Offshore Wind in Maine: Investing in a Cleaner future

Mackenzie Briggs – Building Construction Technology

Lora Miller – Environmental Science

Sagie Madnick – Natural Resource Conservation

Brittney Furtado – Animal Science

 

A computer-simulated image provided by Cape Wind Associates of the view off Cape Cod after construction of the proposed wind farm. Retrieved November 12,2014 from http://www.cbsnews.com/news/feds-ok-nations-first-offshore-wind-farm/

A computer-simulated image provided by Cape Wind Associates of the view off Cape Cod after construction of the proposed wind farm. Retrieved November 12,2014 from http://www.cbsnews.com/news/feds-ok-nations-first-offshore-wind-farm/

 

Offshore Wind in Maine:

 Investing in a Cleaner future

 

The sun starts to rise and you’re woken up by its blinding light and the annoying “Ehh! Ehh!” of an alarm. It’s just another day and you need to get ready. Half-asleep, you go through your morning routine; eat, shower, whatever that may be. You reach for the door handle then quickly retract.  You realize you forgot something, the most vital part of your outfit: your respirator. This may seem far fetched, but for millions of people this has already become a reality. In cities like Beijing, air pollution has become so thick from fossil fuel emissions that many people do not leave home without a protective mask. This reality may not be too far down the road for us here in the United States. Continue Reading

Green Roofs at UMass Amherst

Brianna Lancaster- Animal Sci

Quinn Lonczak- ECO

John Yip- BCT

INTRODUCTION AND THESIS

If you have studied, lived, or worked at the University of Massachusetts Amherst, then chances are you have seen it. Running alongside Massachusetts Avenue, just south of the Intramural Athletic fields, it is now a normal presence. “It” is a grand stream of excess stormwater produced by the ever growing amount of impermeable surfaces on the campus. It is not formed naturally. It carries pesticides, contaminants, and other harmful substances directly into the Mill River and it can be abated. Increases in development of these impermeable surfaces prevent water from being absorbed into the ground as it naturally would. These surfaces force large quantities of water to flow and collect in smaller areas that are not necessarily designed to handle that quantity of water. Continue Reading

Green Roofs for Endangered Birdlife in Boston, MA

Juliana Dolin – Pre-veterinary, Zachary Miller – Building Construction Technology, Sean Braley – Building Construction Technology

There’s no place like home, right? Imagine the comfort of your home, relaxing in a familiar territory, surrounded by family and friends. Now imagine that disappearing. Where would you go? What would you do?

This is the harsh reality for many animals as natural lands come down and concrete buildings go up. As urban expansion continues, open spaces diminish and with this several plant and animal species dwindle as well. According to the National Wildlife Federation, Smart Growth America and NatureServe (2005), over the next 25 years at least 22,000 acres of natural habitat and almost 1,200 species of both plants and animals will be lost due to metropolitan development (“Groups: Urban Sprawl”). The government lists 1,264 species to be endangered or threatened by extinction in the United States (“Groups: Urban Sprawl”, 2005). Over 300 of these species are in Massachusetts (“Massachusetts List”, 2014). Continue Reading

Naturalistic Housing and Environmental Enrichment for Nonhuman Primates

Wisconsin National Primate Research Center [Photograph]. (2014). Retrieved November 12, 2014, from: http://wisconsinwatch.org/2014/07/university-of-wisconsin-to-reprise-controversial-monkey-studies/

Wisconsin National Primate Research Center [Photograph]. (2014). Retrieved November 12, 2014, from: http://wisconsinwatch.org/2014/07/university-of-wisconsin-to-reprise-controversial-monkey-studies/

Introduction

Research laboratories around the world utilize animals as their subjects in hopes of making scientific discoveries that will benefit humans. However, in exchange, the welfare of these animal subjects becomes a concern, especially that of non-human primates. In the last year, the poor welfare of these primates has been exposed, as Harvard Medical School announced it’s plans to close down their primate research facility. They came to this decision as a result of multiple citations issued for incidents occurring from 2011-2012. Although they stated that their decision to shut down was based on financial hardships, a string of incidents resulting in multiple primate fatalities suggests there was more that led to that decision (Valdmanis, 2013). Valdmanis (2013) states that there were different causes to the death of four primates, including an overdose of anesthetic that led to liver failure in one, dehydration in two others, and one that suffered accidental strangulation by a chain attached to a toy. Based on this sequence of isolated events, the welfare of non-human primates in laboratory settings is a concern, as multiple deaths have occurred due to neglect. If primate research laboratories continue to operate in their current condition, this neglect will continue. If these conditions are not made known to those who work in these laboratories, the same careless mistakes will continue to be made. While there are a number of regulations in place in regards to the treatment of primates, the next step towards bettering their welfare seems to be environmental enrichment.

Causal Analysis

The root of the concerns with the welfare of non-human primates stems from the lack of environmental enrichment in the laboratory settings, which allows for species-typical behavior such as perching, grooming, foraging, and toy manipulation (V. Reinhardt; A. Reinhardt, 2008). Beaver (1989) notes that this lack of enrichment leads to depression, aggression, and self-mutilation among the primates. Since many laboratories are shutting down based on the welfare concerns of primates, research on primates altogether may come to a stop. Primate research is important because this species is the most closely related species to humans, which means that utilizing them for research will be beneficial to finding cures for diseases that affect the human population (Gabarini, 2010). In addition to this, experimental findings that are skewed, resulting from decreased welfare, could have negative impacts on humans that are using the drugs developed through the research (Shively, Clarkson & Kaplan, 1989). Shively et al. (1989) described a significant increase in the incidence of coronary artery atherosclerosis in female cynomolgus monkey housed alone, this underlying physiological occurrence holds the potential to skew reactions to testing and medications. Therefore, for better treatment of non-human primates, a laboratory setting should be created that mimics their natural habitat and allows for them to practice their natural behaviors.

Social Enrichment

Since non-human primates naturally live in social groups, housing them in close proximity to one another ensures social contact and avoids the development of abnormal behaviors. For example, Thom and Crockett (2008) propose placing animals in cages with a grooming contact bar panel, allowing social grooming to occur. The authors also state that the social needs of these animals can be met if they are housed together in large cages, connected “run-through” cages, or in cages connected by tunnels that allow for physical contact.  Beaver (1989) states that a study placing non-human primates in isolation identified development of abnormal behaviors, which included body clasping, rocking, hyperaggression, rigid stances, sexual dysfunction, clinging, repetitive circling, and self-mutilation (p. 7). These findings exemplify the critical importance of ensuring that non-human primates are housed in a setting that allows social contact.

Further research is being conducted on how to provide primates with the opportunity for social interactions while still providing scientists the opportunity to work with primates on an individual basis to obtain valid results and measurements. A social tethering system allows for scientific testing to take place while still “[p]rovid[ing] primates with the opportunity to engage in species typical behavior and thereby minimiz[ing] conditions that have been identified as contributing to the development of abnormal behaviors associated with individual housing” (Coelho, 1990, p. 388). This system still effectively allows scientist to sample body fluids, monitor physiological parameters, collect urine, monitor food/water consumption, and monitor their physical activity and social interactions. The Coelho (1990) system consisted of a specialized cage with a section for housing small social groups of adult baboons, and another section consisting of the tether and indwelling catheter system to collect samples. This system allowed for up to four baboons to be housed together, and this number could vary depending on the size of the housing unit created. The units themselves had the opportunity to be subdivided by means of a wire fence. “The tether system consisted of a backpack, a cloth jacket, a stainless-steel flexible cable containing electrical cable and catheters, and a saline infusion pump mounted on the top of the cage”(Coelho, 1990, pp. 390). Depending on the specific type of research is going to be conducted with the primates, this system could provide an excellent model for research housing.

Enrichment with Wood

In addition to the importance of providing social conditions to research primates, providing other components that simulate a natural habitat, such as the presence of wood and the opportunity for foraging, is vital to increase welfare. For most primates, species-typical behaviors include perching, climbing, and foraging for resources such as food. The United States Department of Agriculture requires that animals held in captivity be provided enrichment that allows the expression of these activities (United States Department of Agriculture, 1991). The opportunity for primates to engage in many species-typical behaviors can be provided through wooden stimuli. Reinhardt (2000) states, “wooden objects provide inexpensive, safe, long-term and effective stimulation for the expression of non-injurious, species-typical behaviors such as perching, gnawing, gouging, manipulating and playing” (p. 13). Furthermore, there is a tendency for wood to warp over time, and this provides primates with continual intellectual stimulation (Luchins, Baker, Gilbert, Blanchard, & Rudolf, 2011).

The benefits to providing wooden enrichment expand beyond it’s inexpensive cost, low hazard threat, and strong promotion of species-typical behavior. For example, Simonson (2002) states that using hydroscopic materials, such as wood, increases indoor comfort and air quality in comparison to similar structures made of steel and concrete. This statement validates their research by saying in their tests, “…as many as 10 or more people of 100 are satisfied with the thermal comfort conditions (warm respiratory conditions) at the end of occupation.” Similarly the authors determined occupant discomfort was reduced by 25%(Simonson, 2002, abstract). Given the close relationship between humans and non-human primates it seems fair to say that they should be housed in a comfortable environment. It is important to create a comfortable environment for nonhuman primates to create accurate test results. This is comparable to taking a test in a hot and humid room. The heat makes it difficult to focus, but the humidity makes it that much worse, not to mention participants are unlikely to perform to the same standard as they might in less humid conditions.

 

Opposition to Enrichment

Some opposition to naturalistic habitats in a research or laboratory setting has been presented from researchers concerned over the potential of wood to present as a fomite. If this were the case, wooden objects, such as perches and toys, would need to be replaced frequently to prevent potential disease transfer, which would pose an expense on researchers (Bayne, Dexter, Hurst, Strange & Hill, 1993). This concern has been invalidated by research done on the sanitation of wood. After researchers sanitized three different sources of primate cages, they found that Manzanita wood displayed on 13% growth of gram-negative bacteria compared to a 50% growth rate on plastic toys and 32% growth on the actual cages (Luchins et al., 2011, p. 6). This indicates that wood will not pose threat as a potential fomite and that it’s easy sterilization makes wood an excellent candidate for a source of environmental enrichment. Reinhardt (1997) expands on this by showing that with wooden objects being sanitized in the same routine as cage sanitation procedures there has been no incidence of health risks or injuries associated with wood.

Opposition to Primate Research

Opposition to research involving animals in any form will hold that the shutting down of research laboratories is a cause for celebration. However, in terms of human medicine, this is not the case. The utilization of primates in research holds a critical importance to contemporary medicine (Gabarini, 2010). Incredible advances in the treatment of Parkinson’s diseases, Alzheimer’s disease, and AIDS have been made in the past decade, and these advances would have been impossible without the model of primates (Capitanio & Emborg, 2008). The understanding and treatment of alcoholism, sleep related disorders, and behavioral disorders are also results of the major advances made from research conducted on primates (Garbarini, 2010). In the contemporary world of medicine, primates serve a vital role in the treatment of human disease and disorder, and as long as steps are made to provide these primates the maximal care and welfare, scientists should be able to continue their advances. Applying a naturalistic environment should be the key to establishing this maximum welfare.

Conclusion

It is clear that there is a lack of enrichment in current research laboratories, leading to the decreased welfare of nonhuman primates. Enrichment is necessary not only on an ethical standpoint, but it is also required to successfully conduct primate research and obtain the most valid results. Enrichment provided through the use of housing that allows for social contact and naturalistic elements such as wooden toys and foraging stimuli simulates a natural environment at which primates function best. This natural environment should promote species-typical behaviors and decrease the incidence of depression, agitation, self-mutilation and stereotypies amongst primates. This will correspond to an increase in primate welfare, which will allow breakthroughs in modern medicine to continue. Currently, the American Association for Laboratory Animal Sciences regulates and audits laboratories through the Institutional Animal Care and Use Committee (IACUC). While the IACUC enforces strict regulations in terms of cage height, sanitation, and food availability, there are not specific guidelines in terms of enrichment (Garber et al., 2011). Hopefully, by reviewing the information presented in this paper and other research, the IACUC will be influenced to mandate policies that promote enrichment and increase the welfare of non-human primates used in research.

References

Bayne K.A., Dexter S.L., Hurst J.K., Strange G.M., Hill E.E. (1993). Kong toys for laboratory primates: are they really an enrichment or just fomites? Lab Anim Sci, 43, 78–85. Retreived from PubMed.

Beaver, B. (1989). Environmental enrichment for laboratory animals. ILAR Journal, 31(2), 5-11. doi: http://ilarjournal.oxfordjournals.org/content/31/2/5.full

Coelho A.M. Jr., and Carey K.D (1990). A social tethering system for nonhuman primates used in laboratory research. Lab Anim Sci, 40(4), 388-394. Retrieved from PubMed.

Eckert, K., Niemeyer, C., Anonymous , Rogers, R.W., Seier, J., Ingersoll, B., Barklay, L., Brinkman, C., Oliver, S., Buckmaster, C., Knowles, L., Pyle ,S. (2000). Wooden objects for enrichment: A discussion. Laboratory Primate Newsletter 39(3), 1-4.

Garbarini, N. (2010). Primates as a model for research. Disease Models & Mechanisms, 3 (2), 15-19. doi:10.1242 Harvard Fined $24,000 for Animal Mistreatment After Monkeys Die.” Reuters. N.p., 18 Dec 2013.

Garber, C., Barbee, R., Bielitzki, J.,Clayton, L., Donovan, J., Kohn, D., Lipman, N., Locke, P., Melcher, J., Quimby, F., Turner, P., Wood, G., Wurbel, H. (2011). Guide for the Care and Use of Laboratory Animals. National Research Council, 8. Retrieved from American Association of Laboratory Animal Sciences.

Luchins, K., Baker, K., Gilbert, M., Blanchard, J., & Rudolf, B. (2011). Manzanita wood: A sanitizable enrichment option for nonhuman primates. Journal of the American Association Laboratory Animal Science, 50 (6), 884–887. Retrieved from PubMed.

Shively, C. A., Clarkson, T. B., & Kaplan, J. R. (1989). Social deprivation and coronary artery atherosclerosis in female cynomolgus monkeys. Atherosclerosis, 77, 69-76.

Simonson, C. J., Salonvaara, M., & Ojanen, T. (2002). The effect of structures on indoor humidity possibility to improve comfort and perceived air quality. Indoor Air, 12(4), 243-251.

Thom, J., & Crockett, C. (2008). Managing environmental enhancement plans for individual research projects at a national primate research center. Journal of the American Association Laboratory Animal Science, 47 (3), 51–57. Retrieved from PubMed.

Reinhardt, V. and Reinhardt, A. (2008). Environmental enrichment and refinement for nonhuman primates kept in research laboratories: a photographic documentation and literature review. Washington (DC): Animal Welfare Institute. 1-10.

Reinhardt, V., Houser, W.D., Cowley, D., Champoux, M. (1987). Preliminary comments on environmental enrichment with branches for individually caged rhesus monkeys. Labrotary Primate News, 26, 1–3.

United States Department of Agriculture (1991). Animal Welfare; Standards; Final Rule. Federal Register 56(32), 6426-6505.

Valdmanis, R. (2013, December 18). Harvard fined $24,000 for animal mistreatment after monkeys die. Retrieved December 3, 2014, from http://www.reuters.com/article/2013/12/18/us-usa-harvard-monkeys-idUSBRE9BH11120131218

 

 

Environmentally Sustainable Buildings

Tim Bemis Building Construction Technology

Katherine Sholl Animal Science

Steven Barscz Natural Resource Conservation

Imagine looking up at the sky and spotting a Peregrine Falcon soaring through the air, looking for prey among a group of pigeons. In a blink of an eye, the falcon dive-bombs towards its prey at speeds of over 200 mph, making it the fastest animal on earth.  Before you know it the falcon has grabbed the pigeon. Could you imagine if this animal went extinct?  At one point these falcons almost became extinct in New England due to DDT issues, but thanks to conservation efforts and accommodations the Peregrine Falcon was removed from the endangered species list in 1999. One way we’ve accommodated these falcons was by providing an indirect perch on tall, thin buildings, such as the library at UMass. However, the latest trend is that short and widened buildings are being constructed into vacant areas. Unfortunately not much is being done to accommodate the falcon species, nor are many people aware of the effects construction causes if not properly planned for the environment. Most people are unaware that tall buildings are the ideal habitat for the falcon species. In return, it’s proven to also create a better environment for the area it occupies, hence alleviating effects to our often-fragile environment. Now imagine you’re resting near a pond. You see a salamander emerge from the pond. You’re surprised to see that this salamander has six legs. This deformity is caused by pollution runoff going into the water.

Continue Reading

Partial Harvesting in the Northeastern United States

Raina D’Orazio, Pre-Veterinary Medicine

Whitney Comeau, Animal Sciences

William Rueda, Building and Construction Technology

Chloe Rutkowski, Building and Construction Technology

[Untitled Diagrams of Clearcutting and Partial-Harvesting]. Retrieved November 10, 2014, from: http://www.nrs.fs.fed.us/fmg/nfmg/fm101/silv/index.htm

[Untitled Diagrams of Clearcutting and Partial-Harvesting]. Retrieved November 10, 2014, from: http://www.nrs.fs.fed.us/fmg/nfmg/fm101/silv/index.htm

Introduction

You wouldn’t expect to walk into a health food restaurant and be served a salad with no organic ingredients. The means would not be consistent with the ends, and you would distrust the company. A health food restaurant validates its interests in its consumer’s dietary choices by using organic ingredients in its dishes. Similarly, any company that markets its products to clients with certain values needs to make itself credible by creating its product in a manner that reflects the those same values. Here, sustainable construction is that salad, and sustainable forestry practices are the necessary organic ingredients.  Continue Reading

Sustainable Landscapes and its Benefits

Neil Hourahan- BCT

Nick Kline- NRC

David Gagne

 

 

Intro

In today’s world, the word “sustainability” and “green building” have endless meanings and definitions in people’s minds.  With the two words going hand-in-hand with each other, there are endless parts of a building that are built under the LEED standards that can be considered going green or building sustainable.  Sustainability alone can have to do with our environment, our ecology, or even our economy, and although each help our nation and world in endless ways, sustainability in landscaping incorporates all three into its meaning.  Sustainable landscaping is using the efficient planning of a landscape to help lower energy costs of a building, reduce water runoff, and overall help the performance of the building.  With planners and designers using pervious surfaces and native plants around their buildings for shading and native plants on the roofs of their structures to help lower energy costs and runoff respectively, buildings can help the environment and the inhabitants of the building or structure in many ways.  Landscapes of a building play a much larger role than most people in today’s world believe and can really have a positive overall effect in our future to come.

Continue Reading

Public involvement by Massachusetts’s landowners is a crucial factor in the fight against the hemlock woolly adelgid infestation

Lauren Johnston: Animal Science

Emily Casey: Natural Resources Conservation

Zach Cross: Natural Resources conservation

 

Trees are often seen as the strongest of plants, sort of permanent structures that dominate and decorate our landscapes.  But what if I told you that a small insect was changing that? Would you be skeptical, afraid or both? The hemlock woolly adelgid is an invasive insect running rampant through the Northeast, targeting the dominant canopy tree species of eastern and Canadian hemlocks. Landowners with this infestation on their property experience not only the great loss of these native New England canopy trees, but property damages and value declines when no management efforts are taken. But there is hope! With little time and money investments by private landowners, this infestation can be controlled before its too late to see our hemlocks in abundance again.   Figure 1 exemplifies just a portion of the vast loss of hemlocks in a Pennsylvania forest.

Figure 1 Skeletal remains of hemlocks plagued by HWA infestation shown in the PA forest (http://www.americanforests.org/magazine/article/the-last-of-the-giants/).

Figure 1 Skeletal remains of hemlocks plagued by HWA infestation shown in the PA forest (http://www.americanforests.org/magazine/article/the-last-of-the-giants/).

Continue Reading