Search tips
Search criteria

Results 1-25 (607557)

Clipboard (0)

Related Articles

1.  Preparing tomorrow's health sciences librarians: feasibility and marketing studies. 
The University of North Carolina at Chapel Hill is devising and evaluating five curricular models designed to improve education for health sciences librarianship. These models fit into a continual learning process from the initial professional preparation to lifelong learning opportunities. Three of them enhance existing degree and certificate programs in the School of Information and Library Science (SILS) with a health sciences specialization, and two are new programs for working information professionals. The approaches involve partnerships among SILS, the Health Sciences Library, and the program in Medical Informatics. The planning process will study the feasibility of the proposed programs, test the marketability of the models to potential students and employers, and make recommendations about implementation.
PMCID: PMC226194  PMID: 8913557
2.  "Current topics in health sciences librarianship": a pilot program for network-based lifelong learning. 
The long-term objective of this project is to make health sciences librarians more effective in their role by using emerging technologies to deliver timely continuing education (CE) programs to them regardless of their physical location. The goals of the one-year planning project at the William H. Welch Medical Library are to plan, implement, and evaluate a pilot CE program that includes (1) a three-day general-interest session organized in four tracks: Market Forces and Management, Information Technology and the Internet, Publishing and Copyright, and Education; (2) a one-day special topic session on the Informatics of the Human Genome Project; and (3) an electronic poster session in parallel with the general-interest session. The program will be offered in three simultaneous formats: (1) on-site, in a distance-learning classroom in Baltimore; (2) as a telecourse, in a similar classroom outside Washington, DC; and (3) online, via the World Wide Web. An electronic proceedings of the entire program will be published on the Web to serve as a continuously available CE resource for health sciences librarians. This paper gives an overview of the planning process, presents a status report on the programmatic and technical implementation of the pilot project at its midpoint, and discusses future directions for the program.
PMCID: PMC226191  PMID: 8913554
3.  A comparative analysis of moral principles and behavioral norms in eight ethical codes relevant to health sciences librarianship, medical informatics, and the health professions 
Based on the authors' shared interest in the interprofessional challenges surrounding health information management, this study explores the degree to which librarians, informatics professionals, and core health professionals in medicine, nursing, and public health share common ethical behavior norms grounded in moral principles.
Using the “Principlism” framework from a widely cited textbook of biomedical ethics, the authors analyze the statements in the ethical codes for associations of librarians (Medical Library Association [MLA], American Library Association, and Special Libraries Association), informatics professionals (American Medical Informatics Association [AMIA] and American Health Information Management Association), and core health professionals (American Medical Association, American Nurses Association, and American Public Health Association). This analysis focuses on whether and how the statements in these eight codes specify core moral norms (Autonomy, Beneficence, Non-Maleficence, and Justice), core behavioral norms (Veracity, Privacy, Confidentiality, and Fidelity), and other norms that are empirically derived from the code statements.
These eight ethical codes share a large number of common behavioral norms based most frequently on the principle of Beneficence, then on Autonomy and Justice, but rarely on Non-Maleficence. The MLA and AMIA codes share the largest number of common behavioral norms, and these two associations also share many norms with the other six associations.
The shared core of behavioral norms among these professions, all grounded in core moral principles, point to many opportunities for building effective interprofessional communication and collaboration regarding the development, management, and use of health information resources and technologies.
PMCID: PMC4188052  PMID: 25349543
4.  Books and other endangered species: an inquiry into the values of medical librarianship. 
Major values of medical librarians, as exemplified in their periodical literature 1903-1977, are identified as "professionalism," "cooperation," "sense of community with health sciences practitioners," and "knowledge orientation." These values are examined in terms of interdisciplinary research into human values. Professionalism is studied in greater depth in relation to criteria on a scale of professionalism. Medical librarians have been most concerned with the criteria of organization, specialized education (with more emphasis on continuing education than on introductory medical library education), and service orientation. Indication of challenge to long-held values exists in the contradictions among certain related assumptions underlying our self-image, our current lack of standards, and changing societal views toward commitment to a single, life-long specialization. It is suggested that there is unexplored potential for support of our traditional values and the development of new ones by comparing them with the value systems of health scientists and educators of health sciences practitioners.
PMCID: PMC199524  PMID: 708952
5.  Are Graduate Students Rational? Evidence from the Market for Biomedical Scientists 
PLoS ONE  2013;8(12):e82759.
The U.S. National Institutes of Health (NIH) budget expansion from 1998 through 2003 increased demand for biomedical research, raising relative wages and total employment in the market for biomedical scientists. However, because research doctorates in biomedical sciences can often take six years or more to complete, the full labor supply response to such changes in market conditions is not immediate, but rather is observed over a period of several years. Economic rational expectations models assume that prospective students anticipate these future changes, and also that students take into account the opportunity costs of their pursuing graduate training. Prior empirical research on student enrollment and degree completions in science and engineering (S&E) fields indicates that “cobweb” expectations prevail: that is, at least in theory, prospective graduate students respond to contemporaneous changes in market wages and employment, but do not forecast further changes that will arise by the time they complete their degrees and enter the labor market. In this article, we analyze time-series data on wages and employment of biomedical scientists versus alternative careers, on completions of S&E bachelor's degrees and biomedical sciences PhDs, and on research expenditures funded both by NIH and by biopharmaceutical firms, to examine the responsiveness of the biomedical sciences labor supply to changes in market conditions. Consistent with previous studies, we find that enrollments and completions in biomedical sciences PhD programs are responsive to market conditions at the time of students' enrollment. More striking, however, is the close correspondence between graduate student enrollments and completions, and changes in availability of NIH-funded traineeships, fellowships, and research assistantships.
PMCID: PMC3871560  PMID: 24376573
6.  Research: the third dimension of librarianship. 
The rapid accumulation of data through increasingly sophisticated computer technology has created an unprecedented information explosion which might better be called an ignorance explosion. Data gathering emphasizing quantity rather than quality, speed of transmission rather than reliability or relevance, poses a challenge to the future of librarianship. Two concerns are discussed: (1) Relationship of technology to the information age. Librarians must be concerned with the methodology used in data collection, including the value judgments reflected in this activity. (2) Preparation of medical librarianship for the future. The profession will grow only as a result of individual effort, the recognition of people, and an appreciation of human values. Thus far, attempts to evaluate needs focus on technology while neglecting research into the human aspect. The author proposes that dimensions of the total professional model for medical librarianship must include research, as well as education and practice. The need to aid in the development of library researchers at the Ph.D. level through a National Library of Medicine program similar to that offered to researchers by the National Institutes of Health is stressed. By way of federal assistance and scholarships made available through national library associations, library research can become the vital and effective third dimension that will redefine the traditional concept of information storage and service in human terms, thus introducing a new relevance into the area of medical librarianship during the coming decades.
PMCID: PMC226407  PMID: 7356492
7.  Fat Dogs and Coughing Horses: K-12 Programming for Veterinary Workforce Development 
Journal of veterinary medical education  2013;40(4):10.3138/jvme.0313-053R.
Workforce development strategies to educate, inform, and diversify the veterinary profession of the future must begin with children in elementary school. This manuscript provides a description of the Fat Dogs and Coughing Horses program, which takes a multifaceted approach toward informing young students, beginning in first grade, about the interesting work and career opportunities available in the field of veterinary medicine. The program, a collaboration among Purdue University and Indiana public schools, is supported by a Science Education Partnership Award from the Office of Research Infrastructure Programs, a component of the National Institutes of Health. The overall goal of the program is to provide formal and informal educational opportunities for students, parents, teachers, and the public about the science involved in keeping people and their animals healthy. Examples of health concerns that impact both people and their pets are used to inform and excite children about careers in the health sciences. The program resulted in (1) curricula for students in grades 1–3, 6, and 9; (2) four children’s books and a set of collectible cards which highlight veterinarians, veterinary technicians, and research scientists who work with animals; and, (3) four traveling museum-grade exhibits. Preliminary assessment data has shown that the implementation of the curricula enhanced student science learning, and science attitudes and interests. The program provides evidence that partnerships among professionals in veterinary medicine and K-12 education can result in impactful workforce development programs.
PMCID: PMC3837546  PMID: 24052417
Workforce development; K-12 education; veterinary medicine; curricula; traveling exhibit; children’s books
8.  Medical Students' Exposure to and Attitudes about the Pharmaceutical Industry: A Systematic Review 
PLoS Medicine  2011;8(5):e1001037.
A systematic review of published studies reveals that undergraduate medical students may experience substantial exposure to pharmaceutical marketing, and that this contact may be associated with positive attitudes about marketing.
The relationship between health professionals and the pharmaceutical industry has become a source of controversy. Physicians' attitudes towards the industry can form early in their careers, but little is known about this key stage of development.
Methods and Findings
We performed a systematic review reported according to PRISMA guidelines to determine the frequency and nature of medical students' exposure to the drug industry, as well as students' attitudes concerning pharmaceutical policy issues. We searched MEDLINE, EMBASE, Web of Science, and ERIC from the earliest available dates through May 2010, as well as bibliographies of selected studies. We sought original studies that reported quantitative or qualitative data about medical students' exposure to pharmaceutical marketing, their attitudes about marketing practices, relationships with industry, and related pharmaceutical policy issues. Studies were separated, where possible, into those that addressed preclinical versus clinical training, and were quality rated using a standard methodology. Thirty-two studies met inclusion criteria. We found that 40%–100% of medical students reported interacting with the pharmaceutical industry. A substantial proportion of students (13%–69%) were reported as believing that gifts from industry influence prescribing. Eight studies reported a correlation between frequency of contact and favorable attitudes toward industry interactions. Students were more approving of gifts to physicians or medical students than to government officials. Certain attitudes appeared to change during medical school, though a time trend was not performed; for example, clinical students (53%–71%) were more likely than preclinical students (29%–62%) to report that promotional information helps educate about new drugs.
Undergraduate medical education provides substantial contact with pharmaceutical marketing, and the extent of such contact is associated with positive attitudes about marketing and skepticism about negative implications of these interactions. These results support future research into the association between exposure and attitudes, as well as any modifiable factors that contribute to attitudinal changes during medical education.
Please see later in the article for the Editors' Summary
Editors' Summary
The complex relationship between health professionals and the pharmaceutical industry has long been a subject of discussion among physicians and policymakers. There is a growing body of evidence that suggests that physicians' interactions with pharmaceutical sales representatives may influence clinical decision making in a way that is not always in the best interests of individual patients, for example, encouraging the use of expensive treatments that have no therapeutic advantage over less costly alternatives. The pharmaceutical industry often uses physician education as a marketing tool, as in the case of Continuing Medical Education courses that are designed to drive prescribing practices.
One reason that physicians may be particularly susceptible to pharmaceutical industry marketing messages is that doctors' attitudes towards the pharmaceutical industry may form early in their careers. The socialization effect of professional schooling is strong, and plays a lasting role in shaping views and behaviors.
Why Was This Study Done?
Recently, particularly in the US, some medical schools have limited students' and faculties' contact with industry, but some have argued that these restrictions are detrimental to students' education. Given the controversy over the pharmaceutical industry's role in undergraduate medical training, consolidating current knowledge in this area may be useful for setting priorities for changes to educational practices. In this study, the researchers systematically examined studies of pharmaceutical industry interactions with medical students and whether such interactions influenced students' views on related topics.
What Did the Researchers Do and Find?
The researchers did a comprehensive literature search using appropriate search terms for all relevant quantitative and qualitative studies published before June 2010. Using strict inclusion criteria, the researchers then selected 48 articles (from 1,603 abstracts) for full review and identified 32 eligible for analysis—giving a total of approximately 9,850 medical students studying at 76 medical schools or hospitals.
Most students had some form of interaction with the pharmaceutical industry but contact increased in the clinical years, with up to 90% of all clinical students receiving some form of educational material. The highest level of exposure occurred in the US. In most studies, the majority of students in their clinical training years found it ethically permissible for medical students to accept gifts from drug manufacturers, while a smaller percentage of preclinical students reported such attitudes. Students justified their entitlement to gifts by citing financial hardship or by asserting that most other students accepted gifts. In addition, although most students believed that education from industry sources is biased, students variably reported that information obtained from industry sources was useful and a valuable part of their education.
Almost two-thirds of students reported that they were immune to bias induced by promotion, gifts, or interactions with sales representatives but also reported that fellow medical students or doctors are influenced by such encounters. Eight studies reported a relationship between exposure to the pharmaceutical industry and positive attitudes about industry interactions and marketing strategies (although not all included supportive statistical data). Finally, student opinions were split on whether physician–industry interactions should be regulated by medical schools or the government.
What Do These Findings Mean?
This analysis shows that students are frequently exposed to pharmaceutical marketing, even in the preclinical years, and that the extent of students' contact with industry is generally associated with positive attitudes about marketing and skepticism towards any negative implications of interactions with industry. Therefore, strategies to educate students about interactions with the pharmaceutical industry should directly address widely held misconceptions about the effects of marketing and other biases that can emerge from industry interactions. But education alone may be insufficient. Institutional policies, such as rules regulating industry interactions, can play an important role in shaping students' attitudes, and interventions that decrease students' contact with industry and eliminate gifts may have a positive effect on building the skills that evidence-based medical practice requires. These changes can help cultivate strong professional values and instill in students a respect for scientific principles and critical evidence review that will later inform clinical decision-making and prescribing practices.
Additional Information
Please access these Web sites via the online version of this summary at
Further information about the influence of the pharmaceutical industry on doctors and medical students can be found at the American Medical Students Association PharmFree campaign and PharmFree Scorecard, Medsin-UKs PharmAware campaign, the nonprofit organization Healthy Skepticism, and the Web site of No Free Lunch.
PMCID: PMC3101205  PMID: 21629685
9.  Linking research to practice: the rise of evidence-based health sciences librarianship* 
The lecture explores the origins of evidence-based practice (EBP) in health sciences librarianship beginning with examples from the work of Janet Doe and past Doe lecturers. Additional sources of evidence are used to document the rise of research and EBP as integral components of our professional work.
Four sources of evidence are used to examine the rise of EBP: (1) a publication by Doe and research-related content in past Doe lectures, (2) research-related word usage in articles in the Bulletin of the Medical Library Association and Journal of the Medical Library Association between 1961 and 2010, (3) Medical Library Association activities, and (4) EBP as an international movement.
These sources of evidence confirm the rise of EBP in health sciences librarianship. International initiatives sparked the rise of evidence-based librarianship and continue to characterize the movement. This review shows the emergence of a unique form of EBP that, although inspired by evidence-based medicine (EBM), has developed its own view of evidence and its application in library and information practice.
Health sciences librarians have played a key role in initiating, nurturing, and spreading EBP in other branches of our profession. Our close association with EBM set the stage for developing our own EBP. While we relied on EBM as a model for our early efforts, we can observe the continuing evolution of our own unique approach to using, creating, and applying evidence from a variety of sources to improve the quality of health information services.
PMCID: PMC3878930  PMID: 24415915
10.  Complementary competencies: public health and health sciences librarianship 
Objectives: The authors sought to identify opportunities for partnership between the communities of public health workers and health sciences librarians.
Methods: The authors review competencies in public health and health sciences librarianship. They highlight previously identified public health informatics competencies and the Medical Library Association's essential areas of knowledge. Based on points of correspondence between the two domains, the authors identify specific opportunities for partnership.
Results: The points of correspondence between public health and health sciences librarianship are reflected in several past projects involving both communities. These previous collaborations and the services provided by health sciences librarians at many public health organizations suggest that some health sciences librarians may be considered full members of the public health workforce. Opportunities remain for productive collaboration between public health workers and health sciences librarians.
Conclusions: Drawing on historical and contemporary experience, this paper presents an initial framework for forming collaborations between health sciences librarians and members of the public health workforce. This framework may stimulate thinking about how to form additional partnerships between members of these two communities.
PMCID: PMC1175799  PMID: 16059423
11.  A Pilot Project in Training for Mental Health Librarianship 
In an effort to recruit and train competent personnel for its medical library, Central Louisiana State Hospital undertook a pilot project in preprofessional training in mental health librarianship. Students received an introduction to the library as it operates in the hospital setting through a survey of the mental health sciences and the needs for library resources and services with special emphasis upon the librarian as a member of the hospital team.
PMCID: PMC198258  PMID: 14271117
12.  Association of Medical Students' Reports of Interactions with the Pharmaceutical and Medical Device Industries and Medical School Policies and Characteristics: A Cross-Sectional Study 
PLoS Medicine  2014;11(10):e1001743.
Aaron Kesselheim and colleagues compared US medical students' survey responses regarding pharmaceutical company interactions with the schools' AMSA PharmFree scorecard and Institute on Medicine as a Profession's (IMAP) scores.
Please see later in the article for the Editors' Summary
Professional societies use metrics to evaluate medical schools' policies regarding interactions of students and faculty with the pharmaceutical and medical device industries. We compared these metrics and determined which US medical schools' industry interaction policies were associated with student behaviors.
Methods and Findings
Using survey responses from a national sample of 1,610 US medical students, we compared their reported industry interactions with their schools' American Medical Student Association (AMSA) PharmFree Scorecard and average Institute on Medicine as a Profession (IMAP) Conflicts of Interest Policy Database score. We used hierarchical logistic regression models to determine the association between policies and students' gift acceptance, interactions with marketing representatives, and perceived adequacy of faculty–industry separation. We adjusted for year in training, medical school size, and level of US National Institutes of Health (NIH) funding. We used LASSO regression models to identify specific policies associated with the outcomes. We found that IMAP and AMSA scores had similar median values (1.75 [interquartile range 1.50–2.00] versus 1.77 [1.50–2.18], adjusted to compare scores on the same scale). Scores on AMSA and IMAP shared policy dimensions were not closely correlated (gift policies, r = 0.28, 95% CI 0.11–0.44; marketing representative access policies, r = 0.51, 95% CI 0.36–0.63). Students from schools with the most stringent industry interaction policies were less likely to report receiving gifts (AMSA score, odds ratio [OR]: 0.37, 95% CI 0.19–0.72; IMAP score, OR 0.45, 95% CI 0.19–1.04) and less likely to interact with marketing representatives (AMSA score, OR 0.33, 95% CI 0.15–0.69; IMAP score, OR 0.37, 95% CI 0.14–0.95) than students from schools with the lowest ranked policy scores. The association became nonsignificant when fully adjusted for NIH funding level, whereas adjusting for year of education, size of school, and publicly versus privately funded school did not alter the association. Policies limiting gifts, meals, and speaking bureaus were associated with students reporting having not received gifts and having not interacted with marketing representatives. Policy dimensions reflecting the regulation of industry involvement in educational activities (e.g., continuing medical education, travel compensation, and scholarships) were associated with perceived separation between faculty and industry. The study is limited by potential for recall bias and the cross-sectional nature of the survey, as school curricula and industry interaction policies may have changed since the time of the survey administration and study analysis.
As medical schools review policies regulating medical students' industry interactions, limitations on receipt of gifts and meals and participation of faculty in speaking bureaus should be emphasized, and policy makers should pay greater attention to less research-intensive institutions.
Please see later in the article for the Editors' Summary
Editors' Summary
Making and selling prescription drugs and medical devices is big business. To promote their products, pharmaceutical and medical device companies build relationships with physicians by providing information on new drugs, by organizing educational meetings and sponsored events, and by giving gifts. Financial relationships begin early in physicians' careers, with companies providing textbooks and other gifts to first-year medical students. In medical school settings, manufacturers may help to inform trainees and physicians about developments in health care, but they also create the potential for harm to patients and health care systems. These interactions may, for example, reduce trainees' and trained physicians' skepticism about potentially misleading promotional claims and may encourage physicians to prescribe new medications, which are often more expensive than similar unbranded (generic) drugs and more likely to be recalled for safety reasons than older drugs. To address these and other concerns about the potential career-long effects of interactions between medical trainees and industry, many teaching hospitals and medical schools have introduced policies to limit such interactions. The development of these policies has been supported by expert professional groups and medical societies, some of which have created scales to evaluate the strength of the implemented industry interaction policies.
Why Was This Study Done?
The impact of policies designed to limit interactions between students and industry on student behavior is unclear, and it is not known which aspects of the policies are most predictive of student behavior. This information is needed to ensure that the policies are working and to identify ways to improve them. Here, the researchers investigate which medical school characteristics and which aspects of industry interaction policies are most predictive of students' reported behaviors and beliefs by comparing information collected in a national survey of US medical students with the strength of their schools' industry interaction policies measured on two scales—the American Medical Student Association (AMSA) PharmFree Scorecard and the Institute on Medicine as a Profession (IMAP) Conflicts of Interest Policy Database.
What Did the Researchers Do and Find?
The researchers compared information about reported gift acceptance, interactions with marketing representatives, and the perceived adequacy of faculty–industry separation collected from 1,610 medical students at 121 US medical schools with AMSA and IMAP scores for the schools evaluated a year earlier. Students at schools with the highest ranked interaction policies based on the AMSA score were 63% less likely to accept gifts as students at the lowest ranked schools. Students at the highest ranked schools based on the IMAP score were about half as likely to accept gifts as students at the lowest ranked schools, although this finding was not statistically significant (it could be a chance finding). Similarly, students at the highest ranked schools were 70% less likely to interact with sales representatives as students at the lowest ranked schools. These associations became statistically nonsignificant after controlling for the amount of research funding each school received from the US National Institutes of Health (NIH). Policies limiting gifts, meals, and being a part of speaking bureaus (where companies pay speakers to present information about the drugs for dinners and other events) were associated with students' reports of receiving no gifts and of non-interaction with sales representatives. Finally, policies regulating industry involvement in educational activities were associated with the perceived separation between faculty and industry, which was regarded as adequate by most of the students at schools with such policies.
What Do These Findings Mean?
These findings suggest that policies designed to limit industry interactions with medical students need to address multiple aspects of these interactions to achieve changes in the behavior and attitudes of trainees, but that policies limiting gifts, meals, and speaking bureaus may be particularly important. These findings also suggest that the level of NIH funding plays an important role in students' self-reported behaviors and their perceptions of industry, possibly because institutions with greater NIH funding have the resources needed to implement effective policies. The accuracy of these findings may be limited by recall bias (students may have reported their experiences inaccurately), and by the possibility that industry interaction policies may have changed in the year that elapsed between policy grading and the student survey. Nevertheless, these findings suggest that limitations on gifts should be emphasized when academic medical centers refine their policies on interactions between medical students and industry and that particular attention should be paid to the design and implementation of policies that regulate industry interactions in institutions with lower levels of NIH funding.
Additional Information
Please access these websites via the online version of this summary at
The UK General Medical Council provides guidance on financial and commercial arrangements and conflicts of interest as part of its good medical practice document, which describes what is required of all registered doctors in the UK
Information about the American Medical Student Association (AMSA) Just Medicine campaign (formerly the PharmFree campaign) and about the AMSA Scorecard is available
Information about the Institute on Medicine as a Profession (IMAP) and about its Conflicts of Interest Policy Database is also available
“Understanding and Responding to Pharmaceutical Promotion: A Practical Guide” is a manual prepared by Health Action International and the World Health Organization that medical schools can use to train students how to recognize and respond to pharmaceutical promotion
The US Institute of Medicine's report “Conflict of Interest in Medical Research, Education, and Practice” recommends steps to identify, limit, and manage conflicts of interest
The ALOSA Foundation provides evidence-based, non-industry-funded education about treating common conditions and using prescription drugs
PMCID: PMC4196737  PMID: 25314155
13.  A current perspective on medical informatics and health sciences librarianship 
Objective: The article offers a current perspective on medical informatics and health sciences librarianship.
Narrative: The authors: (1) discuss how definitions of medical informatics have changed in relation to health sciences librarianship and the broader domain of information science; (2) compare the missions of health sciences librarianship and health sciences informatics, reviewing the characteristics of both disciplines; (3) propose a new definition of health sciences informatics; (4) consider the research agendas of both disciplines and the possibility that they have merged; and (5) conclude with some comments about actions and roles for health sciences librarians to flourish in the biomedical information environment of today and tomorrow.
Summary: Boundaries are disappearing between the sources and types of and uses for health information managed by informaticians and librarians. Definitions of the professional domains of each have been impacted by these changes in information. Evolving definitions reflect the increasingly overlapping research agendas of both disciplines. Professionals in these disciplines are increasingly functioning collaboratively as “boundary spanners,” incorporating human factors that unite technology with health care delivery.
PMCID: PMC1082936  PMID: 15858622
14.  Ethics in health sciences librarianship. 
Against a background of discussion about drafting of an ethical code for librarians and a review of articles confronting ethical issues in librarianship, the authors surveyed the 150 institutional members of the Health Science Librarians of Illinois (HSLI) regarding their perceptions of ethical concerns. Among the issues addressed in the survey are library organization, personnel policies, and professional competency, along with the traditional concerns of professional versus personal values, privacy and confidentiality, access to materials, and materials selection criteria in a health sciences context. Based on a 60% response rate, survey results indicate widespread agreement on some issues and a conspicuous lack of consensus on others. Further research is suggested in order to assess the need for a separate ethical code for health sciences librarians.
PMCID: PMC227753  PMID: 3450346
15.  MLA Certification: The Certification Program and Education for Medical Librarianship * 
The certification program was formally adopted by the Medical Library Association in 1948 in an attempt to establish standards for medical librarians. The program is reviewed, and some of its effects on education for medical librarians are discussed. At the time of its adoption the program defined the kind of education librarians in the field thought necessary for work in medical libraries. New techniques and a shortage of personnel demand consideration of new educational programs, and the Medical Library Assistance Act will provide the means for their establishment. The Association should assume leadership in determining what and where these programs should be and should evaluate its certification and standards programs as often as current needs require.
PMCID: PMC198486  PMID: 6016371
16.  Problem-based learning in a health sciences librarianship course. 
Problem-based learning (PBL) has been adopted by many medical schools in North America. Because problem solving, information seeking, and lifelong learning skills are central to the PBL curriculum, health sciences librarians have been actively involved in the PBL process at these medical schools. The introduction of PBL in a library and information science curriculum may be appropriate to consider at this time. PBL techniques have been incorporated into a health sciences librarianship course at the School of Library and Information Science (LIS) at the University of Wisconsin-Milwaukee to explore the use of this method in an advanced Library and Information Science course. After completion of the course, the use of PBL has been evaluated by the students and the instructor. The modified PBL course design is presented and the perceptions of the students and the instructor are discussed.
PMCID: PMC226380  PMID: 9681169
17.  On the origin of a species: evolution of health sciences librarianship. 
The basic role of the health sciences librarian has not significantly changed throughout history. It has been- and remains-to collect information and organize it for effective use. What has changed is the environment in which this role is carried out and the tools used to accomplish the tasks. Over the one hundred-year history of the evolution of health sciences librarianship, we have used specialty education as the mechanism for differentiating ourselves from other types of librarianship and for acquiring the knowledge and skills to succeed in our profession. Changing conditions require a continual review of our specialty education and a willingness to modify it in order to prepare ourselves for changing environments. A review of specialty education for health sciences librarianship reveals that we have always adapted to new and changing conditions and will continue to do so in the future.
PMCID: PMC226216  PMID: 9028565
18.  Interactions between Non-Physician Clinicians and Industry: A Systematic Review 
PLoS Medicine  2013;10(11):e1001561.
In a systematic review of studies of interactions between non-physician clinicians and industry, Quinn Grundy and colleagues found that many of the issues identified for physicians' industry interactions exist for non-physician clinicians.
Please see later in the article for the Editors' Summary
With increasing restrictions placed on physician–industry interactions, industry marketing may target other health professionals. Recent health policy developments confer even greater importance on the decision making of non-physician clinicians. The purpose of this systematic review is to examine the types and implications of non-physician clinician–industry interactions in clinical practice.
Methods and Findings
We searched MEDLINE and Web of Science from January 1, 1946, through June 24, 2013, according to PRISMA guidelines. Non-physician clinicians eligible for inclusion were: Registered Nurses, nurse prescribers, Physician Assistants, pharmacists, dieticians, and physical or occupational therapists; trainee samples were excluded. Fifteen studies met inclusion criteria. Data were synthesized qualitatively into eight outcome domains: nature and frequency of industry interactions; attitudes toward industry; perceived ethical acceptability of interactions; perceived marketing influence; perceived reliability of industry information; preparation for industry interactions; reactions to industry relations policy; and management of industry interactions. Non-physician clinicians reported interacting with the pharmaceutical and infant formula industries. Clinicians across disciplines met with pharmaceutical representatives regularly and relied on them for practice information. Clinicians frequently received industry “information,” attended sponsored “education,” and acted as distributors for similar materials targeted at patients. Clinicians generally regarded this as an ethical use of industry resources, and felt they could detect “promotion” while benefiting from industry “information.” Free samples were among the most approved and common ways that clinicians interacted with industry. Included studies were observational and of varying methodological rigor; thus, these findings may not be generalizable. This review is, however, the first to our knowledge to provide a descriptive analysis of this literature.
Non-physician clinicians' generally positive attitudes toward industry interactions, despite their recognition of issues related to bias, suggest that industry interactions are normalized in clinical practice across non-physician disciplines. Industry relations policy should address all disciplines and be implemented consistently in order to mitigate conflicts of interest and address such interactions' potential to affect patient care.
Please see later in the article for the Editors' Summary
Editors' Summary
Making and selling health care goods (including drugs and devices) and services is big business. To maximize the profits they make for their shareholders, companies involved in health care build relationships with physicians by providing information on new drugs, organizing educational meetings, providing samples of their products, giving gifts, and holding sponsored events. These relationships help to keep physicians informed about new developments in health care but also create the potential for causing harm to patients and health care systems. These relationships may, for example, result in increased prescription rates of new, heavily marketed medications, which are often more expensive than their generic counterparts (similar unbranded drugs) and that are more likely to be recalled for safety reasons than long-established drugs. They may also affect the provision of health care services. Industry is providing an increasingly large proportion of routine health care services in many countries, so relationships built up with physicians have the potential to influence the commissioning of the services that are central to the treatment and well-being of patients.
Why Was This Study Done?
As a result of concerns about the tension between industry's need to make profits and the ethics underlying professional practice, restrictions are increasingly being placed on physician–industry interactions. In the US, for example, the Physician Payments Sunshine Act now requires US manufacturers of drugs, devices, and medical supplies that participate in federal health care programs to disclose all payments and gifts made to physicians and teaching hospitals. However, other health professionals, including those with authority to prescribe drugs such as pharmacists, Physician Assistants, and nurse practitioners are not covered by this legislation or by similar legislation in other settings, even though the restructuring of health care to prioritize primary care and multidisciplinary care models means that “non-physician clinicians” are becoming more numerous and more involved in decision-making and medication management. In this systematic review (a study that uses predefined criteria to identify all the research on a given topic), the researchers examine the nature and implications of the interactions between non-physician clinicians and industry.
What Did the Researchers Do and Find?
The researchers identified 15 published studies that examined interactions between non-physician clinicians (Registered Nurses, nurse prescribers, midwives, pharmacists, Physician Assistants, and dieticians) and industry (corporations that produce health care goods and services). They extracted the data from 16 publications (representing 15 different studies) and synthesized them qualitatively (combined the data and reached word-based, rather than numerical, conclusions) into eight outcome domains, including the nature and frequency of interactions, non-physician clinicians' attitudes toward industry, and the perceived ethical acceptability of interactions. In the research the authors identified, non-physician clinicians reported frequent interactions with the pharmaceutical and infant formula industries. Most non-physician clinicians met industry representatives regularly, received gifts and samples, and attended educational events or received educational materials (some of which they distributed to patients). In these studies, non-physician clinicians generally regarded these interactions positively and felt they were an ethical and appropriate use of industry resources. Only a minority of non-physician clinicians felt that marketing influenced their own practice, although a larger percentage felt that their colleagues would be influenced. A sizeable proportion of non-physician clinicians questioned the reliability of industry information, but most were confident that they could detect biased information and therefore rated this information as reliable, valuable, or useful.
What Do These Findings Mean?
These and other findings suggest that non-physician clinicians generally have positive attitudes toward industry interactions but recognize issues related to bias and conflict of interest. Because these findings are based on a small number of studies, most of which were undertaken in the US, they may not be generalizable to other countries. Moreover, they provide no quantitative assessment of the interaction between non-physician clinicians and industry and no information about whether industry interactions affect patient care outcomes. Nevertheless, these findings suggest that industry interactions are normalized (seen as standard) in clinical practice across non-physician disciplines. This normalization creates the potential for serious risks to patients and health care systems. The researchers suggest that it may be unrealistic to expect that non-physician clinicians can be taught individually how to interact with industry ethically or how to detect and avert bias, particularly given the ubiquitous nature of marketing and promotional materials. Instead, they suggest, the environment in which non-physician clinicians practice should be structured to mitigate the potentially harmful effects of interactions with industry.
Additional Information
Please access these websites via the online version of this summary at
This study is further discussed in a PLOS Medicine Perspective by James S. Yeh and Aaron S. Kesselheim
The American Medical Association provides guidance for physicians on interactions with pharmaceutical industry representatives, information about the Physician Payments Sunshine Act, and a toolkit for preparing Physician Payments Sunshine Act reports
The International Council of Nurses provides some guidance on industry interactions in its position statement on nurse-industry relations
The UK General Medical Council provides guidance on financial and commercial arrangements and conflicts of interest as part of its good medical practice website, which describes what is required of all registered doctors in the UK
Understanding and Responding to Pharmaceutical Promotion: A Practical Guide is a manual prepared by Health Action International and the World Health Organization that schools of medicine and pharmacy can use to train students how to recognize and respond to pharmaceutical promotion.
The Institute of Medicine's Report on Conflict of Interest in Medical Research, Education, and Practice recommends steps to identify, limit, and manage conflicts of interest
The University of California, San Francisco, Office of Continuing Medical Education offers a course called Marketing of Medicines
PMCID: PMC3841103  PMID: 24302892
19.  Food-based Science Curriculum Increases 4th Graders Multidisciplinary Science Knowledge 
Journal of food science  2013;12(4):81-86.
Health professionals and policymakers are asking educators to place more emphasis on food and nutrition education. Integrating these topics into science curricula using hand-on, food-based activities may strengthen students’ understanding of science concepts. The Food, Math, and Science Teaching Enhancement Resource (FoodMASTER) Initiative is a compilation of programs aimed at using food as a tool to teach mathematics and science. Previous studies have shown that students experiencing the FoodMASTER curriculum were very excited about the activities, became increasingly interested in the subject matter of food, and were able to conduct scientific observations. The purpose of this study was to: 1) assess 4th graders food-related multidisciplinary science knowledge, and 2) compare gains in food-related science knowledge after implementation of an integrated, food-based curriculum. During the 2009–2010 school year, FoodMASTER researchers implemented a hands-on, food-based intermediate curriculum in eighteen 4th grade classrooms in Ohio (n=9) and North Carolina (n=9). Sixteen classrooms in Ohio (n=8) and North Carolina (n=8), following their standard science curricula, served as comparison classrooms. Students completed a researcher-developed science knowledge exam, consisting of 13 multiple-choice questions administered pre- and post-test. Only subjects with pre- and post-test scores were entered into the sample (Intervention n=343; Control n=237). No significant differences were observed between groups at pre-test. At post-test, the intervention group scored (9.95±2.00) significantly higher (p=.000) than the control group (8.84±2.37) on a 13-point scale. These findings suggest the FoodMASTER intermediate curriculum is more effective than a standard science curriculum in increasing students’ multidisciplinary science knowledge related to food.
PMCID: PMC4138830  PMID: 25152539
Education; Food Science; Nutrition Education; Multidisciplinary Science Knowledge; Elementary
20.  Using Basic Science to Develop an Innovative Program in Complementary and Alternative Medicine 
The growing interest in Complementary and Alternative Medicine (CAM) and the increasing incorporation of its modalities in the United States' healthcare system have exposed a number of problems in the field. These include a shortage of qualified CAM providers, scarcity of evidence-based research, lack of trained scientists in the field, and the ubiquitous marketing of frequently uncontrolled CAM products. Thus, the development of a comprehensive and scientifically sound educational infrastructure has become a crucial initial step in redirecting these adverse trends.
With support from the NIH-sponsored curricular CAM initiative, faculty from the department of physiology and biophysics at Georgetown University developed a M.S. program in CAM in 2003. This unique, first of its kind, science-based graduate program offers a master's degree (MS) in physiology with an emphasis on CAM. The CAM-MS degree in physiology is designed to enable students to critically assess various CAM modalities, apply scientific rigor, and carry out evidence-based CAM research. The curriculum includes core science courses and CAM-related classes. Additionally, in order to emphasize the application of academic knowledge and further strengthen problem-solving skills, the students complete an eight-week summer practicum in a professional CAM-related environment.
Here, we report on our innovative and interdisciplinary CAM graduate program where creative teaching is implemented by basic scientists and enhanced by the application of their disciplines in tandem with the clinical expertise of CAM practitioners in the community. Thus, the faculty in the Department of Physiology & Biophysics is developing emerging cross disciplinary areas of study and interest in order to prepare new generations of future physicians, health professionals, educators, and researchers capable of objectively assessing the safety and efficacy of various CAM modalities, and introducing scientific rigor to much needed research into the various aspects of CAM therapies.
PMCID: PMC3019605  PMID: 21243105
Graduate education; Basic science; Complementary and Alternative Medicine
21.  Telemedicine: history, applications, and impact on librarianship. 
This paper traces the uses of telecommunications in health care from the Civil War era to the present. Topics include the National Aeronautics and Space Administration's involvement in the origins of current telemedicine systems and the impact of television. Applications of telemedicine discussed include remote consultation and diagnosis, specialty clinical care (including examples from anesthesia, dermatology, cardiology, psychiatry, radiology, critical care, and oncology), and others (including examples of patient education, home monitoring, and continuing education). The concluding section highlights how telemedicine affects health sciences librarianship, beginning with the development of online computerized literature searching. This section also discusses the medical resources available to health sciences librarians as a result of the Internet.
PMCID: PMC226126  PMID: 8938332
22.  “... And Gladly Teach”: The American Hospital Association's Experience in Conducting Institutes on Hospital Librarianship 
As part of its overall educational program, the American Hospital Association has since 1959 conducted three institutes on hospital librarianship to meet the demand for more competent librarians in medical, nursing school, and patients' libraries. The purpose of such institutes is to teach the basic elements of library science to untrained personnel in hospital libraries.
Discussed are steps in initiating an institute; factors determining length, date, and place; financing; publicity; choice and responsibility of local advisory committee; program content; qualifications of instructors; characteristics of registrants; materials for distribution; evaluations. Details of the most recent institute are outlined. A summary of problems still facing this type of educational program and suggestions for future improvements conclude the paper.
PMCID: PMC198075  PMID: 14119309
23.  Health sciences librarians' awareness and assessment of the Medical Library Association Code of Ethics for Health Sciences Librarianship: the results of a membership survey 
The Medical Library Association (MLA) Board of Directors and president charged an Ethical Awareness Task Force and recommended a survey to determine MLA members' awareness of and opinions about the current Code of Ethics for Health Sciences Librarianship.
The task force and MLA staff crafted a survey to determine: (1) awareness of the MLA code and its provisions, (2) use of the MLA code to resolve professional ethical issues, (3) consultation of other ethical codes or guides, (4) views regarding the relative importance of the eleven MLA code statements, (5) challenges experienced in following any MLA code provisions, and (6) ethical problems not clearly addressed by the code.
Over 500 members responded (similar to previous MLA surveys), and while most were aware of the code, over 30% could not remember when they had last read or thought about it, and nearly half had also referred to other codes or guidelines. The large majority thought that: (1) all code statements were equally important, (2) none were particularly difficult or challenging to follow, and (3) the code covered every ethical challenge encountered in their professional work.
Comments provided by respondents who disagreed with the majority views suggest that the MLA code could usefully include a supplementary guide with practical advice on how to reason through a number of ethically challenging situations that are typically encountered by health sciences librarians.
PMCID: PMC4188053  PMID: 25349544
24.  The health sciences librarian in medical education: a vital pathways project task force 
The Medical Education Task Force of the Task Force on Vital Pathways for Hospital Librarians reviewed current and future roles of health sciences librarians in medical education at the graduate and undergraduate levels and worked with national organizations to integrate library services, education, and staff into the requirements for training medical students and residents.
Standards for medical education accreditation programs were studied, and a literature search was conducted on the topic of the role of the health sciences librarian in medical education.
Expectations for library and information services in current standards were documented, and a draft standard prepared. A comprehensive bibliography on the role of the health sciences librarian in medical education was completed, and an analysis of the services provided by health sciences librarians was created.
An essential role and responsibility of the health sciences librarian will be to provide the health care professional with the skills needed to access, manage, and use library and information resources effectively. Validation and recognition of the health sciences librarian's contributions to medical education by accrediting agencies will be critical. The opportunity lies in health sciences librarians embracing the diverse roles that can be served in this vital activity, regardless of accrediting agency mandates.
PMCID: PMC2759163  PMID: 19851492
25.  Developing a Culture of Research in Vermont: Training and Research Support for Faculty and Students Through Outreach 
The Vermont Genetics Network (VGN) Outreach Core works with undergraduate college faculty throughout the state to implement and integrate cutting edge technology into their curricula and research programs. The opportunities afforded to undergraduates exposed to VGN Outreach activities allow them to gain important skills and encourage them to pursue research careers. The VGN Outreach Core, based at the University of Vermont (UVM) and Norwich University, has utilized the technologies and expertise from the three VGN Core Facilities at UVM – Microarray, Proteomics, and Bioinformatics – to support faculty and student research and to create educational modules.
Through these modules, our team has worked with over 20 faculty and 560 undergraduate students from eight baccalaureate partner institutions (BPIs). Seven of the eight colleges have integrated one or more modules into their curricula and all eight BPIs have reported other changes to curricula that were influenced by VGN Outreach interactions. Results from outreach surveys suggest that our outreach programs influence the educational and career goals of undergraduates. Students report an increased interest in studying science and pursuing a career in science or medicine after participating in VGN educational modules. Further results from the outreach surveys will be discussed.
Additionally, the VGN Outreach Core directly supports faculty and student research. The team works with faculty to enhance their research by bringing research into the classroom, integrating novel experiments into the modules, establishing relationships with the core facilities, offering technical support for project design, and providing extensive bioinformatics support. Core members also work with undergraduate students by serving as technical advisors and/or thesis committee members for independent senior projects and by providing research support. Through all the VGN Programs, a stronger culture of research is being developed at our partner institutes and around the state.
This work was sponsored by Grant Number P20 RR16462, from the IDeA Network of Biomedical Research Excellence (INBRE) Program of the National Institute of General Medical Sciences (NIGMS), a component of the National Institutes of Health (NIH).
PMCID: PMC3635394

Results 1-25 (607557)