and achieving universal access to basic services by 2030.

Of the 2.1 billion people who do not have safely managed water, 844 million do not have even a basic drinking water service. This includes 263 million people who have to spend over 30 minutes per trip collecting water from sources outside the home, and 159 million who still drink untreated water from surface water sources, such as streams or lakes.

In 90 countries, progress towards basic sanitation is too slow, meaning they will not reach universal coverage by 2030.

Of the 4.5 billion people who do not have safely managed sanitation, 2.3 billion still do not have basic sanitation services. This includes 600 million people who share a toilet or latrine with other households, and 892 million people – mostly in rural areas – who defecate in the open. Due to population growth, open defecation is increasing in sub-Saharan Africa and Oceania.

Good hygiene is one of the simplest and most effective ways to prevent the spread of disease. For the first time, the SDGs are monitoring the percentage of people who have facilities to wash their hands at home with soap and water. According to the new report, access to water and soap for handwashing varies immensely in the 70 countries with available data, from 15 per cent of the population in sub-Saharan Africa to 76 per cent in western Asia and northern Africa.

Additional key findings from the report include:

Many countries lack data on the quality of water and sanitation services. The report includes estimates for 96 countries on safely managed drinking water and 84 countries on safely managed sanitation.
In countries experiencing conflict or unrest, children are 4 times less likely to use basic water services, and 2 times less likely to use basic sanitation services than children in other countries.
There are big gaps in service between urban and rural areas. Two out of three people with safely managed drinking water and three out of five people with safely managed sanitation services live in urban areas. Of the 161 million people using untreated surface water (from lakes, rivers or irrigation channels), 150 million live in rural areas.
Note to editors
Safely managed drinking water and sanitation services means drinking water free of contamination that is available at home when needed, and toilets whereby excreta are treated and disposed of safely.

Basic services mean having a protected drinking water source that takes less than thirty minutes to collect water from, using an improved toilet or latrine that does not have to be shared with other households, and having handwashing facilities with soap and water in the home.

Sustainable Development Goal 6 is to ensure availability and sustainable management of water and sanitation for all. The JMP monitors progress on the following two targets:

Target 6.1: By 2030, achieve universal and equitable access to safe water and sanitation for all.
Target 6.2 By 2030, achieve access to adequate and equitable sanitation and hygiene for all and end open defecation, paying special attention to the needs of women and girls and those in vulnerable situations.
The JMP also contributes to monitoring of SDG 1 “to end poverty in all its forms everywhere”, and “to SDG 4 to ensure inclusive and equitable quality education and promote lifelong learning opportunities for all” by contributing data on basic water, sanitation and hygiene for the following targets:

Target 1.4: By 2030, ensure that all men and women, in particular the poor and the vulnerable, have equal rights to economic resources, as well as access to basic services.
Target 4.a: Build and upgrade education facilities that are child, disability and gender sensitive and provide safe, non-violent, inclusive and effective learning environments for all.
Safe water, sanitation and hygiene are also essential to SDG 3 “Ensuring healthy lives and promote wellbeing for all at all ages”. Under SDG target 3.9, countries are working to substantially reduce the number of deaths and illnesses from hazardous chemicals and air, water and soil pollution and contamination by 2030. Additionally, safe water, sanitation and hygiene are needed to reduce maternal mortality and to end preventable deaths of newborns and children as called for in SDG targets 3.1 and 3.2.

UNICEF media package
About the Joint Monitoring Programme
The WHO/UNICEF Joint Monitoring Programme (JMP) for Water Supply, Sanitation and Hygiene is the official United Nations mechanism tasked with monitoring country, regional and global progress, and especially towards the targets of the Sustainable Development Goals relating to universal and equitable access to drinking water, sanitation and hygiene. Thanks to the globally supported household surveys, JMP analysis helps draw connections between use of basic water and sanitation facilities and quality of life, and serves as an authoritative reference to make policy decisions and resource allocations, especially at the international level.

For more information, please contact:
Geneva
Nada Osseiran
World Health Organization
Tel: +41 22 791 4475
Mobile: +41 79 445 1624
Email: osseirann@who.int

Kim Chriscaden
World Health Organization
Tel: +41 22 791 2885
Mobile: +41 79 603 1891
Email: chriscadenk@who.int

New York
Yemi Lufadeju
UNICEF
Tel: +1 212 326 7029
Mobile: +1 917-213-4034
Email: glufadeju@unicef.org

Christopher Tidey
UNICEF
Mobile: +1 917 340 3017
Email: ctidey@unicef.org


NASA: Sometime between July 10 and July 12, an iceberg about the size of Delaware split off from Antarctica’s Larsen C ice shelf.

Antarctic Ice Shelf Sheds Massive Iceberg

Sometime between July 10 and July 12, an iceberg about the size of Delaware split off from Antarctica’s Larsen C ice shelf. Now that nearly 5,800 square kilometers (2,200 square miles) of ice has broken away, the Larsen C shelf area has shrunk by approximately 10 percent.

Scientists have been tracking the stability of this ice shelf for several years. The Moderate Resolution Imaging Spectroradiometer (MODIS) on NASA’s Aqua satellite captured an image (above) of the new iceberg on July 12, 2017. The false-color view uses MODIS band 31, which measures infrared signals known as “brightness temperature.” This measurement is useful for distinguishing the relative warmth or coolness of a landscape. Dark blue depicts where the surface is the warmest—most notably between the new iceberg and the ice shelf, but also in areas of open ocean or where water is topped by thin sea ice. Lighter blue colors show intact or thicker ice (cooler surfaces).

acquired July 12, 2017 download large image (462 KB, JPEG, 1076×1004)
acquired July 12, 2017 download GeoTIFF file (1 MB, TIFF, 1076×1004)

The calving event was confirmed by the Visible Infrared Imaging Radiometer Suite (VIIRS) on the Suomi NPP satellite. The day-night band (DNB) of VIIRS captured this image on July 12, 2017.

The final rupture was first reported by Project MIDAS, an Antarctic research project based in the United Kingdom. Adrian Luckman of Swansea University and MIDAS explains the significance of the calving event in a post here.

Larsen C, a floating platform of glacial ice on the east side of the Antarctic Peninsula, is the fourth-largest ice shelf on the coast of Antarctica. In 2014, a crack that had been slowly growing in the ice shelf for decades suddenly turned northward and accelerated, creating today’s iceberg.

“The interesting thing is what happens next…how the remaining ice shelf responds,” said Kelly Brunt, a glaciologist from NASA’s Goddard Space Flight Center and the University of Maryland. “Will the ice shelf weaken, or possibly collapse like its neighbors Larsen A and B? Will the glaciers behind the ice shelf accelerate and have a direct contribution to sea level rise? Or is this just a normal calving event?”

Scientists have monitored the progression of the rift over the past year using data from the European Space Agency’s Sentinel satellites (which can image with radar during the long Antarctic night) and thermal imagery from Landsat 8 and the MODIS instruments on NASA’s Terra and Aqua satellites.

In the coming months and years, researchers will monitor the response of Larsen C and the glaciers that flow into it with satellite imagery, airborne surveys, automated geophysical instruments on the ice, and field work.

“We don’t currently know what changed in 2014 that allowed this rift to push through the suture zone and propagate into the main body of the ice shelf,” said Dan McGrath, a glaciologist at Colorado State University who has been studying Larsen C since 2008.

McGrath said the growth of the crack is not directly linked to climate change. “The Antarctic Peninsula has been one of the fastest warming places on the planet throughout the latter half of the 20th century. This warming has driven really profound environmental changes, including the collapse of Larsen A and B,” McGrath said. “But with the rift on Larsen C, we haven’t made a direct connection with the warming climate. Still, there are definitely mechanisms by which this rift could be linked to climate change, most notably through warmer ocean waters eating away at the base of the shelf.”

The U.S. National Ice Center will monitor the trajectory of the new iceberg, which is likely to be named A-68. The currents around Antarctica generally dictate the path that the icebergs follow. In this case, the new berg is likely to follow a similar path to the icebergs produced by the collapse of Larsen B: north along the coast of the peninsula, then northeast into the South Atlantic.

NASA Earth Observatory images by Joshua Stevens, using MODIS and VIIRS data from LANCE/EOSDIS Rapid Response. Story by Maria-Jose Viñas, adapted for Earth Observatory by Kathryn Hansen.

Instrument(s):
Aqua – MODIS
Suomi NPP – VIIRS

State-Sponsored Slave Labor: North Korea to Russia

NY Times

“…..the [ North Korea] government has sent tens of thousands of its impoverished citizens to cities and towns across the former Soviet Union to earn money for the state.

Human rights groups say this state-controlled traffic amounts to a slave trade, but so desperate are conditions in North Korea that laborers often pay bribes to get sent to Russia.

North Korean laborers helped build a new soccer stadium in St. Petersburg to be used in next year’s World Cup, a project on which at least one of them died. They are working on a luxury apartment complex in central Moscow, where two North Koreans were found dead last month in a squalid hostel near the construction site……A lengthy report on North Korean workers in Russia issued last year by the Data Base Center for North Korean Human Rights, a group in Seoul, said the Workers’ Party of Korea seizes 80 percent of the wages earned by forestry workers and at least 30 percent of the salaries paid to laborers working in construction. Further money is taken to cover living expenses, mandatory contributions to a so-called loyalty fund and other “donations.”……..”

The Koreas at Night

NASA


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