The SAGE Encyclopedia of Stem Cell Research. Группа авторов
the digital phenomena of global social networks became widespread, their use as traditional publishing media platforms was still deemed mostly as a limited or negligible channel to engage with the public—and more specifically, interested stakeholders—in a meaningful way. The perceived incapability of social networks as a way of gaining respectful public attention through digital means made it unattractive to people interested in gaining the trust of their constituents and the public at large.
Today, social media platforms comprise a profoundly different medium than it was at their inception. In effect, social media are more engaging, attractive, demanding, and harder to manage than traditional media. As the reach of traditional media channels declines, private and public institutions have opened up to the idea that they must engage differently with parties of interest and adopt innovative channels of communication to connect with their constituents and general public. This has given rise to the phenomenon of social media advocacy. Moreover, during the last decade, as advocate activists, professionals, and organizations increasingly try to satisfy the public preference for more authentic and personalized ways of reaching out, the role of personalized social media connections has become increasingly crucial. Many users have found that social media allow them to build connections and dialogue with other members of their social media networks, especially on topics of mutual interest. The fact that this can be managed both at the local level and worldwide, with access to free translation digital programs, greatly enhances its possibilities for advocacy.
Another benefit of social media is that not only are they user friendly but they also offer the availability of multimedia convergence, and a measurable impact for very little money. Therefore, they constitute a tool that individuals and grassroots organizations can use as effectively as professional advocacy groups. Social media, however, bring with them new responsibilities. Users must be aware of the double-edged impact of publications if they become viral and must exercise extraordinary prudence and care in their publications and interactions. The expansion of social media has brought with it the realization that organizations own a limited amount of social capital, and an error in social media can cause exponential damage.
Trudy M. Mercadal
Florida Atlantic University
See Also: Christopher & Dana Reeve Foundation, The; Cloning, Ethics of; Congress: Votes and Amendments.
Further Readings
Bhattacharya, D. Public Health Policy: Issues, Theories and Advocacy. Hoboken, NJ: Jossey-Bass, 2013.
Hoefer, Richard. Advocacy Practice for Social Justice. Chicago, IL: Lyceum Books, 2011.
Jansson, Bruce R. Improving Healthcare Through Advocacy. A Guide for the Health and Helping Professions. Hoboken, NJ: Wiley, 2011.
Alabama
Alabama
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Alabama
A 2012 Gallup poll found Alabama the most conservative state in the United States, with more than half of those polled self-identifying as conservative. This ideological bent is reflected in the state’s 2014 Healthcare Rights of Conscience Act that gives Alabama health care providers the right to refuse to participate in abortions, human cloning, human embryonic stem cell research, and sterilizations if their objections are submitted in writing and placed on file prior to being asked. Paradoxically, Alabama is also the site of exciting stem cell research and the home of the second-largest biotechnical research park in the nation. Highlighting the work done with adult stem cells has allowed the state’s research institutions to demonstrate that the conservative majority can support stem cell research without violating their principles. The Alabama Medical Institute, an independent, privately funded nonprofit organization, is committed to raising funds for politically riskier work in regenerative medicine and embryonic stem cell research.
The University of Alabama at Birmingham (UAB) is the largest of the state’s seven research universities and the institution most heavily invested in stem cell research. Stem cell biology is a major division of UAB’s biochemistry and structural biology graduate program. Faculty members in the department have particular interests in stem cell self-renewal and lineage specification of adult and pluripotent stem cells. The stem cell biology group at UAB expanded in 2011 when the UAB Stem Cell Institute was established. Also in 2011, UAB acquired from SANYO (now Panasonic Healthcare) the first cell-processing workstation in the United States. The self-contained unit, which has been described as “a clean room in a box,” contains all the necessary equipment required to manufacture cells for cell therapy in a sterile environment.
The unit is used in the stem cell biology group by researchers such as Tim Townes, professor and chair of the department of biochemistry and molecular genetics. Townes developed the first practical animal model for sickle cell disease in 1997. A decade later, he and his team, in collaboration with researchers at the Massachusetts Institute of Technology, took skin cells from mice with sickle cell disease and converted the cells into induced pluripotent stem cells (iPS) and genetically corrected the sickle mutation. They then transformed the corrected iPS cells into bone marrow cells and transplanted them into the diseased mice and cured sickle cell disease in the mouse model.
Other researchers whose work has been enhanced by the cell-processing workstation include Lawrence Lamb, professor of medicine and director of the UAB cell therapy laboratory, and Fred Goldman, professor of pediatrics at UAB and director of the Lowder Blood and Marrow Transplant Program at the Children’s Hospital of Alabama. Lamb’s research has shown that gamma delta T cells, a small component of the immune system, when present in large numbers, will increase survival for patients with leukemia. Goldman’s research uses iPS cells for dyskeratosis, a rare progressive bone marrow failure syndrome, and other nonmalignant blood disorders.
Biotechnology in Alabama
With $4.87 billion in annual research and development expenditures in 2012, Alabama ranks 12th in the nation for research revenue in life sciences and biotechnology, behind both Georgia and North Carolina. Accelerate Alabama, an economic development plan unveiled in January 2012 by the Alabama Department of Commerce, targeted the biosciences industry as an area for growth. According to BioAlabama, in 2014 Alabama had 557 biotech companies providing more than 10,000 jobs with an average salary of $56,000. The city of Birmingham is the home of 122 biotechnology companies as well as the University of Alabama at Birmingham, which includes the main campus of the School of Medicine. UAB conducted nearly 1,500 clinical trials in 2012. Huntsville, home to the world’s fourth-largest research center and the National Space and Aeronautics Administration’s (NASA) Marshall Space Flight Center, is another center of biotechnology in the state.
In 1962, the city of Huntsville, with support from Brown Engineering and rocket pioneer Wernher von Braun, zoned 3,000 acres of land to serve as a research park. Cummings Research Park, with almost 3,500 acres and 285 companies—including aerospace, defense, biotechnology, software development, and information technology—is second only to the Research Triangle Park in North Carolina. HudsonAlpha, a nonprofit institute for biotechnology, anchors the 152-acre biotech campus within the park. The HudsonAlpha Institute for Biotechnology provides research space for the Genome Sequencing Center and Genomic Services Lab, as well as for tissue culture, cell culture, bioscience clean labs, and other projects. In 2012, researchers from HudsonAlpha and from Vanderbilt University identified a special population of intestinal stem cells that respond to damage and help prevent cancer.
In 2013, the Biomedical and Life Sciences team of the CFD Research Corporation, located at the HudsonAlpha Institute for Biotechnology, received a $1 million, two-year Department of Defense contract through the Defense Health Program to fund stem cell detection and sorting research. Kapil Pant, director of biomedical technology for the company, explained that researchers will use induced pluripotent stem cells as a starting point. The hope is that noninvasively determining the differentiation state of stem cells will be a step in using stem cells for advances in treatment