key: cord-0014297-krsrro3z authors: Lisco, Giuseppe; Giagulli, Vito Angelo; De Tullio, Anna; De Pergola, Giovanni; Guastamacchia, Edoardo; Triggiani, Vincenzo title: Age-Related Male Hypogonadism and Cognitive Impairment in the Elderly: Focus on the Effects of Testosterone Replacement Therapy on Cognition date: 2020-10-16 journal: Geriatrics (Basel) DOI: 10.3390/geriatrics5040076 sha: d655e66b9d531a5d945cec040183d02ef9bcbd81 doc_id: 14297 cord_uid: krsrro3z Background. Epidemiological data report that male hypogonadism may play a role in cognitive impairment in elderly. However, the effect of testosterone replacement therapy (TRT) on cognitive abilities in this cluster of patients has not been well established. Methods. PubMed/MEDLINE, Google Scholar, Cochrane Library, and Web of Science were searched by using free text words and medical subject headings terms related with “male hypogonadism”, “late-onset hypogonadism”, elderly, cognition, “mild cognitive impairment”, memory, “testosterone replacement therapy” used in various combinations according to the specific clinical questions. Original articles, reviews, and randomized controlled trials written in English were selected. Results. A long-term TRT could improve specific cognitive functions, such as verbal and spatial memory, cognitive flexibility, and physical vitality. However, randomized controlled trials do not provide positive results, and in most of the cases TRT might not induce beneficial effects on cognitive function in elderly men. Discussion and conclusions. Since the lengthening of life expectancy, the prevalence rate of cognitive decline in elderly men is expected to increase remarkably over the next decade with considerable healthcare and economical concerns. Therefore, this remains a relevant clinical topic and further investigations are needed for clarifying the role of TRT especially in elderly men with hypogonadism. The term late-onset hypogonadism (LOH) has been introduced to identify a syndrome characterized by both clinical and biochemical evidence of low concentrations of testosterone (T) associated with advancing age in males [1] . Specifically, an aging-related decline in gonadal function has been observed starting from 35 years of age with a more marked decline in the serum concentrations of T after the 7th decade of life [2] . This phenomenon is attributable to several mechanisms, including a progressive decline in the number of normally functioning Leydig cells in aged testicles, lower testicular response to luteinizing hormone (LH), along with a gradual increase in serum concentration of the sex-hormone-binding globulin (SHBG) with a consequent reduction in both serum free and bioavailable T concentrations. In most of the cases, LOH might be the consequence of the use of medications (glucocorticoids, opioid analgesics, antidepressants, or aldosterone antagonists) or chronic diseases [3] [4] [5] [6] [7] [8] [9] . The age-related decline in serum T concentrations has been described in both longitudinal (−1.6%/year) and cross-sectional studies (−0.8%/year) [10] . According to the results of the European Male Aging Study, LOH was diagnosed in 23.3% of participants (mean age 60 years) [11] . A comparative analysis of evidence-based recommendations and guidelines highlighted a significative grade of discordance, thus generating confusion about different issues [12] . First, the best age-specific cutoff value to define the onset of LOH remains equivocal. Moreover, signs and symptoms suggestive of male hypogonadism are heterogeneous, and guidelines and recommendations do not always categorize the level of specificity of these clinical markers, making the diagnostic workup dissimilar in comparable clinical contexts especially in the elderly. Finally, the goal of an optimal T replacement therapy is dissimilar and is often not appropriate for aged men. A routinely assessment of gonadal status in aged men is not recommended, and testing appears appropriate only in the case of highly suspicious patients such as those with sexual dysfunction [13, 14] . However, sexual dysfunction is a very common finding in the elderly and might be related with underlying conditions other than male hypogonadism. Moreover, poor specific signs and symptoms, such as cognitive or mood change, unexplained anemia, loss of muscle bulk and strength, increase of visceral abdominal fat, fatigue, and social isolation, can be frequently associated with male hypogonadism, especially in the elderly, but they are often attributable to other common conditions in this clinical setting, hence, leading to misdiagnosis. According to the Center for Disease Control and Prevention (https://www.cdc.gov/aging/aginginfo/ subjective-cognitive-decline-brief.html), the prevalence of subjective cognitive decline is 11%, more in men (11.3%) than in women (10.6%) and among the elderly (>65y: 11.7%) respective to youngers (45-59y: 10.8%). Cognitive decline may be considered a risk factor for the future development of dementia [15] , but it is usually the result of a physiological cognitive decline associated with aging (cognitive aging), especially in community-dwelling elderly [16] . Patients with a cognitive impairment experienced a decline in several cerebral functions, which are normally necessary to maintain normal daily life routines and daily activities, including memory, language, thinking, and judgment. The so called "mild cognitive impairment" (MCI) is a clinical stage comprised between cognitive aging and a mild dementia and is characterized by a subjective and objective functional decline, which includes memory complaints and abnormal memory for age but without any evidence of decline in cognition, impairment of daily life activities, and dementia [17] . Its estimated that prevalence ranges from 2.5 per 1000 person-year for ages 75-79 years to 60.1 per 1000 person-year for ages > 85 years [18] . Cognitive impairment over time is related with several clinical conditions, which include genetic predisposition, geographical distribution, cardiovascular diseases, education, cigarette smoking, poor physical activities, diabetes mellitus, oxidative-inflammatory status, arterial hypertension, atherosclerosis, atrial fibrillation, vitamin D and vitamin B insufficiency or deficiency, sleep-breathing disorders, longer duration of sleep, metabolic syndrome and type 2 diabetes, psychiatric or neurodegenerative illness, brain injury, and hormonal imbalance (including male hypogonadism) [19] [20] [21] [22] [23] [24] [25] [26] [27] [28] [29] [30] [31] [32] [33] [34] [35] . Androgen receptors have been found in several cerebral areas, such as in the medial preoptic area, ventro-medial hypothalamus, medial amygdala, nucleus accumbens, stria terminalis end septum, and cerebral cortex [36] . Androgen metabolism is particularly active in the brain; T and its active metabolites, such as estradiol and dihydrotestosterone (DHT), play a role in the regulation of brain development [37] . Sexual steroids are known to modulate endothelial function, thus regulating blood flow and vascular inflammation also in brain [38] . In Alzheimer's disease, an overproduction of amylogenic precursors, such as amyloid beta-peptide, and their accumulation in several areas of brain is involved in the pathophysiology of neurodegeneration [39, 40] . T was found to reduce the secretion of amyloid beta-peptide and increase the secretion of the non-amyloidogenic fragment, sbetaAPPalpha, from mouse neuroblastoma cells line (N2a) and rat primary cortico-cerebral neurons, thus demonstrating to positively modulate the intracellular metabolism and protect against Alzheimer's disease evolution [41] . This protective effect exerted by androgens, including T and its metabolites, has been confirmed by other observations [42] [43] [44] [45] . Additionally, patients with Klinefelter syndrome usually display worse verbal processing speed and verbal execution function both associated with an imaging evidence of reduced brain left temporal lobe volume [46] . These neurocognitive outcomes were assumed to be related not only with supernumerary X chromosomes but also with lower concentrations of serum T, frequently observed in this cluster of patients [46] . Moreover, different psychiatric disorders such as schizophrenia, autism, attention-deficit hyperactivity disorder, depression, and anxiety have been frequently reported in individuals with Klinefelter syndrome and testosterone replacement therapy (TRT) usually fails to restore these disorders even when it is prescribed for correcting the underlying hypogonadism [47] . A longitudinal study reported a relationship between T decline over time and decline in cognitive function in men [48, 49] . To confirm a tight correlation between low concentrations of T and cognitive decline, a propensity-score matching analysis demonstrated that the risk of dementia was higher among patients who were prescribed 5 alpha-reductase inhibitors [50] . T decline may affect cognitive processing speed in elderly men even in the case of mild or compensated hypogonadism [51] . Working memory, which is considered as the ability to acquire and maintain information and flexibly manage or update it, should be considered a critical gateway for a broad range of cognitive skills and is normally affected by sexual hormone imbalance in both of genders [52] . Conversely, memory, learning capacity, and cognitive activity are positively modulated by T and its active metabolites as suggested by the evidence of the higher prevalence of these dysfunctions in hypogonadal men [53] . Recent evidence reported that elderly men with hypogonadism are at higher risk of developing neurodegenerative dementia [54] . Given these considerations, TRT could be useful for improving cognition in elderly patients. Despite these evidences, the importance of cognitive and mood declines over time, especially in aged men, could be clinically underestimated. Indeed, not all guidelines considered cognitive impairment as a suggestive item to be considered for diagnosing male hypogonadism and, even if well recognized, neurocognitive signs and symptoms are normally considered as mildly or moderately suggestive for male hypogonadism, especially for LOH [12] . To settle the diagnostic challenges of LOH, validated questionnaires may be useful, but even in this case only a few of these tools considered cognitive symptoms as relevant clinical items, usually exploring favorable mood symptoms (Androgen Deficiency in Aging Males; the Massachusetts Male Aging Study questionnaire; Androtest) [55] [56] [57] [58] . PubMed/MEDLINE, Google Scholar, Cochrane library, and Web of Science were searched by using free text words and medical subject headings terms related with "male hypogonadism", "late-onset hypogonadism", elderly, cognition, "mild cognitive impairment", memory, "testosterone", "testosterone replacement therapy" used in various combinations according to the specific clinical questions. Original articles, reviews, and randomized controlled trials written in English only and published from 2000 to 2020, were selected. Additional filters included male sex and age > 65 years. Randomized controlled trials were selected specifically comparing TRT to placebo. The research focalized about the effect of TRT on age-related cognitive decline and MCI. Several randomized controlled trials have been carried-out in order to explore the effects of TRT on different outcomes related to cognitive functions (Table 1) . Results were normalized on the basis of the education levels of participants. Study designs were different, particularly referring to the age of participants, gonadal status at baseline, and different cognitive impairment at baseline. Moreover, TRT supplementation were differently administered (oral, transdermal, intramuscular) and the exposure to TRT was variable according to the different follow-up strategies. In addition, T supplementations were aimed to achieve and maintain different serum T objectives (low-normal, normal, above the normal range), and methods of assay (radio-and chemiluminescence immune assay; liquid chromatography; liquid chromatography-mass spectrometry) as well as timing of serum T concentrations assessment (random or in the morning) were dissimilar among the different trials. Neurocognitive testing was carried-out, aiming to explore several cerebral areas (such as frontal, pre-frontal, temporal cerebral cortex) involved in the control of memory, verbal fluency, and visuo-spatial recognition. TRT induced a slight but significant amelioration of MMSE score. The amelioration occurred when patients treated with placebo were shifted to T (B) and persisted when those started with T were shifted to P (A). Depression symptoms followed the aforementioned trend. Other outcomes remained unchanged. Age > 60 years (mean 67 years); total T < 300 ng/dL or bioavailable T < 70 ng/dL; MCI 60 patients randomized to (2 × 2 design): vehicle-placebo (16) or T enanthate-placebo (14) or T enanthate-finasteride (17) or vehicle-finasteride (13) Mean change in depression symptoms (GDS); visual-spatial processing (the Trail Making Test A and B, and the Benton Judgment of Line Orientation); psychological well-being (Life Satisfaction Index A and B); recognition and memory performance (the Rey-Osterrieth complex figure test at 0, 5, and 30 min recall test). Hormonal concentrations did not alter cognition. However, free T concentrations were found to be positively related to spatial cognition and estrogen concentrations were negatively related with working memory performance. This pilot study did not find any modifications in cognitive function. Mean change in modified MMSE: temporal and spatial orientations; registration of three words; attention and calculation/mental reversal; three-word recall; language in five components (naming, repeating, following a three-stage command, reading and obeying, and writing); visual construction (copying two pentagons). Assessment were performed at baseline, at 1, 2, 3, and 4 months. DHT seems to slightly impair cognitive function according to the results of the modified MMSE. 17) or P (n = 13). Mean change in: verbal fluency (many words as possible pronounced in 1 min); spatial memory (memorize a route marked in a city map within 2 min); verbal memory (six-paired words were read to the patient and an immediate and delayed recall was carried out to evaluate the number of remembered words); Stroop and mental rotation. Tests were performed at baseline and 5 days after the randomization. An acute administration of T did not provide any relevant improvement or deterioration of the explored cognitive functions. In the Cognitive Functional Trial, 498 patients with an age-associated memory impairment (mean age 72 years; mean serum T concentrations at baseline 242 ng/dL) were randomized (1:1) to receive either T supplementation (gel formulation) aiming to obtain and maintain T concentrations in the normal range for young men or placebo. Even though the subgroup treated with TRT achieved higher concentrations of T compared to those on placebo, visual memory, executive function, and spatial ability did not improve at 6 and 12 months of treatment between the two groups [59] . Similar data were also obtained by the TEAAM trial in which 280 men with LOH and mild cognitive impairment were randomized to receive TRT versus placebo for 36 months. Several aspects of cognition were assessed and compared between the two groups, such as visual spatial ability, verbal fluency, verbal memory, manual dexterity, attention, and executive function after the adjustment for age, baseline cognitive function, and education [60] . Wahjoepramono et al. recruited and analyzed 50 healthy patients with normal cognitive function at baseline (age > 50 years) and a low-to-normal serum T concentrations, founding that TRT compared to placebo lead to a slight improvement of Mini-Mental State Examination (MMSE) testing and lower depressive symptoms assessed by the Geriatric Depression Scale (GDS) [61] . Among hypogonadal men (>60 years) with MCI, TRT per se slightly improved recognition and memory performance and reduced depressive symptoms [64] . Cherrier et al. observed a slight but significative improvement in both verbal and spatial memory assessed in community-dwelling volunteer men supplemented with T enanthate 100 mg once-weekly administrated for 6 weeks compared to placebo [77] . Other trials found that TRT leads to a slight but significative improvement in spatial reasoning performance, physical activity, and vitality as well as in cognitive flexibility, spatial memory, and verbal memory [70, 75, 76] . T metabolites, such as DHT and estradiol, may contribute to these positive effects on some cognitive functions, particularly verbal memory [71] . Despite these results, other authors did not confirm similar findings irrespective of the baseline characteristics of recruited patients, including gonadal status at baseline, formulations used for either a T replacement or supplementation, serum concentrations of T during and after the treatment, period of exposure to T and follow-up strategies [62, 63, 66, 69, [72] [73] [74] 77] . In addition, supraphysiologic T concentrations might prompt detrimental effects especially on verbal memory [67] . Male hypogonadism may be considered as a risk factor for cognitive decline especially in the elderly, and it is attributable to the loss of several neuroprotective effects provided by T at the level of the central nervous system. Moreover, normal levels of serum T seems to prevent cardiometabolic and coagulative disturbances that might be considered as risk factors for cognitive impairment and MCI [79] [80] [81] [82] [83] [84] [85] . Despite these evidences, T supplementation-even in eugonadal men-normally failed to demonstrate protective effects [86] [87] [88] , and the results of the examined trials confirmed this trend. To partially explain this phenomenon, it should be considered that study designs and protocols were different. First, the mean age of participants ranged from 61 years [62] to 80 years [74] ; participants were more than 70 years old in some trials [59, 63, 67, 69, 74, 76] and less than 70 years old in the remaining studies [60, 61, [65] [66] [67] [69] [70] [71] [72] [76] [77] [78] . In one trial [64] , young patients were also included (mean age 28 years). As known, elderly men are more prone to both a baseline cognitive impairment and lower levels of serum T. Indeed, the mean levels of serum T at baseline were lower than 300 ng/dL in trials recruiting older men [59, 63, 66, 68, 73, 75] excepted for one of them [74] . Conversely, the mean levels of serum T in trials recruiting younger patients were greater than 300 ng/dL [60, 61, 64, 65, 67, [69] [70] [71] [72] [76] [77] [78] . Patients with baseline cognition impairment were included in only three trials [59, 63, 73] that recruited patients with a higher mean age (>70 years), and those with subjective memory complaints were included in only one [62] . The remaining trials assessed the effect of TRT in patients with normal cognition levels for age and education in both elderly (mean age > 70 years) [66, 68, 75] and younger patients (mean age < 70 years). Considering that TRT is the most effective treatment for restoring normal levels of serum T in hypogonadal men, it is expected that T supplementation may be more effective in hypogonadal compared to in eugonadal men. For the same fundamental conditions, patients with worse cognition and poor cognitive reserve could benefit from TRT better than those with no cognitive decline or complaints. Despite these assumptions, the results of a clinical trial did not find positive effects of TRT on global cognitive function in elderly patients with cognitive impairment and male hypogonadism [59] . Indeed, Resnik et al. [59] treated similar patients with Testogel 1% 5 mg with further titration to achieve serum T concentrations of 500-800 ng/dL. Patients who were randomized to TRT obtained a moderate increase in serum T levels (500 ng/dL in mean) after 3 months and achieved the target until the 9th month. Even though male hypogonadism was effectively treated, no improvement in cognitive function were found compared to placebo. Cherrier et al. [63] in younger patients (mean age 70 years) with mild cognitive decline, but with normal baseline serum T concentrations (mean T = 308 ng/dL), failed to find cognitive improvement due to TRT. In this case, Testogel posology were strictly titrated (3 months) to achieve and maintain a moderate increase in serum T concentrations to 500-900 ng/dL. Serum T concentrations increased after 3 months and remained stable at 6 months from randomization (650 and 600 ng/dL, respectively). Similar findings were finally found by Kenny et al. [73] in elderly eugonadal men (mean levels of serum T at baseline of 410 ng/dL) with cognitive decline. Patients were started on T enanthate 200 mg i.m. every 3 weeks for 3 months. Serum T concentrations raised up to 1211 ng/dL through the follow-up, hence achieving levels that, to date, we would define as supraphysiologic for age (80 years) . Another cluster of clinical trials focalized on elderly patients (mean age >70 years) with LOH but normal cognition at baseline [66, 68, 73] . Among these trials, only in one [75] , T supplementation induced a mild improvement in physical activity and vitality as well as in cognitive flexibility. In this case, T was administered by means of a transdermal T patch, 2-2.5 g/day for 12 months, obtaining a moderate increase in the levels of serum T. Maki [66] and Vaughan [68] failed to obtain significative improvement in cognitive function. In the former trial, T enanthate 200 mg (i.m.) was administered once-weekly for 90 days in order to achieve supraphysiologic serum T concentrations (T = 249 → 970 ng/dL); in the latter, T enanthate 200 mg was administered every two weeks for 3 years, with or without finasteride 5 mg/day, to achieve moderate increase in serum T levels (T = 286 → 588 ng/dL). Finally, the remaining trials assessed the effect of T on cognitive function in younger men (<70 years) without baseline hypogonadism and without cognitive impairment or complaints [60, 61, 65, 67, [69] [70] [71] [72] 74, 76] . Among these, positive findings were found only in 5 out of 10 trials [61, 67, 70, 74, 76] and consisted in an improvement in spatial memory, spatial ability, and verbal memory. In all of the cases, TRT was administered for significantly improving baseline serum T concentrations by using T gel 50 mg per day for 26 weeks [61] and T enanthate 100 mg (i.m) once a week alone ( [67, 74, 76] , Cherrier M.M. et al. 2007) or in combination with anastrozole 1 mg per day [70] . Despite differences in serum T concentrations at baseline and considering the different formulations administered to replace hypogonadism, neither moderate nor supraphysiologic increases in serum T concentrations were able to improve cognitive function in patients with mild cognitive impairment irrespective of LOH. Possibly, TRT requires a long period of time to efficiently restore cognitive function, as observed in a wide range of clinical trials in which a single shot of transdermal T [78] , as well as a short follow-up period [62, 64] failed to improve cognitive function. Conversely, younger patients with normal cognitive function and without LOH seems to exhibit a slight improvement of spatial abilities and memory. These ameliorations were specifically found in the case of a remarkable T supplementation, while they become negligible in the case of a mild supplementation by means of T gel 1%, T undecanoate 160 mg/d, T enanthate (50-600 mg/w) [60, 65, 69, 71, 72] . Considering these heterogenous study designs and protocols, these positive results on cognition could be the consequences of several biases. In a recently published metanalysis, Buskbjerg et al. extensively evaluated the effect of T supplementation on cognition, finding a great variability in the results [89] . Particularly, different sources of bias have been verified. A poor detailed description of the methods of randomizations and allocation concealment, blinding of participants and researchers, incomplete outcome data reporting, and pharmaceutical sponsoring were found as the main confounding factors. Authors highlighted that statistically significant effects of T supplementation were found among subgroups such as those evaluating eugonadal men at baseline, younger men, studies administering T by injections, non-sponsored trials, and studies assessing random instead of morning T. Despite these findings, the final effect of T supplementation on cognitive function was minimal and statistically insignificant. Probably, T supplementation per se does not improve cognitive function or prevent cognitive decline according to the currently available evidences. In order to explain this result, several observations might be done. Study designs had poor statistical robustness having been conceived for assessing heterogeneous outcomes starting from a usually low number of participants and considering numerous biases in studies protocols. Moreover, in some of the cases, study population did not focalize on the specific issue of male hypogonadism in the elderly. Indeed, in most of the cases, participants had normal or low-normal serum T concentrations and, in this cluster of patients, it is expected that T supplementation (and not replacement) may induce poor or even detrimental systemic effects (including those on cognition). In addition, a few trials assessed the effect of TRT/T supplementation in elderly patients, and in most of the cases participants were younger and therefore less prone to improve cognitive function due to a greater cognitive reserve [90] . This clinical matter remains to be clarified also in light of current guidelines and recommendations that did not specifically established the cutoff of age for the diagnosis of LOH [12] , hence emphasizing the need of an accurate diagnostic workup of male hypogonadism in the elderly (clinical practice) [91] and an adequate study population selection (clinical research) only among those with high probability of having hypogonadism (and consequently in which TRT can be prescribed effectively and safely). Therefore, more studies are needed to better explore the role of hypogonadism in elderly men and the impact of TRT in patients with LOH and cognitive decline. Different T formulations have been used for the supplementation in clinical trials, mostly transdermal or intramuscular, and different T targets have been proposed once TRT was started. According to the clinical practice, TRT in the elderly should be carefully started and managed in order to avoid a detrimental overexposure to T, as well as dangerous fluctuation of serum T concentrations [92] , which are expected to induce side effects more frequently (especially on cognition). According to this point of view, T formulations with a short half-life should be more appropriate for treating elderly men [92] , but this clinical consideration does not have a scientific robust support as head-to-head trials aimed to compare both the efficacy and safety of different T formulations are currently lacking. Besides these considerations, it should be noted that serum T concentrations do not necessarily replicate the concentrations of T in the central nervous system. Martin et al. recently observed that serum and cerebrospinal fluid steroid (including T) concentrations were weakly correlated to each other [93] , thus confirming a difference between peripheral and central concentrations of T. Hence, the improvement of serum T, while patients is started on TRT/T supplementation, could not methodologically be the best biomarker to use in clinical trials, and further studies might be considered also in light of this further variable. Pending further clarification in the field [94, 95] , the main indication for TRT prescription also in elderly men remains the treatment of suggestive symptoms of hypogonadism associated with unequivocally low concentrations of serum T, thus it should not be specifically the aim to improve neurocognitive functions or prevent cognitive decline also in aged men with hypogonadism [96] . However, since the rate of prevalence of cognitive impairment and dementia in elderly is expected to increase remarkably in the next decade, due to the lengthening of life expectancy, this clinical topic is relevant making urgent further study in the field necessary [97] . Characteristics of androgen deficiency in late-onset hypogonadism: Results from the European Male Aging Study (EMAS) Age-specific population centiles for androgen status in men The prevalence of hypertension, hyperlipidemia, diabetes mellitus and depression in men with erectile dysfunction Longitudinal changes in testosterone over five years in community-dwelling men Serum testosterone, dihydrotestosterone and estradiol concentrations in older men self-reporting very good health: The healthy man study Prevalence of low male testosterone concentrations in primary care in Germany: Cross-sectional results from the DETECT study Prevalence, incidence and risk factors of testosterone deficiency in a population-based cohort of men: Results from the study of health in Pomerania Metabolic Disorders and Male Hypogonadotropic Hypogonadism Hypogonadism in the aging male diagnosis, potential benefits, and risks of testosterone replacement therapy Age Trends in the Level of Serum Testosterone and Other Hormones in Middle-Aged Men: Longitudinal Results from the Massachusetts Male Aging Study Characteristics of Secondary, Primary, and Compensated Hypogonadism in Aging Men: Evidence from the European Male Ageing Study Critical evaluation of different available guidelines for late-onset hypogonadism Managing erectile dysfunction in heart failure Erectile dysfunction and testosterone deficiency Age-related cognitive decline, mild cognitive impairment or preclinical Alzheimer's disease? Prevalence of cognitive impairment: Data from the Indianapolis Study of Health and Aging Mild cognitive impairment: Clinical characterization and outcome The incidence of mild cognitive impairment: A systematic review and data synthesis Cohort Profile: The Health In Men Study (HIMS) Association between C-reactive protein and cognitive deficits in elderly men and women: A meta-analysis Metabolic syndrome and longitudinal changes in cognitive function: A systematic review and meta-analysis The Prevalence of Mild Cognitive Impairment in Diverse Geographical and Ethnocultural Regions: The COSMIC Collaboration A Systematic Review and Meta-Analysis of the Effect of Low Vitamin D on Cognition Predicting Risk of Cognitive Decline in Very Old Adults Using Three Models: The Framingham Stroke Risk Profile; the Cardiovascular Risk Factors Age-related cognitive decline and associations with sex, education and apolipoprotein E genotype across ethnocultural groups and geographic regions: A collaborative cohort study Determinants of cognitive performance and decline in 20 diverse ethno-regional groups: A COSMIC collaboration cohort study Anticoagulation in atrial fibrillation and cognitive decline: A systematic review and meta-analysis Association of Blood Pressure Lowering With Incident Dementia or Cognitive Impairment: A Systematic Review and Meta-analysis Investigation of antihypertensive class, dementia, and cognitive decline: A meta-analysis Association of blood lipids, atherosclerosis and statin use with dementia and cognitive impairment after stroke: A systematic review and meta-analysis Effect of Vitamin B Supplementation on Cognitive Function in the Elderly: A Systematic Review and Meta-Analysis Sleep-disordered breathing and the risk of cognitive decline: A meta-analysis of 19,940 participants Korean Meta-Analysis (KORMA) Study Group. Longer Duration of Sleep and Risk of Cognitive Decline: A Meta-Analysis of Observational Studies Focus on the Correlations between Alzheimer's Disease and Type 2 Diabetes Androgen receptors, sex behavior, and aggression Early androgen influences on human neural and behavioural development. Early Hum. Dev Androgen receptor in human endothelial cells An overview of APP processing enzymes and products Metabolic processing of the amyloid precursor protein-New pieces of the Alzheimer's puzzle Testosterone reduces neuronal secretion of Alzheimer's beta-amyloid peptides Protective effects of testosterone on presynaptic terminals against oligomeric β-amyloid peptide in primary culture of hippocampal neurons Protective actions of sex steroid hormones in Alzheimer's disease Androgens regulate neprilysin expression: Role in reducing beta-amyloid concentrations Testosterone improves spatial memory in men with Alzheimer disease and mild cognitive impairment The structural brain correlates of cognitive deficits in adults with Klinefelter's syndrome Longitudinal Relationships between Reproductive Hormones and Cognitive Decline in Older Men: The Concord Health and Ageing in Men Project Hormonal changes and their impact on cognition and mental health of ageing men The risk of dementia with the use of 5 alpha reductase inhibitors Elevated luteinizing hormone despite normal testosterone concentrations in older men-natural history, risk factors and clinical features Sex steroids modify working memory Effects of sex steroid hormones on memory Low Testosterone Level and Risk of Alzheimer's Disease in the Elderly Men: A Systematic Review and Meta-Analysis A new 'aging males' symptoms' rating scale Validation of a screening questionnaire for androgen deficiency in aging males Construction and field validation of a self-administered screener for testosterone de-ficiency (hypogonadism) in ageing men ANDROTEST: A structured interview for the screening of hypogonadism in patients with sexual dysfunction Testosterone Treatment and Cognitive Function in Older Men With Low Testosterone and Age-Associated Memory Impairment Effects of long-term testosterone administration on cognition in older men with low or low-to-normal testosterone concentrations: A prespecified secondary analysis of data from the randomised, double-blind, placebo-controlled TEAAM trial The Effects of Testosterone Supplementation on Cognitive Functioning in Older Men Testosterone replacement therapy in older male subjective memory complainers: Double-blind randomized crossover placebo-controlled clinical trial of physiological assessment and safety Testosterone treatment of men with mild cognitive impairment and low testosterone concentrations Cognition is not modified by large but temporary changes in sex hormones in men Effect of testosterone supplementation on functional mobility, cognition, and other parameters in older men: A randomized controlled trial Intramuscular testosterone treatment in elderly men: Evidence of memory decline and altered brain function Characterization of verbal and spatial memory changes from moderate to supraphysiological increases in serum testosterone in healthy older men Exogenous testosterone alone or with finasteride does not improve measurements of cognition in healthy older men with low serum testosterone Dose-dependent effects of testosterone on sexual function, mood, and visuospatial cognition in older men The role of aromatization in testosterone supplementation: Effects on cognition in older men Effect of oral testosterone undecanoate on visuospatial cognition, mood and quality of life in elderly men with low-normal gonadal status Older men are as responsive as young men to the anabolic effects of graded doses of testosterone on the skeletal muscle Effects of testosterone on behavior, depression, and cognitive function in older men with mild cognitive loss Relationship between testosterone supplementation and insulin-like growth factor-I concentrations and cognition in healthy older men Effects of transdermal testosterone on cognitive function and health perception in older men with low bioavailable testosterone concentrations Testosterone supplementation improves spatial and verbal memory in healthy older men A double-blind, placebo-controlled, randomized clinical trial of transdermal dihydrotestosterone gel on muscular strength, mobility, and quality of life in older men with partial androgen deficiency Testosterone and cognition in elderly men: A single testosterone injection blocks the practice effect in verbal fluency, but has no effect on spatial or verbal memory The Role of Diet and Weight Loss in Improving Secondary Hypogonadism in Men with Obesity with or without Type 2 Diabetes Mellitus Weight loss more than glycemic control may improve testosterone in obese type 2 diabetes mellitus men with hypogonadism Body Composition, and Their Metabolism Based on Sex Is There Room for SERMs or SARMs as Alternative Therapies for Adult Male Hypogonadism? Adding liraglutide to lifestyle changes, metformin and testosterone therapy boosts erectile function in diabetic obese men with overt hypogonadism Testosterone deficiency in male: A risk factor for heart failure Worse progression of COVID-19 in men: Is testosterone a key factor? Andrology 2020 Testosterone Deficiency and Testosterone Treatment in Older Men Serum Testosterone and Cognitive Function in Ageing Male: Updating the Evidence Testosterone Therapy: What We Have Learned From Trials Testosterone Supplementation and Cognitive Functioning in Men-A Systematic Review and Meta-Analysis Effects of two-year testosterone replacement therapy on cognition, emotions and quality of life in young and middle-aged hypogonadal men Hypogonadism: Easy to define, hard to diagnose, and controversial to treat Evidence-based medicine update on testosterone replacement therapy (TRT) in male hypogonadism: Focus on new formulations Weak correlations between serum and cerebrospinal fluid concentrations of estradiol, progesterone and testosterone in males Effects of Testosterone Supplementation on Separate Cognitive Domains in Cognitively Healthy Older Men: A Meta-analysis of Current Randomized Clinical Trials Effects of Testosterone Therapy on Cognitive Function in Aging: A Systematic Review Role of testosterone in cognition and mobility of aging men Testosterone Deficiency and Risk of Cognitive Disorders in Aging Males