Monthly Archives: October 2016

Birds to bacteria and kickstarting research boundaries

Did you know us humans have a background army of microbes that work to keep us healthy, turns out these microbial cells outnumber human cells 10 to 1 in a healthy human body! The human microbiome is beginning to be elucidated that shows most of these microbes have a mutualist relationship such as helping us to digest food or producing anti-inflammatories that our human genome can’t produce. Similar to humans, other mammals are expected to have a similar microbiomes that can contribute to a healthy species. However this area of research is in it’s infancy, our guest is spearheading this effort and pushing the boundaries of avian-microbe interactions in tropical environments that can help us understand what contributes to a healthy bird population.

Felipe after sampling a baby trogon (Trogon melanocephalus). This species only nest inside termite nests.

Felipe after sampling a baby trogon (Trogon melanocephalus). This species only nest inside termite nests.

Felipe found his way to these avian-microbe questions while pursing a masters degree at a Chamela biological field station in Mexico. He noticed that some young birds he found in termite-associated nests were dirty and grimy, but they were very healthy! How could this be? His curiosity continued to drive his motivation to pursue a PhD in the Biology Department at the University of Oregon. Yes that’s right he’s a duck, but science holds no grudges because all that really matters is what kind of knowledge this research can produce.

His passion for the outdoors started young while growing up visiting small towns in the seasonal dry jungles of Mexico. He recalls playing with his siblings but would always stop and look at cool rocks, or to show his friends all the creepy crawly insects he found! Only recently did he discover his siblings thought this was annoying because he was more focused on observing his surroundings than playing games with them; sound like a scientist in the making!

Felipe is teaching two field assistants (Rosi and Jesus) how to take body measurements of chicks.

Felipe is teaching two field assistants (Rosi and Jesus) how to take body measurements of chicks.

He is now in his 5th year of his project but has run into a sort of barrier; his research interests are the boundaries of where other researchers have ventured. If he is successful he will be one of few who will assess how nesting behavior influence bird-biomes in a tropical setting. Pushing boundaries may sound glamours but it comes at a cost, literally, because few agencies are willing to fund such a new exploration he’s chosen to pursue other means of obtaining funding.

Experiment.com is a way of combining a grant submission easily understandable to the public, and they can fund your work similar to a kickstarter. As Bill Gates said, “This solution helps close the gap for potential and promising, but unfunded projects.” Felipe’s campaign to raise enough money to help process 500 samples collected from the Mexican jungles has just started and will continue until the end of November. You can learn more about his project on his Facebook page. If you’re interested in this ‘crowd-sourced’ version of research funding you can read about how the process works.

Flycatcher chick after being sampled and measured.

Flycatcher chick after being sampled and measured.

You’ll have to tune in to hear the current state of his research as well as how this new funding venture could provide him the avenue to finish his PhD! You can listen October 30th 2016 at 7PM on the radio at 88.7FM KBVR Corvallis, or stream live.

Mosquito soup in the Brazilian rainforest

Fieldwork in the Brazilian Amazonia meant continuously trying to outsmart their savviest opponents…ants!

Fieldwork in the Brazilian Amazonia meant continuously trying to outsmart their savviest opponents…ants!

Deforestation in Brazil due to cultivation of monoculture crops, such as soybean, has profoundly impacted wildlife populations. In the lab of Taal Levi in the Department of Fisheries and Wildlife, wildlife biologist Aimee Massey has adopted a quantitative approach to studying this impact. During her first and second year of graduate school, Aimee traveled to Brazil for fieldwork and data collection, collaborating with researchers from Brazil and the UK. During this trip, she collected 70,000 biting flies, including mosquitoes and sandflies, by engineering 200 fly traps constructed from 2-liter soda bottles, netting, and rotting beef. Aimee installed biting traps throughout 40 individual forest patches, which are regions delineated by their physical characteristics, ranging approximately in size from the OSU campus to the state of Rhode Island.

Who knew fieldwork could be such a balancing act?!…especially when trying to avoid poisonous insects and thorns. Let’s hope the next branch Aimee reaches for is not of the slithering snake kind!

Who knew fieldwork could be such a balancing act?!…especially when trying to avoid poisonous insects and thorns. Let’s hope the next branch Aimee reaches for is not of the slithering snake kind!

Subsequent DNA analysis on biting flies provides a relatively unbiased source of wildlife tracking, since mosquitoes serve as a repository of DNA for the wildlife they have feasted upon. DNA analysis also provides information regarding diseases that may be present in a particular patch, based on the bacterial and viral profile. For example, sandflies are carriers of protozoa such as leishmania, which cause the disease leishmaniasis. To analyze DNA, Aimee uses bioinformatics and metabarcoding, which is a technique for assessing biodiversity from an environmental sample containing DNA. Different species of animals possess characteristic DNA sequences that can be compared to a known sequence in an online database. By elucidating the source of the DNA, it is possible to determine the type of wildlife that predominates in a specific patch, and whether that animal may be found preferentially in patches featuring deforestation or pristine, primary rain forest.

Learning about human/wildlife interactions while drinking tea with camel’s milk in Laikipia, Kenya.

Learning about human/wildlife interactions while drinking tea with camel’s milk in Laikipia, Kenya.

Aimee completed her undergraduate studies at University of Maine, where she quickly discovered she wanted to study biology and chemistry in greater depth. She planned to attend med school, and was even accepted to a school in her junior year; however, an introductory fieldwork course in Panama spent exploring, doing fieldwork, and trekking made a deep impression on her, so she decided to apply to graduate school instead. Aimee completed a Masters degree in environmental studies at the University of Michigan, during which time she spent 4 months at the Mpala Research Centre in the middle of the Kenyan plateau, just north of the Masai Mara. Following completion of her Masters degree, Aimee spent a year as a research assistant at the University of New Hampshire working with small mammals. Before beginning her PhD studies at OSU, Aimee spent two months in Haines, Alaska doing fieldwork with her future PI, Taal Levi. After she finishes her PhD, Aimee plans to focus on conservation work in New England where she is originally from.

Having fun after fieldwork; Aimee’s eulachon fish catch of the day in Haines, Alaska. One is better than none!

Having fun after fieldwork; Aimee’s eulachon fish catch of the day in Haines, Alaska. One is better than none!

Tune in on October 23rd, 2016 at 7PM on the radio at 88.7FM KBVR, or stream live, to hear more about Aimee’s adventures in Brazil, and why her graduate work is shaping our understanding of how deforestation impacts biodiversity.

 

A Big Punch at the Smallest Scale

How do you connect the dots between sunscreen, coatings on reading glasses, and medicine? Nanoparticles! More and more the potential uses of nanotechnology are moving forward. For example the use of nanoparticles in sunscreen (i.e. zinc dioxide) helps to increase its protective coverage time and its ability to block harmful UVA rays. Another emerging field of nanotechnology hopes to decrease the economic burdens of growing enough food for a booming world population. Matt Slattery joins us from the College of Agricultural Sciences Department of Environmental and Molecular Toxicology to discuss his flourishing endeavor to ensure that technology does not outpace environmental safety.

Matt reflecting at Panther Creek Falls

Matt reflecting at Panther Creek Falls.

Growing food takes a serious amount of commitment, time, and money; and one of the major factors dictating a successful harvest is the timing and effectiveness of the pesticides applied to a crop. Over a billion (1,000,000,000) lbs of the active ingredient in pesticides are applied in the USA alone (EPA)! With the help of nanotechnology we can decrease the necessity of repeated pesticide application and still get the same level of productivity from the land. When pesticides are applied, they generally have a very short residence time, and are only effective in fighting pests for a week or two. However, by encapsulating pesticides in multi-layered nanoparticles that slowly releases a small quantity of pesticide over time, you can get a far more consistent application instead of the boom-and-bust strategy that’s currently used. Another major benefit of nanoparticle delivered pesticides is that farm workers are less exposed to the chemicals because application of the pesticide is less frequent and safer. This encapsulation method is not just for an agricultural application but has the potential to be used in any platform that needs a “time-release” delivery, but much work is still required to make sure we really understand how they interact with the environment.

Matt having a grand time play his ukulele in Halong Bay, Vietnam

Matt having a grand time playing his ukulele in Halong Bay, Vietnam.

To no surprise, it takes someone special to merge multiple scientific disciplines into one research project, and our guest fits the bill! Matt has always been interested in science, but it was the interdisciplinary nature of environmental toxicology that requires the understanding of how chemistry, physics, and the environment can affect the biology and health of an organism. His first experience with the contamination of the Puget Sound in Bellingham, while attending Western Washington University, was a catalyst that launched him to eventually work with the Lummi Tribe. There he joined the discussion of how salmon as a major source of food, as well as their cultural foundation, could be damaged by bioaccumulation from the contaminated estuary. This intersection of science and outreach convinced Matt he wanted to pursue a higher degree, but he decided to go abroad for a short time before putting his nose to the grindstone!

You’ll have to tune in to hear where Matt’s explorations led him, and how nano-technology is becoming an increasing popular method for chemical delivery across scientific disciplines and industries. You can listen on October 16th 2016 at 7PM on the radio at 88.7FM KBVR, or stream live.

Heavy Digging

minealgae

Mine Algae!!!

When I think of mining, the first thing that comes to mind is the classic gold rush miners from the mid-1800s. Someone that looks a lot like Stinky Pete from Toy Story 2. I don’t mean to imply that this is, or isn’t, what a miner looks like. However, this does say something about the general lack of thought about mining practices. The EPA certainly isn’t as ignorant about mines as I am; in fact, as of 2014, they had designated over 1,300 sites around the country as superfund sites requiring extensive cleanup efforts. Tullia Upton is also thinking about mines much more deeply than the average person, and she is uncovering some alarming information.

During a road trip through southern Oregon, Tullia was bummed when she was told it was unsafe to swim in a local river, so she decided to dive a bit deeper, figuratively of course. She learned that this area has become dangerously polluted due to waste products of the Formosa mine.

formosamine

The Formosa mine near Riddle, OR

Mining practices involve extensive digging and extracting of heavy metals which are normally buried in a reducing environment deep down within the earth’s sediment. The process of digging up these heavy metals leaves behind a staggering amount of unused material, known as tailings. Mining also exposes the metals to oxygen and allows them to leach into soils and the watershed. Due to runoff from the tailings and other waste at the Formosa mine, there is now an estimated 18 mile dead zone where no organism can live. The full extent of the damage being done to the local watershed has not been thoroughly mapped though.

tulliainlab

Tullia analyzing samples in the lab

As she learned more about the dangerous metals coming from the mine, Tullia immediately got involved as a volunteer and secured research funding to study the pollution occurring at the Formosa mine. Tullia hopes to map the full extent of runoff from the Formosa mine and provide a better picture of the mess for the EPA, and other scientists, working on the cleanup process. When she finishes her Ph.D. here in Environmental Sciences, Tullia hopes to move on to a post-doc and eventually run her own research lab.

Tune in this Sunday, October 9th at 7pm PST to hear more about mine pollution and Tullia’s unique journey to grad school at OSU.