Monday February 20, 2006 news@michigandaily. com SCIENCE SA Sharks: The initial frontier 'U' scientists explore the possibilities of controlling sharks via remote control By Matt Beneke Daily Science Writer When most people hear the word "shark," certain images come to mind: a swiftly moving fin slicing through the water with dramatic 1970's nail- biting music in the background; or maybe a giant pointed nose, a pair of angry, flared nostrils and a row of dag- ger-like teeth a league wide. But researchers are adding a new image to that list. Sharks are now the guinea pig used to validate the design of the next generation of electrical brain stimulation devices. A shark whose behavior is dictated by a small wireless device implanted in its head? Sounds like something out of the next James Bond picture. But if all goes well, a research team at the University will make this areality. A multi-disciplinary team, led by biomedical engineering Prof. Darryl Kipke, is in a competition with other universities to create a wireless brain recording and stimulation device to transfer control of free-swimming nurse sharks to a human operator. Being able to model the dynamics of the nurse shark's brain might also help us learn more about the brain plasticity of other animals, including that of a certain advanced ground- dwelling primate. Sponsored by the Defense Advance- ment Research Project Administration, the team consists of Albion College biology Prof. Jeff Carrier, researching at Kipke's Neura, and Ann Arbor start-up company NeuroNexus. The Neuro Engineering Labora- tory brings to the table experience in neural implant recording and stimu- lation experiments. Carrier captures the sharks, houses them and brings his expertise in shark husbandry and behavior. NeuroNexus supplies the neu- ral electrodes and electronics that will be implanted into the sharks. But why a nurse shark? According to nurse shark expert Car- rier, there are a number of reasons. First of all, they are relatively easy to capture. All it takes is a trip to the Florida Keys, and Carrier is able to live-cap- ture them using a variety of methods, including nets, rod and reel, and long- hooked lines. The ideal size, for reasons of trans- port and subsequent laboratory research, is a shark between 2 to 4 feet long, but the animals can grow up to 7 feet. The nurse shark is also known to adapt well to captivity. Most sharks need to keep mobile in order to move water across their gills, but nurse sharks can keep a steady flow of oxygenated water over their gills even if they are lying still in a confined environment. Additionally, nurse sharks are par- ticularly docile, as they only eat small aquatic invertebrates and are not as likely to chomp off the arm of a careless grad student. "Nurse sharks are very intelligent creatures and conditioning their behav- ior with the use of food is not as daunting of a task as it may seem," Carrier said. As with any research involving ver- tebrate animals, the research must be approved by the University Commit- tee on the Use and Care of Animals. In addition, the research must follow protocols established by the commit- tee regarding the ethical treatment of the animals. According to University researcher Mark Lehmkuhle, the first step toward developing the device is to effectively record brain signals from anesthetized nurse sharks. The team does this by implanting sensory electrodes into the known olfactory and auditory brain cen- ters of the shark. DAVID TUMN/Daily Albion College biology professor Jeff Carrier carefully places a shark back Into a tank at his research lab. "It's going to be tricky to figure out how to protect electronics from the harsh environment that is sea water." - Jeff Carrier, Albion College biology professor A brief history of neurological experiments The inspiration for this project is not confined to a single disci- pline; it draws from many areas of science and has roots in vari- ous notable experiments of the past. In the 1780's, the Italian biologist Luigi Galvani first per- formed an experiment that would be repeated endless times in biology laboratories to easily- impressionable undergraduates. Galvani found that the applica- tion of electricity to a frog could cause its muscles to contract, even if the muscle is part of a detached leg. The work was furthered in the early 1800s by a fellow Ital- ian named Felice Fontana, who advanced to human brains. He applied electricity to the brains of cadavers, which elic- ited mysterious facial muscle contractions. But Italian society was not quite ready for this type of experimentation with their deceased. Fontana avoided their wrath by switching to the use of living research subjects. Russian scientist Ivan Pavlov was a pioneering researcher best known for his research in the early 1900s involving condi- tioned reflexes. Pavlov's infamous experiment involved ringing a bell before feeding his dogs. The dogs then associated the sound with a sub- sequent food reward. With time, he was able to get the dogs to involuntarily drool with no food being presented, as long as they heard the bell ringing. The idea that environmental events (a ringing bell) that previ- ously had no relation to a given reflex (drooling), would trigger that reflex proved to be a revo- lutionary idea impacting not only the field of animal research, but also in human behavior. The first quantitative recording of electrical signals of the brain was done in the mid-1920s by an Austrian scientist named Hans Berger. Inspired by a telepathic encoun- ter with his sister, he decided to devote his life to develop a scientific model to explain the mechanism of his experience. In a quest to determine how blood flow to the brain fuels mental and psychic energies, he developed the first electroen- cephalogram. Though his psychic energy models have yet to be validated by anyone, his device continues to be a valuable tool to non-inva- sively measure brain function. These electrodes are then connected to wires that power the device as well as deliver the electronic brain signals to a data acquisition program on a computer. But they're not looking for just any brain activity. The team is interested in recording representative signals from the appropriate locations in the cortex while exposing the sharks to specific scent and auditory cues. Previous research has shown that it is possible to expose certain odors to lab rats, and correlate each of the odors to a specific pattern of neural activity. This activity is sensed by electrodes placed in olfactory centers of the animal's brain. The next step would be to conduct the same sensory experiments on conscious, free-swimming nurse sharks. The sharks will be trained to move to the left or right side of their holding tank, according to scent and auditory cues, with the motivation of a food reward when it moves in the desired direction. The aim of this step.is to gather a set of electrical brain signals that are valid representations of the odors and sounds used to train the sharks. Once the sharks have been trained, the team will attempt to direct the shark to move to the left or right, but without exposure to the scent and sound cues. By using stimulating electrodes in the appropriate areas of the shark's brain (still with trailing power and communication wires), they will deliver the representative brain sig- nals to mimic the real cues. The idea is that if the scent and sound information can be adequately repro- duced by artificial stimulation in the appropriate areas of the shark brain, the behavior associated with the real scents and sounds will be reproduced with the artificial stimulation. Finally, the previous tests would be repeated on the same free-swim- ming sharks, but this time without wires attached. A wireless device will be implanted under the skin of the sharks, capable of sensory recording and transmitting the brain signal to a computer, as well as receiving instructions from the computer to stimulate the motor areas of the brain to elicit the desired movement. Going wireless has many obvious advantages, especially in the electri- cally-conductive and corrosive envi- ronment of salt water that the nurse shark needs to survive. However, there are real problems involving signal bandwidth and power to overcome, as known to anyone with a cellular phone who has experienced broken or dropped signals and dead bat- teries. Carrier said mixing electronics with water will also create some inherent difficulties. "It's going to be tricky to figure out how to protect electronics from the harsh environment that is sea water," he said. This project is at its early stages, oDvAI DTUAN /j Daiy Albion College biology senior Amy Hupp and nurse shark expert Jeff Carrier measure a shark in Carrier's lab. and right now the team is at the tory cues, dictate shark behavior first step. With its lofty ambitions within the brain. and scope, they anticipate that it The development of this device will will take years to progress to the result in a valuable tool to understanding wireless controller. At present, it how animal behavioral responses change is not clear how sensory system when they originate from artificial, ver- input, such as olfactory and audi- sus natural, neural stimulation. I I1 LI-M 5ummer Language Frograms ~tuj j tkela~ngu age o g ur c) UF kice! Intensive. courses avai able in i14- an&;ua es! .0 w ckecC oijt the full range of offerings go to \ $ , I 7 Exciting Summer Opportunities with a leader in Electro-hydraulics. FEMA Corporation announces it is seeking mechanical engineering student candidates for summer engineering internships to work in a world-class manufacturing environment. Successful candidates will be exposed to the following real life training: Product orientation Testing equipment training Laboratory procedlures Less commonl9 taught language courses will include: Arabic, Chinese, Dutch, Greek, Hindi, Italian, Japa-