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As a participant in the NOLA Anthropocene Campus, I have gained insights on how communities, stewards, and managers of ecosystems in New Orleans have rolled out forms of interspecies care vis-à-vis ongoing environmental changes, coastal erosion, climate catastrophes and their deeply present and current effects (i.e., the 2010 BP oil disaster). Whilst much analytical lens has been given to geospatial changes in the study of the Anthropocene, here, I focus on how relations to non-human beings, also threatened by the changing tides of NOLA’s waterscapes, can enrich our understanding of such global transformations.

After disasters like Katrina, urban floodwaters harbored many hidden perils in the form of microbes that cause disease. Pathogenic bacterial exposure occurred when wastewater treatment plants and underground sewage got flooded, thus affecting the microbial landscape of New Orleans and increasing the potential of public health risks throughout Southern Louisiana. But one need not wait for a disaster event like Katrina to face these perils. Quotidian activities like decades of human waste and sewage pollution have contaminated public beaches now filled with lurking microbes. Even street puddle waters, such as those found on Bourbon Street, contain unsanitary bacteria level from years of close human exploitation of horses and inadequate drainage in 100-year old thoroughfares. More recently, microbial ecologies have also changed in the Gulf of Mexico due to the harnessing of energy resources like petroleum. Lush habitats for countless species are more and more in danger sounding the bells of extinction for the imperiled southern wild.

Human-alteration has severely damaged the wetland marshes and swamps that would have protected New Orleans from drowning in the water surge that Hurricane Katrina brought from the Gulf of Mexico. The latter is something that lifelong residents (i.e., indigenous coastal groups) of the Mississippi River Mouth have been pointing to for a  long time. Over the past century, the river delta’s “natural” infrastructure has been altered by the leveeing of the Mississippi River. Consequently, much of the silt and sediments that would generally run south and deposit in the river mouth to refeed the delta get siphoned off earlier upstream by various irrigation systems.

While some actors see it as a futile effort, there have been many proposals to restore the Mississippi River Delta. For instance, the aerial planting of mangrove seeds has even been recommended to help protect the struggling marshes and Louisiana’s coastal region. Tierra Resources, a wetland’s restoration company, proposed that bombing Lousiana’s coast with mangrove seeds could save it. Mangrove root systems are especially useful in providing structures to trap sediments and provide habitats for countless species. Additionally, mangroves have been touted as highly efficient species in carbon sequestration, thus taking carbon dioxide out of the biosphere.

Species diffusion into new environments has been of great concern for the different lifeways these soggy localities sustain, whether human or non-human. Many so-called “invasive species” have been identified throughout the river delta by researchers at the Center for Bioenvironmental Research hosted by Tulane and Xavier University. Such species have disrupted local ecological relations and practices and have had profound economic effects. Some plants have even entirely blocked waterways in the swamps and estuaries where salt and freshwater mix. 

Louisiana’s humid subtropical climate, and the diverse ecosystems therein, also warrant attention in that they can incubate some of the world’s deadliest parasites and other microbes. Of particular concern would be some of today's Neglected Tropical Diseases (i.e., Chagas, Cysticercosis, Dengue fever, Leishmaniasis, Schistosomiasis, Trachoma, Toxocariasis, and West Nile virus) often perceived as only affecting tropical regions of Latin America and revealing the enduring legacies of colonial health disparities.

How and when are seemingly quotidian events and upsets understood as not isolated but rather as produced in conjunction with other anthropocenics worldwide? What roles will interspecies relations and forms of care play as we cope with further anthropocenic agitation?

NOLA’s oldest tree, McDonogh Oak in City Park, 800 years old: https://www.youtube.com/watch?v=DK9YoGpng_c&t=0s

Other trees in New Orleans: https://www.atlasobscura.com/things-to-do/new-orleans-louisiana/trees

This policy was innitially well recieved and was quickly ratified by a number of countries with major nuclear capabilities. However after the Fukushima Disaster, this policy and other international policies were percieved by the public to be slow and inefficient in spreading vital information.

This article utilizes excerpts from interviews to illustrate the story narrative of an illness, showing how emotion and values are reflected in the creation of a "plot" of the narrative, and uses statistics and broader research to analize these stories from a broader, more societal perspective. 

The Red Cross opened a Red Cross R&D in 1961 to further existing research on blood component technology, blood safety, plasma-derived therapeutics, transfusion medicine, and biomedical science. Red Cross R&D has made accievements in the following areas, listed on their website:

• Developed a technique to freeze red blood cells, preserving their viability for up to 3 years, helping to ensure a steady supply of red cells for patients needing rare blood types. (1971)
• Contributed to the development of bar-coding for blood products. (1977)
• Developed procedures for large-scale purification of therapeutic blood proteins like gamma globulin and factor VIII. (1978)
• Collaborated with scientists at the Centers for Disease Control and Prevention (CDC) to define the window period—the length of time between infection with the virus and the earliest stage in infection that can be detected by a test—for human immunodeficiency virus (HIV) following implementation of universal HIV testing of donor blood. (1994)
• Investigated the prevalence of blood-transmitted diseases like human T-lymphotropic virus-1 (HTLV-1) and Chagas disease, providing key data that led to implementation of testing for these diseases. (HTLV-1 in 1987, Chagas disease in 2008)
• Continue to facilitate improvements in bacterial testing of blood products.
• Investigated the role of antibodies in female-source plasma in causing transfusion-related acute lung injury (TRALI), leading to reduction in the incidence of TRALI by providing male-predominant plasma for transfusion. (2009)
• Modified height and weight restrictions for donors younger than 19, which has significantly reduced adverse reactions among young donors. (2009)

Based on this article's bibliography, it appears that a large ammount of information from this article was drawn from MSF reports and essays, United Nations reports, and previous scholarly research done in the fields of humanitarianism, feminism, and the social aspects of medicine.