Authors
- Winston, Nadia MPH, MSN, RN
- Swanson, Barbara PhD, RN, FAAN
Abstract
Abstract: The purpose of our review was to analyze evidence related to physical activity (PA) and cognitive health in people living with HIV (PLWH), appraise psychometric characteristics of study measures, and calculate effect sizes. A computerized database search of the literature published between 1996 and 2017 was examined for correlational and observational studies that included a sample of PLWH, measured PA, and measured cognitive health. Seven articles met the sampling criteria. Of which, six studies used a cross-sectional design; one used a longitudinal design. All but one found significant positive associations between PA and cognitive health in PLWH. Four studies showed a moderate to high effect for PA on cognitive function (Cohen's d values = 0.45-0.58). None reported sample-specific reliability and validity estimates for PA and cognitive health instruments. PA is a modifiable factor that may delay the onset of cognitive impairment and decline among PLWH.
Article Content
Owing to advances in the efficacy of combination antiretroviral therapy (cART), HIV infection has transitioned from a fatal illness to a chronic, manageable condition that affects an estimated 1.1 million people in the United States (Centers for Disease Control and Prevention, 2019). Although cART has been effective in decreasing HIV-related mortalities, people living with HIV (PLWH) show a higher prevalence of comorbidities compared with their uninfected counterparts (Maciel, Kluck, Durand, & Sprinz, 2018). These comorbidities include cardiovascular disease (Duprez et al., 2012), hypertension (Medina-Torne, Ganesan, Barahona, & Crum-Cianflone, 2012), diabetes (Butt et al., 2009), kidney failure (Winston et al., 2008), and HIV-related cognitive impairment (Watkins & Treisman, 2015).
HIV-related cognitive impairment is of particular concern because it can significantly limit self-care abilities needed to manage HIV infection and its sequelae (Watkins & Treisman, 2015). HIV-related cognitive impairment is associated with chronic systemic inflammation (Saylor & Sacktor, 2016), which has been found to be reduced with physical activity (PA; Jarvie, Whooley, Regan, Sin, & Cohen, 2014). Regular engagement in PA may have protective effects against the onset and progression of HIV-related cognitive impairment. Thus, incorporating PA into HIV treatment plans could improve cognitive health outcomes for PLWH.
Although research has found an association between PA and cognitive function in PLWH, the psychometric properties of the study instruments and effect size findings have not been widely reported (Quigley, O'Brien, Parker, & MacKay-Lyons, 2018), thus limiting conclusions about the strength and validity of the exposure/outcome relationship. Therefore, the purpose of our review was to (a) critically analyze evidence related to PA and cognitive health in HIV infection, (b) appraise psychometric characteristics of study measures, and (c) calculate the effect sizes and advance evidence-based practice and research implications.
Background
HIV-related cognitive impairment, also known as HIV-associated neurocognitive disorder (HAND), is caused by HIV dissemination to the brain with subsequent activation of neurotoxic signaling pathways that alter brain function (Ragin et al., 2015). It is estimated to affect approximately 50% of PLWH (Saylor & Sacktor, 2016) and disproportionately affect African American and Latino PLWH (Mindt et al., 2008; Tedaldi, Minniti, & Fischer, 2015). HAND is associated with deficits in memory, attention span, problem-solving, and reasoning skills and slower speed in performing activities of daily living (Vance, Fazeli, & Gakumo, 2013). Although HAND can affect five cognitive domains (memory, executive function, attention, language and communication, and sensory/motor function), only two domains have to be affected to meet diagnostic criteria for HAND (Vance et al., 2013). Risk factors for HAND are multifactorial, including low CD4+ T-lymphocyte count and depression (Heaton et al., 2010), diabetes (Sanmarti et al., 2014), lower education level (Winston et al., 2013), higher viral load (Saylor & Sacktor, 2016), and older age (Fazeli et al., 2014).
HIV-associated dementia consists of moderate to severe neurocognitive impairment in two or more cognitive domains and typically manifests on neuropsychological testing as difficulty learning new information, decreased information processing, and deficits in attention and concentration (Sanmarti et al., 2014). Although cART has substantially reduced the prevalence of HIV-associated dementia, milder forms of impairment, including mild dysfunction in at least two cognitive domains with and without observable functional impairment, persist (Sanmarti et al., 2014). Despite simpler cART regimens that facilitate adherence, the prevalence of milder forms of HAND has increased, especially among persons older than 50 years (Heaton et al., 2010; Saylor & Sacktor, 2016). This suggests that HAND may partially reflect age-related changes in the brain (Sanmarti et al., 2014).
The pathophysiology of HAND involves the migration of infected macrophages and CD4+ T lymphocytes across the blood-brain barrier, which can result in productive infection of brain cells and persistent inflammation that can lead to neuronal dysfunction and death (Williams et al., 2014). The persistence of inflammation is paradoxical in light of the durable viral suppression that can be achieved with cART (Harezlak et al., 2011) and is of major concern because it has been linked to premature senescence, which can manifest as frailty, decreased immune function, and cognitive impairment (Watkins & Treisman, 2015). Potential explanations include suboptimal immune control of chronic viral infections (e.g., cytomegalovirus and Epstein-Barr virus; Hunt, 2012) and HIV-induced disruption of the gastrointestinal mucosa with subsequent bacterial translocation into the systemic circulation (Ancuta et al., 2008).
Given the prevalence of cognitive impairment and persistent inflammation in HIV infection, the identification of modifiable factors to slow cognitive decline and reduce inflammation is an important public health priority. Of particular importance is the body of evidence that supports pleiotropic effects of PA in uninfected persons, including anti-inflammatory effects (Vella et al., 2017), protection against the development of cognitive impairment in healthy middle-aged and older adults (Pizzie et al., 2014), and slowed progression of cognitive decline in older adults with dementia (Kemoun et al., 2010).
A recent scoping review of cross-sectional studies and randomized clinical trials supported the protective effects of PA on the cognitive health of PLWH (Quigley et al., 2018); however, that review did not report effect sizes, a metric that quantifies differences across studies that use different measures, nor the reliability and validity of the studies' measures. Therefore, the purpose of our review was to critically analyze the evidence related to PA and cognitive health in HIV infection, appraise the psychometric characteristics of the study measures, and calculate the effect sizes.
Methods
An electronic search of the literature was conducted to examine the impact of PA on the cognitive function of PLWH. Using customized keyword strategies (Table 1), the following databases were searched: PubMed, Cumulative Index to Nursing and Allied Health Literature, PsycINFO, and Scopus.
Study Selection
The inclusion criteria for study selection were: (a) sampled PLWH, (b) measured PA, (c) measured cognitive function, (d) peer-reviewed article published between 1996 and 2017, (e) either a nonexperimental descriptive correlational or longitudinal design, and (f) published in English. References of the identified literature were also reviewed for potentially relevant studies. Because our primary purpose was to analyze the exposure-outcome relationship between PA and cognitive function in PLWH, intervention-based studies were excluded. Moreover, including intervention studies would have complicated cross-study comparisons of the calculated effect sizes.
As shown in Figure 1, the search yielded a total of 431 articles. After duplicates were removed using RefWorks software, 319 titles were reviewed for relevance to the inclusion criteria. An additional 236 articles were removed because their titles did not indicate measures of PA and cognitive function. The first two authors independently reviewed the abstracts of the remaining 83 articles and identified 20 that were relevant to the inclusion criteria. Thirteen articles were subsequently excluded because of measurement or design issues, resulting in a final sample of seven articles.
Data Extraction and Synthesis
Study variables were extracted using the Joanna Briggs Systematic Review template (Godfrey & Harrison, 2010) and included: (a) author(s), publication year, and country of origin, (b) study design, (c) sampling criteria, (d) number of participants, (e) participant demographics, (f) PA measures, (g) cognitive function measures, (h) reliability and validity of instruments, (i) results, and (j) conclusions (Tables 2 and 3).
The effect size was extracted from each study or calculated based on the available values in each article (Table 4). For those studies that did not provide the effect size, the Cohen's d statistic was calculated using an effect size calculator developed in Microsoft Excel (DeCoster & Iselin, 2005).
Results
Study Designs and Samples
Tables 2 and 3 summarize data from the seven studies. All the studies were conducted in the United States. Six studies used a cross-sectional design, whereas one used a longitudinal design. Study participants ranged from 20 to 79 years of age. Six of the studies had a sample size equal to or greater than 100 (Dufour et al., 2013, 2018; Fazeli et al., 2014, 2015; Honn, Para, Whitacre, & Bornstein, 1999; Monroe et al., 2017). Two of the studies sampled only men living with HIV (Honn et al., 1999; Monroe et al., 2017), and six of the study samples comprised predominately White participants (Dufour et al., 2013, 2018; Fazeli et al., 2014, 2015; Honn et al., 1999; Monroe et al., 2017). Only one study's sample comprised predominately African Americans (Ortega et al., 2015). All studies included PLWH, and two studies sampled uninfected persons for comparative purposes (Dufour et al., 2018; Monroe et al., 2017). Only one study exclusively sampled older PLWH, and this sample comprised predominately White men between the ages of 50 and 79 years (Fazeli et al., 2015).
Physical Activity Measures
Five studies used an investigator-developed self-report questionnaire to measure the number of minutes participants reported engaging in PA over a specified time period (Dufour et al., 2013, 2018; Fazeli et al., 2014; Honn et al., 1999; Ortega et al., 2015). Two studies used the International Physical Activity Questionnaire to measure participant PA (Fazeli et al., 2015; Monroe et al., 2017). Six studies categorized the PA responses into ordinal categories that classified participants as either reporting or not reporting participation in PA. In six studies, the time frame for measuring PA ranged from 72 hr to 1 year; one study did not specify a time range.
Cognitive Function Measures
All studies used a battery of neuropsychological tests to measure cognitive function. Four of the studies matched cognitive domains with specific neuropsychological tests (Dufour et al., 2013, 2018; Fazeli et al., 2014; Ortega et al., 2015), whereas three studies only reported the specific neuropsychological test (Fazeli et al., 2015; Honn et al., 1999; Monroe et al., 2017). The neuropsychological tests used in all the studies measured cognitive functions commonly affected by HIV, such as verbal fluency, working memory, speed of information processing, verbal and visual learning, delayed recall, executive function, and motor function. Verbal fluency was measured in six of the seven studies (Dufour et al., 2013, 2018; Fazeli et al., 2014, 2015; Honn et al., 1999; Ortega et al., 2015).
Association of Cognitive Function and Physical Activity
A majority (6/7) of the studies found a significant association between PA and cognitive function in PLWH (Dufour et al., 2013, 2018; Fazeli et al., 2014, 2015; Monroe et al., 2017; Ortega et al., 2015). Only one study reported no association between self-reported PA and cognitive function (Honn et al., 1999). One study found that high-level PA participation was associated with slower cognitive decline (Monroe et al., 2017), whereas another found that engaging in multiple positive lifestyle factors contributed to improved overall cognitive performance (Fazeli et al., 2014). Only one study correlated PA with brain imaging and found that those participants who were categorized as "physically active" had larger putamen volumes compared with participants who were categorized as "sedentary" (Ortega et al., 2015).
Effect Size and Reliability/Validity of Measures
Of the seven studies, four showed a moderate to high effect for PA on cognitive function as demonstrated by a Cohen's d value of 0.45-0.58 (Dufour et al., 2013; Fazeli et al., 2014, 2015; Ortega et al., 2015). The average Cohen's d value across studies was ~0.51 (SD = 0.79; Table 4). None of the articles reported reliability and validity data for the PA and cognitive function measures for their samples (Table 3).
Discussion
The purpose of our review was to investigate current scientific evidence regarding the relationship between PA and cognitive health among PLWH by identifying, synthesizing, and critically analyzing existing descriptive studies. We are aware of one other review that focused on examining the relationship between exercise and cognition in PLWH (Quigley et al., 2018), but that was a scoping review that included randomized controlled trials and did not consider effect sizes or the psychometric properties of the study measures. We found seven studies that described the relationship between PA and cognitive function in PLWH. In six of the seven studies, PA was found to have a positive association with cognitive function, with significant associations found for executive and motor function, working memory, and speed of information processing.
Only one study had a sample comprising greater than 50% non-Whites (Ortega et al., 2015), thus limiting the generalizability of our findings to minority populations. This limitation was significant given the disproportionate number of minorities living with HIV and known barriers, such as crime and higher prevalence of chronic health conditions, that limit participation in PA compared with Whites (Mendoza-Vasconez et al., 2016).
Four of the seven studies found a moderate or large effect size for PA on cognitive function. Although this finding was consistent with the large body of literature that supports the protective effect of PA on cognitive function in uninfected adults (Reiner, Niermann, Jekauc, & Woll, 2013), the absence of data to support the psychometric rigor of the PA and cognitive function measures is a concern. Many of the studies' neuropsychological performance measures have been validated in healthy populations, but there are limited data to support the psychometric rigor in PLWH.
The reviewed studies had limitations. All the studies used self-report measures of PA, which have been shown to be characterized by measurement errors related to bias and low levels of reliability and validity (Senso, Anderson, Crain, Sherwood, & Martinson, 2014). In addition, the time frame for PA measurements ranged from 72 hr to 1 year, limiting conclusions about the long-term effects of PA in this population. Many of the studies used investigator-developed questionnaires with unreported psychometric properties, thus limiting interpretation of the findings and translation to clinical practice. The reviewed studies did not measure potential confounding variables, such as dietary intake, which would allow for more precise estimates of the unique variance in cognitive function that is accounted for by PA.
Implications for Nursing Practice and Research
Our findings suggest beneficial effects of PA on the cognitive function of PLWH. Accordingly, we recommend that clinicians incorporate PA assessment into patient intakes. Kaiser Permanente has developed a two-item "exercise vital sign" (EVS) questionnaire that is part of the electronic medical record (Stoutenberg, Shaya, Feldman, & Carroll, 2017). The EVS is converted into minutes of PA/week, thus making it possible for clinicians to assess patient adherence to national PA recommendations (U.S. Department of Health and Human Services, 2018). Written PA prescriptions can be given to patients who do not meet the recommended activity level (Thornton et al., 2016).
Although the extant literature suggests a protective effect of PA on the cognitive function of PLWH, additional descriptive research is needed to inform the development and testing of data-driven interventions to improve cognitive outcomes. These descriptive studies should include minority populations and have adequate statistical power to explicate potential racial differences in the relationship between PA and cognitive function (Barnes et al., 2011). In addition, researchers should use objective measures of PA to reduce bias, incorporate reliability and validity estimates to assess psychometric rigor of cognitive tests in PLWH, and measure potential covariates, such as dietary intake.
Conclusion
Gains in life expectancy for PLWH have been accompanied by concerns about the effects of HIV-related cognitive decline on self-care activities and quality of life. Although our review suggests that PA is associated with higher cognitive performance in PLWH, additional studies that use objective measures of PA are needed to confirm and extend these findings. Clinicians are advised to incorporate patient PA levels into the vital sign assessment and to include written PA prescriptions as part of the treatment plan.
Key Considerations
* PLWH are at increased risk of experiencing cognitive impairment that can negatively affect quality of life and self-care.
* PA has been associated with improved levels of cognitive function in PLWH.
* Minorities have been underrepresented in studies of PA and the cognitive function of PLWH.
* PA should be considered a vital sign and measured at each intake visit.
Disclosures
The authors report no real or perceived vested interests related to this article that could be construed as a conflict of interest.
Editorial note: The second author of this article is an associate editor for the journal. She was not privy to any information regarding this manuscript nor was she involved in any way during the peer review process other than as an author. The editor-in-chief handled the peer review process for this manuscript from receipt in the editorial office, through peer review, to final decision.
Acknowledgments
This study was funded in part by the Rush University Minority Scholarship provided by the Golden Lamp Society at Rush University College of Nursing.
References
Ancuta P., Kamat A., Kunstman K. J., Kim E. -Y., Autissier P., Wurcel A., Gabuzda D. (2008). Microbial translocation is associated with increased monocyte activation and dementia in AIDS patients. PLoS One, 3(6), e2516. doi:10.1371/journal.pone.0002516 [Context Link]
Barnes L. L., Wilson R. S., Hebert L. E., Scherr P. A., Evans D. A., Mendes de Leon C. F. (2011). Racial differences in the association of education with physical and cognitive function in older blacks and whites. The Journals of Gerontology. Series B, Psychological Sciences and Social Sciences, 66(3), 354-363. doi:10.1093/geronb/gbr016 [Context Link]
Butt A. A., McGinnis K., Rodriguez-Barradas M. C., Crystal S., Simberkoff M., Goetz M. B., Justice A. C. (2009). HIV infection and the risk of diabetes mellitus. AIDS, 23(10), 1227-1234. doi:10.1097/QAD.0b013e32832bd7af [Context Link]
Centers for Disease Control and Prevention. (2019). Estimated HIV incidence and prevalence in the United States, 2010-2016. Retrieved from http://www.cdc.gov/hiv/library/reports/hiv-surveillance.html[Context Link]
DeCoster J., Iselin A. M. (2005, November). Effect size calculations. Retrieved from http://www.stat-help.com/spreadsheets.html[Context Link]
Dufour C. A., Marquine M. J., Fazeli P. L., Henry B. L., Ellis R. J., Grant I., Moore D. J. (2013). Physical exercise is associated with less neurocognitive impairment among HIV-infected adults. Journal of Neurovirology, 19(5), 410-417. doi:10.1007/s13365-013-0184-8 [Context Link]
Dufour C. A., Marquine M. J., Fazeli P. L., Umlauf A., Henry B. L., Zlatar Z., Moore D. J. (2018). A longitudinal analysis of the impact of physical activity on neurocognitive functioning among HIV-infected adults. AIDS and Behavior, 22(5), 1562-1572. doi:10.1007/s10461-016-1643-z [Context Link]
Duprez D. A., Neuhaus J., Kuller L. H., Tracy R., Belloso W., De Wit S., Neaton J. D. (2012). Inflammation, coagulation and cardiovascular disease in HIV-infected individuals. PLoS One, 7(9), e44454. doi:10.1371/journal.pone.0044454 [Context Link]
Fazeli P. L., Marquine M. J., Dufour C., Henry B. L., Montoya J., Gouaux B., Moore D. J. (2015). Physical activity is associated with better neurocognitive and everyday functioning among older adults with HIV disease. AIDS and Behavior, 19(8), 1470-1477. doi:10.1007/s10461-015-1024-z [Context Link]
Fazeli P. L., Woods S. P., Heaton R. K., Umlauf A., Gouaux B., Rosario D., Moore D. J. (2014). An active lifestyle is associated with better neurocognitive functioning in adults living with HIV infection. Journal of Neurovirology, 20(3), 233-242. doi:10.1007/s13365-014-0240-z [Context Link]
Godfrey C., Harrison M. (2010). Systematic review resource package. The Joanna Briggs Institute method for systematic review research quick reference guide. Retrieved from http://healthindisasters.com/images/Books/Systematic-Review-Resource-Package.pdf. [Context Link]
Harezlak J., Buchthal S., Taylor M., Schifitto G., Zhong J., Daar E., Navia B. (2011). Persistence of HIV-associated cognitive impairment, inflammation, and neuronal injury in era of highly active antiretroviral treatment. AIDS, 25(5), 625-633. doi:10.1097/QAD.0b013e3283427da7 [Context Link]
Heaton R. K., Clifford D. B., Franklin D. R. Jr., Woods S. P., Ake C., Vaida F., Grant I. (2010). HIV-associated neurocognitive disorders persist in the era of potent antiretroviral therapy: CHARTER Study. Neurology, 75(23), 2087-2096. doi:10.1212/WNL.0b013e318200d727 [Context Link]
Honn V. J., Para M. F., Whitacre C. C., Bornstein R. A. (1999). Effect of exercise on neuropsychological performance in asymptomatic HIV infection. AIDS and Behavior, 3(1), 67-74. doi:10.1023/A:1025471503738 [Context Link]
Hunt P. W. (2012). HIV and inflammation: Mechanisms and consequences. Current HIV/AIDS Reports, 9(2), 139-147. doi:10.1007/s11904-012-0118-8 [Context Link]
Jarvie J. L., Whooley M. A., Regan M. C., Sin N. L., Cohen B. E. (2014). Effect of physical activity level on biomarkers of inflammation and insulin resistance over 5 years in outpatients with coronary heart disease (from the Heart and Soul Study). The American Journal of Cardiology, 114(8), 1192-1197. doi:10.1016/j.amjcard.2014.07.036 [Context Link]
Kemoun G., Thibaud M., Roumagne N., Carette P., Albinet C., Toussaint L., Dugue B. (2010). Effects of a physical training programme on cognitive function and walking efficiency in elderly persons with dementia. Dementia and Geriatric Cognitive Disorders, 29(2), 109-114. doi:10.1159/000272435 [Context Link]
Maciel R. A., Kluck H. M., Durand M., Sprinz E. (2018). Comorbidity is more common and occurs earlier in persons living with HIV than in HIV-uninfected matched controls, aged 50 years and older: A cross-sectional study. International Journal of Infectious Diseases, 70, 30-35. doi:10.1016/j.ijid.2018.02.009 [Context Link]
Medina-Torne S., Ganesan A., Barahona I., Crum-Cianflone N. F. (2012). Hypertension is common among HIV-infected persons, but not associated with HAART. Journal of the International Association of Physicians in AIDS Care: JIAPAC, 11(1), 20-25. doi:10.1177/1545109711418361 [Context Link]
Mendoza-Vasconez A. S., Linke S., Munoz M., Pekmezi D., Ainsworth C., Cano M., Larsen B. A. (2016). Promoting physical activity among underserved populations. Current Sports Medicine Reports, 15(4), 290. doi:10.1249/JSR.0000000000000276 [Context Link]
Mindt M. R., Byrd D., Ryan E. L., Robbins R., Monzones J., Arentoft A., Morgello S. (2008). Characterization and sociocultural predictors of neuropsychological test performance in HIV+ Hispanic individuals. Cultural Diversity & Ethnic Minority Psychology, 14(4), 315-325. doi:10.1037/a0012615 [Context Link]
Moher D., Liberati A., Tetzlaff J., Altman D. G. (2009). Preferred reporting items for systematic reviews and meta-analyses: The PRISMA statement. Annals of Internal Medicine, 151(4), 264-269. doi:10.7326/0003-4819-151-4-200908180-00135 [Context Link]
Monroe A. K., Zhang L., Jacobson L. P., Plankey M. W., Brown T. T., Miller E. N., Sacktor N. C. (2017). The association between physical activity and cognition in men with and without HIV infection. HIV Medicine, 18(8), 555-563. doi:10.1111/hiv.1249 [Context Link]
Ortega M., Baker L. M., Vaida F., Paul R., Basco B., Ances B. M. (2015). Physical activity affects brain integrity in HIV+ individuals. Journal of the International Neuropsychological Society: JINS, 21(10), 880-889. doi:10.1017/S1355617715000879 [Context Link]
Pizzie R., Hindman H., Roe C. M., Head D., Grant E., Morris J. C., Hassenstab J. J. (2014). Physical activity and cognitive trajectories in cognitively normal adults: The adult children study. Alzheimer Disease and Associated Disorders, 28(1), 50-57. doi:10.1097/WAD.0b013e31829628d4 [Context Link]
Quigley A., O'Brien K., Parker R., MacKay-Lyons M. (2018). Exercise and cognitive function in people living with HIV: A scoping review. Disability and Rehabilitation, 41(12), 1-12. doi:10.1080/09638288.2018.1432079 [Context Link]
Ragin A. B., Wu Y., Gao Y., Keating S., Du H., Sammet C., Epstein L. G. (2015). Brain alterations within the first 100 days of HIV infection. Annals of Clinical and Translational Neurology, 2(1), 12-21. doi:10.1002/acn3.136 [Context Link]
Reiner M., Niermann C., Jekauc D., Woll A. (2013). Long-term health benefits of physical activity-a systematic review of longitudinal studies. BMC Public Health, 13, 813. doi:10.1186/1471-2458-13-813 [Context Link]
Sanmarti M., Ibanez L., Huertas S., Badenes D., Dalmau D., Slevin M., Jaen A. (2014). HIV-associated neurocognitive disorders. Journal of Molecular Psychiatry, 2(1), 2. doi:10.1186/2049-9256-2-2 [Context Link]
Saylor D., Sacktor N. (2016). Cognitive impairment among older individuals with HIV infection. Current Geriatrics Reports, 5(2), 63-70. doi:10.1007/s13670-016-0165-x [Context Link]
Senso M. M., Anderson C. P., Crain A. L., Sherwood N. E., Martinson B. C. (2014). Self-reported activity and accelerometry in 2 behavior-maintenance trials. American Journal of Health Behavior, 38(2), 254-264. doi:10.5993/AJHB.38.2.11 [Context Link]
Stoutenberg M., Shaya G. E., Feldman D. I., Carroll J. K. (2017). Practical strategies for assessing patient physical activity levels in primary care. Mayo Clinic Proceedings: Innovations, Quality & Outcomes, 1(1), 8-15. doi:10.1016/j.mayocpiqo.2017.04.006 [Context Link]
Tedaldi E. M., Minniti N. L., Fischer T. (2015). HIV-associated neurocognitive disorders: The relationship of HIV infection with physical and social comorbidities. BioMed Research International, 2015, 641913. doi:10.1155/2015/641913 [Context Link]
Thornton J. S., Fremont P., Khan K., Poirier P., Fowles J., Wells G. D., Frankovich R. J. (2016). Physical activity prescription: A critical opportunity to address a modifiable risk factor for the prevention and management of chronic disease: A position statement by the Canadian Academy of Sport and Exercise Medicine. British Journal of Sports Medicine, 50(18), 1109-1114. doi:10.1136/bjsports-2016-096291 [Context Link]
U.S. Department of Health and Human Services. (2018). Physical activity guidelines for Americans (2nd ed.). Retrieved from https://health.gov/paguidelines/second-edition/pdf/Physical_Activity_Guidelines_[Context Link]
Vance D. E., Fazeli P. L., Gakumo C. A. (2013). The impact of neuropsychological performance on everyday functioning between older and younger adults with and without HIV. The Journal of the Association of Nurses in AIDS Care: JANAC, 24(2), 112-125. doi:10.1016/j.jana.2012.05.002 [Context Link]
Vella C. A., Allison M. A., Cushman M., Jenny N. S., Miles M. P., Larsen B., Blaha M. J. (2017). Physical activity and adiposity-related inflammation: The MESA. Medicine and Science in Sports and Exercise, 49(5), 915-921. doi:10.1249/MSS.0000000000001179 [Context Link]
Watkins C. C., Treisman G. J. (2015). Cognitive impairment in patients with AIDS-prevalence and severity. HIV/AIDS: Research and Palliative Care, 7, 35-47. doi:10.2147/HIV.S39665 [Context Link]
Williams D. W., Veenstra M., Gaskill P. J., Morgello S., Calderon T. M., Berman J. W. (2014). Monocytes mediate HIV neuropathogenesis: Mechanisms that contribute to HIV associated neurocognitive disorders. Current HIV Research, 12(2), 85-96. doi:10.2174/1570162X12666140526114526 [Context Link]
Winston A., Arenas-Pinto A., Stohr W., Fisher M., Orkin C. M., Aderogba K., Leen C. (2013). Neurocognitive function in HIV infected patients on antiretroviral therapy. PLoS One, 8(4), e61949. doi:10.1371/journal.pone.0061949 [Context Link]
Winston J., Deray G., Hawkins T., Szczech L., Wyatt C., Young B. (2008). Kidney disease in patients with HIV infection and AIDS. Clinical Infectious Diseases: An Official Publication of the Infectious Diseases Society of America, 47(11), 1449-1457. doi:10.1086/593099 [Context Link]
For more than 22 additional continuing education articles related to the topic of HIV/AIDS, go to http://NursingCenter.com.
Instructions:
* Read the article on page 268.
* The test for this CE activity can be taken online at http://www.NursingCenter.com. Find the test under the article title. Tests can no longer be mailed or faxed.
* You will need to create a username and password and login to your personal CE Planner account before taking online tests. (It's free!) Your planner will keep track of all your Lippincott Professional Development online CE activities for you.
* There is only one correct answer for each question. A passing score for this test is 13 correct answers. If you pass, you can print your certifi cate of earned contact hours and access the answer key. If you fail, you have the option of taking the test again at no additional cost.
* For questions, contact Lippincott Professional Development: 1-800-787-8985.
Registration Deadline: June 3, 2022
Disclosure Statement: The authors and planners have disclosed that they have no financial relationships related to this article.
Provider Accreditation:
Lippincott Professional Development will award 1.5 contact hours for this continuing nursing education activity.
LPD is accredited as a provider of continuing nursing education by the American Nurses Credentialing Center's Commission on Accreditation.
This activity is also provider approved by the California Board of Registered Nursing, Provider Number CEP 11749 for 1.5 contact hours. LPD is also an approved provider of continuing nursing education by the District of Columbia, Georgia, and Florida. CE Broker #50-1223.
Your certificate is valid in all states.
Payment:
* The registration fee for this test is $9.95 for members and $17.95 for nonmembers.
DOI: 10.1097/JNC.0000000000000172