Humans produce 500 billion plastic bags annually.

In China, they recently banned it. Australia, Bangladesh, Ireland, Italy, South Africa,Taiwan, Mumbai and India have either banned it or discouraged its use by raising taxes. And on March 27, 2007, San Francisco became the first city in the USA to ban it from large grocery stores.

More people are ditching plastic bags on a local and national level with good reason: we produce about 500 billion plastic bags world-wide, and less than one percent of that is recycled.

A recent QUEST report shows that plastic bottles are straining our environment, too: each year the USA alone produces 50 billion plastic bottles. Some would say to switch from plastic to paper bags - but reports show that paper bags aren’t the most sustainable solution.

Plastic can have a longer shelf-live than humans do: it can persist in the environment for anywhere between 20 to 1,000 years. But a 16-year-old from Waterloo, Canada figured out to decompose it in only six weeks.

Daniel Burd, a student at Waterloo Collegiate Institute, discovered the key to decomposing plastic bags for a school science fair. Needless to say, he won.

“Almost every week I have to do chores and when I open the closet door, I have this avalanche of plastic bags falling on top of me,” said Burd to The Record, a Waterloo newspaper. “One day, I got tired of it and wanted to know what other people are doing with these plastic bags.”

First, Burd decided to isolate the microbes that break down plastic in polyethelene plastic bags. Burd ground plastic bags into powder and created a solution to break it down using tap water and yeast. Six weeks later, he found that the plastic weighed 17 percent less than the control group.

Burd then isolated the effective strains that caused the degradation - Sphingomonas and Pseudomonas - and tried the experiment again, adding sodium acecate.

Six weeks later - as opposed to 1,000 years - the plastic decomposed by 43 percent.

For his final report, Plastic Not Fantastic, Burd wrote that his process of polyethylene degradation can be used for large-scale plastic bag biodegradation.

“As a result, this would save the lives of millions of wildlife species and save space in landfills,” wrote Burd.

And how this metamorphosis saves Monkeys!

Colombia: a beautiful country, with incredible forests and diverse wildlife, but like many other countries, a trash problem. With no formal trash collection system, the forests and villages suffer from scattered plastic bags, endangering wildlife and creating a mess on village streets. One such village was Los Limites, until they came up with a most transformative solution: Eco-Mochilas!

The Eco-Mochila project was invented by the organization Proyecto Titi (Project Tamarin), a dynamic conservation program that combines field research, education, and community programs in an effort to protect the endangered Cotton Top Tamarin.

An Eco-Mochila is a bag made from crocheting 100 plastic bags into a colorful beach bag or purse. The innovative woman who create the bags are called the Asoartesanas. They encourage villagers and school children to collect plastic bags and as they go door to door to collect, they educate the people about their local wildlife. Then, they cut the bags into strips and begin their craft.

Eco-Mochilas are sold throughout the world at various venues and bring in a suitable salary for an artist. Of course, the collecting of thousands of plastic bags has other benefits: a more beautiful village, and a forest clear of trash, which makes a certain one-pound monkey very happy.

The endangered Cotton Top Tamarin is found only in the forests of Colombia. Deforestation and capture for the pet trade are the species’ greatest threats. The Eco-Mochila project creates sustenance for villagers, an alternative to using the forest for such, and of course, offers a cleaner forest for all wildlife.

The program has been so successful that the Asoartesanas have trained people from other countries to begin similar project in their communities…

And in case this is important to their case, eco-mochilas are cute, come in different sizes, can be personalized, make great presents and are water resistant. I have three!

Click here to purchase an Eco-Mochila and help Cotton-Top Tamarins; and come visit the Tamarins at the Oakland Zoo anytime.

Each big storm with a high tide and an
onshore wind takes a big bite out of Sarichef.Photo By Shishmaref Erosion and Relocation Coalition

In an email this week from John Woodward, an Alaska builder and Home Energy author, he wrote, “I put together a working/management group to manage the relocation of the community of Shishmaref sustainabely. They live on Sarichef, a barrier island that global warming is wiping out.”

Shishmaref is home to a small community of Inupiat, a Native American tribe. John is working with the Inupiat Tribal Government, the City of Shishmaref, and the Shishmaref Erosion & Relocation Coalition, to salvage as much of the village as possible before it goes under water and move it, along with the island inhabitants, to a new plot of land in the interior of Alaska.

The Army Corp of Engineers gives the island about 5 or 10 more years of livability. But as the ocean and permafrost warm and the ocean rises, unpredictable storms take a heavy toll on the island. “Each big storm with a high tide and an on-shore wind takes a big bite out of Sarichef,” says Woodward.

The community is seeking funds for a comprehensive alternative energy plan, an anaerobic pump/methane generator, and the retrofit of all existing buildings, including more than 110 homes, community buildings and a school. The homes will be retrofit to use less than 5 Btu per square foot to heat. Heating load calculations can be pretty complicated, but in general, contractors recommend furnaces that can provide 30-50 Btu per square foot to heat homes in the Bay Area. To reach such a high level of energy efficiency, the Shishmaref homes will have the insulation installed on the outside of the structure, a technique that Woodward has successfully used in the past. The new village will have the look and functionality of the Inupiat culture as defined and designed through community planning.

“Our community planning process involves community charettes with the whole community gathered in the school gym,” say Woodward. “The goal of these meetings is the rough-out of a comprehensive community plan for sustainable relocation of the existing salvageable infrastructure and the development of the new village site.”

The Inupiat will build their new village to suit their needs and lifestyles, to be efficient, and to be in harmony with its surroundings-in other words, sustainabely. Let’s keep an eye on our northern neighbors, who may teach us some valuable lessons. How long before whole towns in California will have to relocate because of water shortages? We all witnessed what happened in New Orleans a few years ago. How long before towns and cities on the coast of California will have to move inland or be seriously reconfigured because of the rising Pacific Ocean?

You can e-mail John Woodward with questions, comments, ideas, and offers of help at panuktuk@yahoo.com.

A look into the science of skin.

In an article this week in the New York Times, brainpower was correlated with the complexity of nerve synapses. Leading researcher Dr. Grant, who has studied the interconnectedness of neurons, likened this connection to technology; “From the evolutionary perspective, the big brains of vertebrates not only have more synapses and neurons, but each of these synapses is more powerful - vertebrates have big Internets with big computers and invertebrates have small Internets with small computers.” The brain has been made analogous to a computer before in order to study evolutionary adaptation. However, the brain was not the organ being studied, rather it was human skin.

Have you ever wondered why we have hair only on the tops of our heads and the rest of our skin is relatively bare? Why does our skin come in so many pigmentations? And why does our skin sweat? Dr. Nina Jablonski kept asking why and attributes these adaptations to the need to keep our brain cool. I first heard Dr. Nina Jablonski speak about her most recent book, Skin: A Natural History, in early 2007. I was absolutely enthralled and two hours raced by as she articulated her fascination with skin. Dr. Jablonski divulged into why our skin appears and acts the way it does from an evolutionary standpoint. Her findings showed that about two million years ago our ancestors were running long distances in Africa under the heat of the equatorial sun. To keep their brains cool, sweat glands became more prominent. This in turn let brain size expand and evolve. In the fossil record, it shows after this increase in brain size, Homo sapiens left Africa to migrate into Mainland China.

Skin:A Natural History

So skin was an evolutionary adaptation to keep our large brains cool and working effectively. Skin color, Dr. Jablonski surmised, was what regulated our body’s reaction to the sun and its rays. Dark skin evolved to protect the body of those of our ancestors close to the equator. Those ancestors further away evolved light skin in order to take in Vitamin D in less sunny climates. After her talk about Rosacea, which is a condition of constant blushing found in Eastern European nationalities, I asked Dr. Jablonski why. She told me this might have been attributed to ancestors of light skin being overly bundled and getting over-heated. It might have been an adaptation to release heat and cool the brain from the only exposed skin.

In her lecture, Dr. Jablonski did not stop with touching upon evolutionary adaptations, she also delved into how we associate and identify through our skin. We decorate our skin, clothe it, paint it, tattoo it, scar and pierce it. She elucidated skin as an intimate connection with the world as well as our presentation of individuality. Skin: A Natural History and Dr. Nina Jablonski have gained national recognition. She was even invited as a guest on the Colbert Report to talk about her findings. It is rumored that she is following up Skin with more in-depth research. Until then, this is an outstanding look at a very under-appreciated organ, one that might have made the complex nuances of our brain and its synapses possible.

Watch Dr. Nina Jablonski on The Colbert Report:

A patch of what might be ice, exposed by Phoenix’s
landing rockets.So, did it land on ice? Huh? Did it?

Two blogs ago I wrote about the then upcoming landing of the Phoenix spacecraft on Mars, near the Northern polar ice cap (Probing the Martian Pole). The entire point of landing on Mars’ extreme northern plains was to find and examine ice-ice we know is up there in great abundance, as detected by orbiting spacecraft (Mars Odyssey 2001).

There, frozen under the surface dust layers, is a vast deposit of ice-”enough to fill Lake Michigan twice.” So Phoenix was sent to actually land there and scrape up surface samples of the soil, and hopefully ice. The question was, would the layer of dust covering the ice be thin enough for Phoenix to reach the ice with its robotic arm and shovel?

The landing occurred on May 25th-a successful landing. NASA broadcast the drama live on NASA TV, which we shared with several hundred Chabot visitors via planetarium, theater, and closed-circuit TV. There were no actual images coming from Phoenix during the landing-after all, it was cooped up in its protective shell for much of the descent-but the excitement of the real-time drama and the nervous faces of NASA/JPL were enough to enthrall our audience. Pictures wouldn’t come form Phoenix until later that night at the earliest.

But the pictures did come in over the days following. At first they looked much like images from other Mars landers (Viking, Pathfinder, Spirit, Opportunity), only flatter. Rusty red soil, low flat horizon, a scattering of pebbles and rocks. The landscape itself appeared less interesting to me than other landing sites-but if you measure Phoenix’s success by the beauty of the scenery, you’re missing the point.

Phoenix is pretty much all about the ice, and what chemicals are frozen and preserved in it. The questions asked by the Phoenix mission are: did life ever arise on Mars, is the current climate on Mars suitable to support life, and what is Mars’ geological makeup? If the vast ice deposits of the flat northern hemisphere lowlands are the frozen leftovers of what was once a liquid sea, then are there chemical clues of past conditions-even past life-locked up and preserved there?

So, do we have answers to these questions yet? Is there ice under Phoenix within reach of its scooper? At the time of my writing this the answer is: maybe. During the first week of testing Phoenix’s systems to get it ready for full-on prospecting, a picture of the ground underneath the lander was taken using the camera attached to the robotic arm. This picture revealed a patch of solid substance that seems to have been exposed by the blast of Phoenix’s landing rockets. It looks like it could be ice, but until a sample is analyzed we won’t know for sure (because, it could be solid rock, too).

The first sample scoop of soil dug up by Phoenix’s shovel was placed in a bucket on board the lander and examined by camera, before being carefully dumped into a designated sample waste location (Mars’ first land fill). The picture revealed some white substance in the reddish soil-which could be ice, or possible salt.…

Stay tuned in the coming days and weeks for hot news from the ice as Phoenix conducts its investigations in earnest.

You’re as likely to be struck by lightning
as to have a severe reaction to a vaccine.

I was reading an article in Time last week about parents not vaccinating their children. The story was about how this phenomenon is becoming more widespread.

These kinds of stories are weird to me because vaccines are pretty safe. The risk of an adverse side effect is incredibly small. For example, the risk for anaphylaxis from the Hepatitis B Virus vaccination is around 1 in 600,000. This is about the same risk as being struck by lightning (1 in 700,000).

Of course, the article wasn’t talking about known risks. Instead, it was referring to a hypothesized link between vaccines and autism.

People proposed this link when they noticed that cases of autism and the number of vaccinations were rising at the same time. Of course, just because two things happen to occur at the same time, this does not mean they are causally linked. For example, the increase in global temperature is not related to the decrease in the world’s populations of pirates (despite what the Pastafarians say).

So how could an increased number of vaccinations cause an increase in the number of cases of autism? I have seen two ideas put forth. The first is that thimerosal is to blame. The second is that there are so many vaccinations now that we are stressing out the body’s immune system. Most likely neither idea is valid.

Thimerosal is a mercury-based preservative that used to be used in vaccines. Even though there haven’t been any good studies on the effects of thimerosal on brain development, everyone knows mercury is bad for the brain. So the idea behind thimerosal makes some sense.

Back in 2001, vaccine manufacturers decided to eliminate thimerosal from their vaccines. We would predict, then, that cases of autism should go down significantly if thimerosal was linked to autism. They haven’t. In fact, in one California study, cases have continued to climb. So thimerosal is most likely not to blame.

Another point that has been made is that there are so many vaccines now that we are stressing out our bodies’ immune systems. Again, this concern is unfounded.

Vaccines are injections of viral proteins. Our bodies see the proteins and raise antibodies to them. Then when a virus invades, we have antibodies that recognize the virus and target it for destruction.

It is the number of viral proteins that matter in terms of taxing the body’s immune system and not the number of vaccinations. All of the current vaccines put together do not have as many viral proteins as the old smallpox vaccine (150 vs. 200). So the number of vaccines is unlikely to be the issue.

What all of this means is that vaccines are probably not responsible for the significant increase in the number of cases of autism. What is responsible? No one knows for sure.

It may be that the rise just comes from all of us recognizing the symptoms more. Or it could be due to some cause we don’t know about or understand.

What we do know is that vaccines save many lives. I assume no one wants to go back to the early 20th century when polio epidemics swept the country. For example, 2,500 cases of polio ended up at one Los Angeles hospital between May and November of 1934. And in 1952, the U.S. had 21,000 cases of paralytic polio.

We can prevent this sort of thing from happening by making sure everyone is vaccinated. And yet there are people who choose to hide behind the people who take the miniscule risk of getting vaccinated.

Is this a matter of free choice? Should parents be allowed to opt out of vaccinating their children even if it risks society at large?

One idea, I suppose, is to have people who choose not to be vaccinated to sign a waiver saying they accept full responsibility for their actions. In practice this would mean that health insurance and the government would not be responsible for their children’s health care bills if they become ill with one of the diseases they refused to be vaccinated against.

And if your infant, grandma, or immuno-suppressed cousin came down with a disease these folks refused to be vaccinated against, then you could sue the un-vaccinated for damages. The common good isn’t enough to encourage these folks. Perhaps threats to their pocketbook will be.