Development of an Innovative Career Development Program for Early-Career Women Faculty.

OBJECTIVE: Our institutional Women in Medicine & Science Program (formerly the Office of Women in Medicine and Science) developed the Early Career Development Program for Women to promote the careers of women faculty. At 6 monthly sessions, participants learn relevant content (imposter syndrome, strengths, change style, career management, assertive communication, feedback, personal influence, conflict management, negotiation, importance of mentors, resilience, and self-care); exchange ideas; and expand their professional networks. Here, we report changes in participants' career skills/knowledge, confidence, and perceptions of the current environment after attending the program. METHOD: Between 2014 and 2017, participants (N = 65) completed pre- and post-program surveys that assessed career knowledge and skills, confidence, and perceptions of the current environment and provided program feedback. RESULTS: Most skills showed pre-post significant improvement. The greatest increases occurred in knowing paths to promotion, tailoring communication style, ability to manage conflict, and ability to handle personal-professional role balance. Women reported a significant increase for all items measuring confidence. Among these items, establishing networks, understanding institutional culture, providing feedback, motivating others, strategic planning, delegating, and conflict management had the largest increases. Overall, 89.3% of respondents rated the program impact as very strong/profound, 98.5% rated the concepts as essential, 95.2% rated the skills as essential, and 90.8% rated the sense of community with women in their class as very/extremely close. CONCLUSIONS: Work-related skills/knowledge, confidence, and perceptions of the current environment increased significantly among program participants. These early-career women faculty indicated that the program augmented the skills needed to develop their careers in an academic medical center.

Positive Value of a Women's Junior Faculty Mentoring Program: A Mentor-Mentee Analysis.

BACKGROUND: Recently appointed women faculty in academic medicine face many challenges during their careers and can become overwhelmed managing their multiple faculty roles as teacher, scholar, and clinician, in addition to their roles in personal life. Although a mentor can be invaluable in assisting a woman junior faculty member to adjust to faculty life and providing critical career guidance, not all medical institutions have faculty mentoring programs. We created a mentoring program specifically for our women junior faculty to address this issue at our own institution. MATERIALS AND METHODS: To assess the value of this program, we conducted a novel mentor-mentee paired-data analysis of annual surveys collected from 2010 to 2015. Of the 470 responses received, 83 were from unique mentees and 61 from unique mentors. RESULTS: Career development, research, and promotion were the top topics discussed among the mentoring pairs, followed by discussions of institutional resources and administration/service. There was high congruency among the mentoring pairs that they thought these discussions, as well as other conversations about mentee professional development and well-being, had been helpful. However in some instances, mentors felt they had not been helpful to their mentee, whereas their mentees felt otherwise; this finding speaks to the value and importance of mentees providing positive feedback to their mentors. Overall, both mentees and mentors thought that the mentees had significantly benefited from the mentorship. Unexpected outcomes of these relationships included promotion, grant applications/awards, articles, presentations, and professional memberships. The use of a Mentee Needs Assessment Form to individualize the mentoring relationship for each mentee may explain the high overall satisfaction and participant recommendations of the program. CONCLUSIONS: Our findings demonstrate the value in establishing mentoring programs specifically for women faculty, especially in environments in which other mentoring opportunities do not exist.

Effect of Ovarian Hormone Therapy on Cognition in the Aged Female Rhesus Macaque.

Studies of the effect of hormone therapy on cognitive function in menopausal women have been equivocal, in part due to differences in the type and timing of hormone treatment. Here we cognitively tested aged female rhesus macaques on (1) the delayed response task of spatial working memory, (2) a visuospatial attention task that measured spatially and temporally cued reaction times, and (3) a simple reaction time task as a control for motor speed. After task acquisition, animals were ovariectomized (OVX). Their performance was compared with intact controls for 2 months, at which time no group differences were found. The OVX animals were then assigned to treatment with either a subcutaneous sham implant (OVX), 17-ß estradiol (E) implant (OVX+E) or E implant plus cyclic oral progesterone (OVX+EP). All groups were then tested repeatedly over 12 months. The OVX+E animals performed significantly better on the delayed response task than all of the other groups for much of the 12 month testing period. The OVX+EP animals also showed improved performance in the delayed response task, but only at 30 s delays and with performance levels below that of OVX+E animals. The OVX+E animals also performed significantly better in the visuospatial attention task, particularly in the most challenging invalid cue condition; this difference also was maintained across the 12 month testing period. Simple reaction time was not affected by hormonal manipulation. These data demonstrate that chronic, continuous administration of E can exert multiple beneficial cognitive effects in aged, OVX rhesus macaque females. SIGNIFICANCE STATEMENT: Hormone therapy after menopause is controversial. We tested the effects of hormone replacement in aged rhesus macaques, soon after surgically-induced menopause [ovariectomy (OVX)], on tests of memory and attention. Untreated ovarian-intact and OVX animals were compared with OVX animals receiving estradiol (E) alone or E with progesterone (P). E was administered in a continuous fashion via subcutaneous implant, whereas P was administered orally in a cyclic fashion. On both tests, E-treated animals performed better than the other 3 experimental groups across 1 year of treatment. Thus, in this monkey model, chronic E administered soon after the loss of ovarian hormones had long-term benefits for cognitive function.

Why primate models matter.

Research involving nonhuman primates (NHPs) has played a vital role in many of the medical and scientific advances of the past century. NHPs are used because of their similarity to humans in physiology, neuroanatomy, reproduction, development, cognition, and social complexity-yet it is these very similarities that make the use of NHPs in biomedical research a considered decision. As primate researchers, we feel an obligation and responsibility to present the facts concerning why primates are used in various areas of biomedical research. Recent decisions in the United States, including the phasing out of chimpanzees in research by the National Institutes of Health and the pending closure of the New England Primate Research Center, illustrate to us the critical importance of conveying why continued research with primates is needed. Here, we review key areas in biomedicine where primate models have been, and continue to be, essential for advancing fundamental knowledge in biomedical and biological research.

A calorie-restricted diet decreases brain iron accumulation and preserves motor performance in old rhesus monkeys.

Caloric restriction (CR) reduces the pathological effects of aging and extends the lifespan in many species, including nonhuman primates, although the effect on the brain is less well characterized. We used two common indicators of aging, motor performance speed and brain iron deposition measured in vivo using magnetic resonance imaging, to determine the potential effect of CR on elderly rhesus macaques eating restricted (n=24, 13 males, 11 females) and standard (n=17, 8 males, 9 females) diets. Both the CR and control monkeys showed age-related increases in iron concentrations in globus pallidus (GP) and substantia nigra (SN), although the CR group had significantly less iron deposition in the GP, SN, red nucleus, and temporal cortex. A Diet X Age interaction revealed that CR modified age-related brain changes, evidenced as attenuation in the rate of iron accumulation in basal ganglia and parietal, temporal, and perirhinal cortex. Additionally, control monkeys had significantly slower fine motor performance on the Movement Assessment Panel, which was negatively correlated with iron accumulation in left SN and parietal lobe, although CR animals did not show this relationship. Our observations suggest that the CR-induced benefit of reduced iron deposition and preserved motor function may indicate neural protection similar to effects described previously in aging rodent and primate species.

Calorie restriction reduces the influence of glucoregulatory dysfunction on regional brain volume in aged rhesus monkeys.

Insulin signaling dysregulation is related to neural atrophy in hippocampus and other areas affected by neurovascular and neurodegenerative disorders. It is not known if long-term calorie restriction (CR) can ameliorate this relationship through improved insulin signaling or if such an effect might influence task learning and performance. To model this hypothesis, magnetic resonance imaging was conducted on 27 CR and 17 control rhesus monkeys aged 19-31 years from a longitudinal study. Voxel-based regression analyses were used to associate insulin sensitivity with brain volume and microstructure cross-sectionally. Monkey motor assessment panel (mMAP) performance was used as a measure of task performance. CR improved glucoregulation parameters and related indices. Higher insulin sensitivity predicted more gray matter in parietal and frontal cortices across groups. An insulin sensitivity × dietary condition interaction indicated that CR animals had more gray matter in hippocampus and other areas per unit increase relative to controls, suggesting a beneficial effect. Finally, bilateral hippocampal volume adjusted by insulin sensitivity, but not volume itself, was significantly associated with mMAP learning and performance. These results suggest that CR improves glucose regulation and may positively influence specific brain regions and at least motor task performance. Additional studies are warranted to validate these relationships.

Homocysteine, neural atrophy, and the effect of caloric restriction in rhesus monkeys.

Higher serum homocysteine (Hcy) levels in humans are associated with vascular pathology and greater risk for dementia, as well as lower global and regional volumes in frontal lobe and hippocampus. Calorie restriction (CR) in rhesus monkeys (Macaca mulatta) may confer neural protection against age- or Hcy-related vascular pathology. Hcy was collected proximal to a magnetic resonance imaging (MRI) acquisition in aged rhesus monkeys and regressed against volumetric and diffusion tensor imaging indexes using voxel-wise analyses. Higher Hcy was associated with lower white matter volume in pons and corpus callosum. Hcy was correlated with lower gray matter volume and density in prefrontal cortices and striatum. CR did not influence Hcy levels. However, control monkeys exhibited a strong negative correlation between Hcy and global gray matter, whereas no relationship was evident for the CR monkeys. Similar group differences were also seen across modalities in the splenium of the corpus callosum, prefrontal cortices, hippocampus, and somatosensory areas. The data suggest that CR may ameliorate the influence of Hcy on several important age-related parameters of parenchymal health.

Jumpstarting Academic Careers: A Workshop and Tools for Career Development in Anesthesiology.

CONTEXT: Career development is essential and has the potential to assist in building a sustained faculty within academic departments of Anesthesiology. Career development is essential for growth in academic medicine. Close attention to the details involved in career management, goal setting as part of career planning, and professional networking are key elements. METHODS: This article examines the specific educational strategies involved in a 120 minute workshop divided into four 25 minute segments with 20 minutes at the end for discussion for training junior faculty in career development. The teaching methods include 1) brief didactic presentations, 2) pre-workshop completion of two professional development tools, 3) facilitated small group discussion using trained facilitators and 4) use of a commitment to change format. Three major learning tools were utilized in conjunction with the above methods: a professional network survey, a career planning and development form and a commitment to change form. RESULTS: Forty one participants from 2009 reported 80 projected changes in their practice behaviors in relation to career management: Build or enhance professional network and professional mentoring (36.3%); Set career goals, make a plan, follow though, collaborate, publish (35.1%); Increase visibility locally or nationally (10.0%); Building core skills, such as clinical, teaching, leading (36.3%); Identify the criteria for promotion in own institution (5.0%); Improved methods of documentation (2.5%). Over the past two years, the workshop has been very well received by junior faculty, with over 95% marking each of the following items as excellent or good (presentation, content, audiovisuals and objectives met). CONCLUSIONS: The challenge for continuing development and promotion of academic anesthesiologists lies in the explicit training of faculty for career advancement. Designing workshops using educational tools to promote a reflective process of the faculty member is the one method to meet this challenge. We believe that this national workshop has initiated an increasing awareness of a core of junior faculty nationally having now delivered the material to almost 200 junior faculty and having trained seven facilitators in the usage of these materials.

A calorie-restricted diet decreases brain iron accumulation and preserves motor performance in old rhesus monkeys.

Caloric restriction (CR) reduces the pathological effects of aging and extends the lifespan in many species, including nonhuman primates, although the effect on the brain is less well characterized. We used two common indicators of aging, motor performance speed and brain iron deposition measured in vivo using MRI, to determine the potential effect of CR on elderly rhesus macaques eating restricted (n = 24; 13 males, 11 females) and standard diets (n = 17; 8 males, 9 females). Both the CR and control monkeys showed age-related increases in iron concentrations in globus pallidus (GP) and substantia nigra (SN), although the CR group had significantly less iron deposition in the GP, SN, red nucleus, and temporal cortex. A diet x age interaction revealed that CR modified age-related brain changes, evidenced as attenuation in the rate of iron accumulation in basal ganglia and parietal, temporal, and perirhinal cortex. Additionally, control monkeys had significantly slower fine motor performance on the Movement Assessment Panel, which was negatively correlated with iron accumulation in left SN and parietal lobe, although CR animals did not show this relationship. Our observations suggest that the CR-induced benefit of reduced iron deposition and preserved motor function may indicate neural protection similar to effects described previously in aging rodent and primate species.

Executive function and attention are preserved in older surgically menopausal monkeys receiving estrogen or estrogen plus progesterone.

Animal models of menopause have been used to further define the cognitive processes that respond to hormone therapy and to investigate parameters that may influence the cognitive effects of estrogen. Many investigations in animals have focused on memory; however, the effects of hormone therapy on executive function and attention processes have not been well studied. Thus, the purpose of this set of investigations was to assess the effects of estrogen therapy alone or with progesterone on executive and attention processes in middle-aged ovariectomized monkeys. Monkeys were preoperatively trained on a modified version of the Wisconsin card sort task and on a visual cued reaction time task. Hormone therapy was initiated at the time of ovariectomy and cognitive function was reassessed at 2, 12, and 24 weeks postoperatively. Relative to monkeys receiving either of the estrogen therapies, monkeys receiving placebo were impaired in their ability to shift a cognitive set in the Wisconsin card sort task and were impaired in shifting visuospatial attention in the visual cued reaction time task. Our findings are consistent with clinical studies that indicate that hormone therapy can improve executive function and attention processes in postmenopausal women.

Neuroprotective effects of estrogen therapy for cognitive and neurobiological profiles of monkey models of menopause.

Many postmenopausal women question whether to start or continue hormone therapy because of recent clinical trial negative results. However, evidence from other studies of postmenopausal women, and from studies in menopausal monkeys, indicate that estrogen has neurocognitive protective effects, particularly when therapy is initiated close to the time of menopause before neural systems become increasingly compromised with age. In this review, we present studies of menopausal women and female monkeys that support the concept that estrogen therapies protect both cognitive function and neurobiological processes.

Effects of two years of conjugated equine estrogens on cholinergic neurons in young and middle-aged ovariectomized monkeys.

The effect of estrogen on the number and size of cholinergic neurons in the basal forebrain was examined in surgically menopausal young and middle-aged cynomolgus monkeys. Young and middle-aged female monkeys were ovariectomized and treated with conjugated equine estrogens (Premarin) at doses that are equivalent to those currently prescribed to postmenopausal women. In the medial septum/diagonal band (MS/DB), no effect of treatment with Premarin was observed in the cholinergic neurons in either ovariectomized young or middle-aged monkeys. However, the number and size of cholinergic neurons in the MS/DB of middle-aged monkeys was greater than that in the young monkeys. In the nucleus basalis of Meynert (NBM) of middle-aged monkeys, the number of cholinergic neurons in the intermediate region (Ch4i) was greater in Premarin-treated monkeys as compared to controls and numbers of neurons in this region were greater at higher levels of estrogen. No effects of estrogen were observed in other NBM regions in the middle-aged monkeys and the size of cholinergic neurons was unaffected by Premarin. These findings suggest that treatment with Premarin has selective beneficial effects on cholinergic neurons in the basal forebrain but that these effects are both age and region specific.

Hypertrophy and increased kisspeptin gene expression in the hypothalamic infundibular nucleus of postmenopausal women and ovariectomized monkeys.

CONTEXT: Human menopause is characterized by ovarian failure, gonadotropin hypersecretion, and neuronal hypertrophy in the hypothalamic infundibular (arcuate) nucleus. Recent studies have demonstrated a critical role for kisspeptins in reproductive regulation, but it is not known whether menopause is accompanied by changes in hypothalamic kisspeptin neurons. OBJECTIVES: Our objective was to map the location of neurons expressing kisspeptin gene (KiSS-1) transcripts in the human hypothalamus and determine whether menopause is associated with changes in the size and gene expression of kisspeptin neurons. In monkeys, our objective was to evaluate the effects of ovariectomy and hormone replacement on neurons expressing KiSS-1 mRNA in the infundibular nucleus. SUBJECTS: Hypothalamic tissues were collected at autopsy from eight premenopausal and nine postmenopausal women and from 42 young cynomolgus monkeys in various endocrine states. METHODS: We used hybridization histochemistry, quantitative autoradiography, and computer-assisted microscopy. RESULTS: Examination of human hypothalamic sections revealed that KiSS-1 neurons were located predominantly in the infundibular nucleus. In the infundibular nucleus of postmenopausal women, there was a significant increase in the size of neurons expressing KiSS-1 mRNA and the number of labeled cells and autoradiographic grains per neuron. Similar to postmenopausal women, ovariectomy induced neuronal hypertrophy and increased KiSS-1 gene expression in the monkey infundibular nucleus. Conversely, in ovariectomized monkeys, estrogen replacement markedly reduced KiSS-1 gene expression. CONCLUSIONS: The cynomolgus monkey experiments provide strong evidence that the increase in KiSS-1 neuronal size and gene expression in postmenopausal women is secondary to ovarian failure. These studies suggest that kisspeptin neurons regulate estrogen negative feedback in the human.

Mentoring for women and underrepresented minority faculty and students: experience at two institutions of higher education.

Women and minority faculty and students are seriously underrepresented in university and academic healthcare institutions. The role of mentoring has been identified as one of the significant factors in addressing this underrepresentation. We have described the mentoring efforts at two institutions of higher learning in assisting women and minority students and faculty in being accomplished in their academic pursuits. One-hundred-thirty students and >50 women and minority faculty have participated in the mentoring programs described. The number of participants has increased dramatically over the years and continues to evolve positively. These programs appear to be quite successful in the short term. Further evaluation of measurable outcomes will be necessary to fully determine their true impact. The mentoring models for women and underrepresented minority faculty and students at Creighton University Health Sciences Schools and Wake Forest University School of Medicine will serve as a guide for other Health Sciences Schools.

Estrogen modulates cognitive and cholinergic processes in surgically menopausal monkeys.

Estrogen deficiency in postmenopausal women is associated with changes in physiological processes. The extent to which estrogen loss is associated with cognitive changes noted by postmenopausal women has been more difficult to determine for a variety of reasons. Primate models of menopause are now being used to determine the effects of estrogen loss and replacement on cognitive abilities and to investigate the neural mechanisms by which estrogen may influence cognitive function. The present report presents data from cognitive and neurobiological studies in surgically menopausal monkeys that have examined how estrogen loss and replacement may be affecting cognitive abilities and the cholinergic system; a neural system that is known to influence memory and attention function. These studies are indicating that visuospatial attention function is especially sensitive to estrogen states in young monkeys, but that multiple cognitive domains are sensitive to estrogen states in middle-aged monkeys. In addition, anatomical and functional imaging studies indicate that the primate cholinergic system is modulated by estrogen, and pharmacological studies demonstrate that estrogen uses cholinergic muscarinic receptors to influence visuospatial attention. These studies demonstrate that estrogen influences cognitive abilities in monkey models of menopause and the cholinergic system may be one of the mechanisms by which estrogen modulates cognitive function. Given the current unknowns and concerns regarding the use of hormone replacement therapy in postmenopausal women, continued studies in monkey models of menopause are especially needed to further elucidate the effects of estrogen on cognitive and neurobiological processes, with particular emphasis on studies in middle-aged monkeys, determining the optimal aspects of ERT regimens, and identifying the relationships between estrogen effects on cognitive and neurobiological function.

Neuropeptide Y gene expression is increased in the hypothalamus of older women.

Neuropeptide Y (NPY) and proopiomelanocortin (POMC) neurons in the infundibular (arcuate) nucleus of the hypothalamus are part of a reciprocal circuit regulating reproduction and energy balance. Based on studies showing an age-related decrease in POMC mRNA, we hypothesized that NPY gene expression would increase in older women. In situ hybridization was used to compare NPY mRNA levels between young (premenopausal) and older (postmenopausal) women. We also measured NPY gene expression in intact and ovariectomized young cynomolgus monkeys. We report a significant increase ( approximately 100%) in the numbers of autoradiographic grains/NPY neuron in the retrochiasmatic area and infundibular nucleus of older women. NPY mRNA was correlated with subject age and inversely proportional to the number of POMC neurons previously counted in the same subjects. In contrast, there was no difference in hypothalamic NPY mRNA in intact vs. ovariectomized monkeys. These data show that aging in women is associated with increased NPY gene expression and suggest that the functional relationship between NPY and POMC neurons demonstrated in other species also exists in the human. Our studies of intact and ovariectomized monkeys suggest that the increase in NPY mRNA in older women is due to factors other than the ovarian failure of menopause.

Effects of two years of estrogen loss or replacement on nucleus basalis cholinergic neurons and cholinergic fibers to the dorsolateral prefrontal and inferior parietal cortex of monkeys.

The present study examined the long-term (2 years) effects of estrogen loss or estrogen replacement therapy (ERT) on cholinergic neurons in the nucleus basalis of Meynert and on cholinergic fibers in the prefrontal and parietal cortex of adult female cynomolgus monkeys. Cholinergic fiber density in layer II of the prefrontal cortex was decreased in monkeys who were ovariectomized and treated with placebo for 2 years. In contrast, ovariectomized monkeys receiving ERT for 2 years had fiber densities that were comparable to those of intact controls. No differences in parietal cholinergic fiber density or nucleus basalis cholinergic neuron number or volume were found among intact, ovariectomized, or ERT monkeys. Our results suggest that ERT is effective in preventing region-specific changes in cortical cholinergic fibers that result from the loss of circulating ovarian hormones. These modest but appreciable effects on cholinergic neurobiology following long-term estrogen loss and ERT may contribute to changes in visuospatial attention function that is mediated by the prefrontal cortex.

Ovarian steroids differentially modulate the gene expression of gonadotropin-releasing hormone neuronal subtypes in the ovariectomized cynomolgus monkey.

In the present study, we compared the morphology and distribution of neurons expressing GnRH gene transcripts in the hypothalamus and forebrain of the cynomolgus monkey to that of the human. As in the human, three subtypes of GnRH neurons were identified. Type I GnRH neurons were small, oval cells with high levels of gene expression and were located within the basal hypothalamus. Type II GnRH neurons were small and sparsely labeled and were widely scattered in the hypothalamus, midline nuclei of the thalamus, and extended amygdala. Type III neurons displayed magnocellular morphology and intermediate labeling intensity and were located in the nucleus basalis of Meynert, caudate, and amygdala. In a second experiment, we determined the effect of estrogen or estrogen plus progesterone on the gene expression of GnRH neurons in the brains of young, ovariectomized cynomolgus monkeys. We report that hormone treatment resulted in a significant decrease in GnRH mRNA in type I neurons within the basal hypothalamus of ovariectomized monkeys. In contrast, there was no effect of hormone treatment on the gene expression of type III GnRH neurons in the nucleus basalis of Meynert. The present findings provide evidence that the increase in gene expression of type I GnRH neurons in postmenopausal women is secondary to the ovarian failure of menopause. The differential responses of type I and III GnRH neurons to hormone treatment provide additional evidence that distinct subpopulations of neurons expressing GnRH mRNA exist in the primate hypothalamus.

Estrogen and the cholinergic system modulate visuospatial attention in monkeys (Macaca fascicularis).

This study determined the effects of estrogen on attention and motor speed in young monkeys (Macaca fascicularis). Performance on visuospatial attention and reaction time motor tasks was measured before ovariectomy, for 2 months after ovariectomy, and at 14 months after treatment with placebo or estrogen replacement therapy (ERT). Release time on invalid trials in the attention task was increased after ovariectomy and was reduced in monkeys treated with ERT. but not placebo. Simple reaction time was not altered after ovariectomy or treatment. The effects of scopolamine on attention, but not memory, in a delayed response task were dependent on estrogen. These observations indicate that loss of estrogen modulates visuospatial attention in primates and that 1 mechanism of this modulation is through the cholinergic system.