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Alzheimer's disease in the Hispanic/Latino population

March 04, 2023

Alzheimer's disease (AD) in the Hispanic/Latino population is becoming a topic of interest in AD research as Hispanics and Latinos are disproportionately affected by Alzheimer's Disease and underrepresented in clinical research.[1][2] AD is a neurodegenerative disease, characterized by the presence of amyloid-beta plaques and neurofibrillary tangles, that causes memory loss and cognitive decline in its patients.[3] However, pathology and symptoms have been shown to manifest differently in Hispanic/Latinos, as different neuroinflammatory markers are expressed and cognitive decline is more pronounced.[4][5] Additionally, there is a large genetic component of AD, with mutations in the amyloid precursor protein (APP), Apolipoprotein E APOE), presenilin 1 (PSEN1), bridging Integrator 1 (BIN1), SORL1, and Clusterin (CLU) genes increasing one's risk to develop the condition.[6][7][8] However, research has shown these high-risk genes have a different effect on Hispanics and Latinos then they do in other racial and ethnic groups.[9] Additionally, this population experiences higher rates of comorbidities, that increase their risk of developing AD.[9] Hispanics and Latinos also face socioeconomic and cultural factors, such as low income and a language barrier, that affect their ability to engage in clinical trials and receive proper care.[10][2]

Alzheimer's disease

 
A healthy brain (left) and the brain of a late-stage Alzheimer's brain (right)

Alzheimer's disease is the most common form of dementia, accounting for 60% of all cases, and is the sixth leading cause of death in the elderly.[11][12] The disease typically presents itself with intracellular aggregation of hyper-phosphorylated tau, forming neurofibrillary tangles (NFTs), and the extracellular aggregation of amyloid beta (Aβ), forming neuritic plaques.[7] As of 2020, 5.4 million Americans have been diagnosed with Alzheimer's disease, and this number is projected to reach 15-22 million by 2050.[6][10] Hispanics and Latinos account for 55 million of the population and this population is projected to rise to 97 million, accounting for 25% of the U.S. population, in 2050.[10]

Hispanic/Latino population

Hispanics and Latinos make up 18% of the U.S. population, however, they are underrepresented in clinical research.[2][13] The National Institute of Health (NIH) reported that Hispanic and Latinos accounted for less than 8% of reported clinical trial participants.[10] One proposed reason for the lack of representation is that the Hispanic/Latino population includes many people from different countries, and with this diverse background come different characteristics and comorbidities associated with AD.[10] Hispanic and Latinos have a higher prevalence of AD compared to White non-Hispanics.[10][2] Studies estimate that 12% of older Hispanic and Latino adults were diagnosed with AD, the highest proportion compared to all other ethnic groups.[2] Hispanic and Latinos are the fastest-growing population in the U.S., and Hispanic/Latino seniors, those who are 65 and older, are expected to have the largest rise in AD and dementia cases compared to other populations, reaching 3.5 million by 2060.[10] In 2011 the National Alzheimer's Disease Project Act was signed into law.[2] The goal of this act was for The National Institute of Aging to accelerate research and clinical care of patients with AD; this act also has the benefit of seeking to improve the inclusion of underrepresented populations in AD research and clinical trials.[2]

Types

There exist two types of Alzheimer's disease: familial Alzheimer's disease, also called Early-onset Alzheimer's disease (EOAD), and sporadic Alzheimer's Disease, also called Late-onset Alzheimer's Disease (LOAD).[6][14] EOAD is the less common of the two, accounting for 5-10%, and patients with EOAD are typically diagnosed with familial AD before they turn 65 years old.[6][14] LOAD is more common and accounts for 90% of AD cases and its patients experience onset after they turn 65.[12][7] EOAD has been shown to have 2 types of inheritance patterns: mendelian (mEOAD) and non-mendelian (nmEOAD, sporadic) patterns.[6] The three main genes that implicated in familial AD are amyloid precursor protein (APP), Presenilin-1 (PSEN-1), presenilin-2 (PSEN-2).[6][14][7] Onset of sporadic AD has both genetic and environmental risk factors.[14] Some genes of interest in LOAD are the APOE gene, specifically the ApoE4 allele, bridging Integrator 1 (BIN1), SORL1, and clusterin (CLU).[6][7][15][16][8]

Pathology and symptoms

Amyloid beta plaques and neurofibrillary tangles

 
Comparing the formation of the plaques, as a result of neuroinflammation, between wild-type (PP) mice, AD-transgenic mice (3xTgAD), and AD patients. The inflammation-induced accumulation of APP fragments (red) represents the seeding point for the aggregation of Amyloid-beta peptides (green).

Neuritic plaques and neurofibrillary Tangles (NFTs) are the main pathological component of AD.[7][17] Neuritic plaques are composed mainly of the peptide Aβ, but also include other components.[18] APP is processed through either of two pathways, the first is termed the amyloidogenic pathway and produces Aβ.[18] The second pathway is the non-amyloidogenic pathway and does not produce Aβ.[18] In the amyloidogenic pathway, APP (the parent protein) is trafficked to endosomes, cleaved by beta-secretase (BACE), after which it moves back to the cell surface to be cleaved by gamma secretase thus releasing the Aβ peptide.[7][8][17][18] This form of APP processing produces multiple Aβ peptides, of which Aβ40 and Aβ42 peptide are most abundantly produced produced.[7][19] APP can also be cleaved by alpha and gamma-secretase and undergo non-amyloidogenic processing.[17][19] NFTs form when the tau protein, which is involved in microtubule stability, is hyperphosphorylated, dissociates from microtubules and then aggregates with other p-tau monomers forming tau oligomers, fibrils and eventually NFTs.[7] These types of pathologies do not differ across ethnic groups.[7]

Chronic inflammation

Neuroinflammation is another pathological component of AD pathology, and is associated with an increase in levels of inflammatory markers.[7][20] Researchers have also identified many genes linked to immune function that are risk factors for AD, such as TREM2.[20] TREM2 are highly expressed in microglia, the immune cell of the brain, tying the progression of AD with dysfunction in microglial activity.[21]  Neuroinflammation, Aβ and tau pathologies interact in Alzheimer's disease, and their progress can be monitored with biomarkers.[20] For example, studies have found the neuroinflammatory marker YKL-40 in the cerebrospinal fluid (CSF) of AD patients.[16][4] This protein increases years before the onset of AD symptoms and correlates with other neurodegenerative biomarkers, which suggests a potential to predict disease progression.[4] While YKL-40 has not been shown to associate with the APOE -ε4 allele, there is research to link this biomarker to AD in the Hispanic population.[4]

Neurodegeneration

Along with the plaques and inflammation, patients with AD also suffer from neurodegeneration, characterized by loss of neurons and synapses (the communication tool for neurons).[17][7] As a result, the entire brain shrinks in volume (termed brain atrophy), the ventricles grow larger, and the hippocampus and cortex shrink in size.[7][17] As all these pathologies progress, patients begin to experience a decline in memory, cognitive abilities, and independence. The accumulation of neurofibrillary tangles and loss of synaptic fields correlate most closely with cognitive loss.[7]

Mild cognitive impairment

Mild cognitive impairment (MCI) precedes the overt diagnosis of AD.[3][22][23] To be diagnosed with MCI a patient must show memory impairment, a progressive decline in cognitive abilities without presenting symptoms of Parkinson's disease, cerebrovascular diseases, and behavioral or language disorders.[23] Studies show that older Hispanic/Latinos exhibit a higher prevalence of dementia than caucasians.[5][24] Demographic and linguistic factors can prevent a proper MCI diagnosis.[25][26] For instance, subjects for whom English might not be the primary language require use of a translator to perform the cognitive testing, which could affect testing results, but such experimental weaknesses are frequently not described.[25][26]

 
PiB-PET scan of an AD patient (left) compared to an age-matched control (right). Pittsburgh Compound B (PIB) is easily taken up into the brains of AD patients and is used to detect Amyloid beta. Brain regions that are colored red and yellow correspond to a high concentration of PiB, suggesting high amounts of amyloid deposit

Brain imaging

Positron emission tomography (PET) is a brain imaging technique that uses a small amount of radioactive substance, called a tracer, to measure energy use or a specific molecule in different brain regions.[27] In AD research, tracers can be used to detect neuritic plaques (containing Aβ) and tau. Depending on the tracer used, the signal can be used to determine the presence of neuritic plaques and NFTs.[27]

 
The role of genetic mutations in Alzheimer's Disease

Biomarkers

Establishing biomarkers for the early detection of AD is an ongoing are of research because pathological changes occur years before symptoms become apparent.[7][16] Common biomarkers for AD include amyloid beta and hyperphosphorylated tau, both of which can be found in brain tissue and cerebrospinal fluid (CSF).[7] Aβ provides a biomarker of neuritic plaques, which form when APP cleavage results in an increase in the Aβ42/Aβ40 ratio.[7] Hyperphosphorylated tau serves as a biomarker of neurofibrillary tangles (NFTs), with the presence of NFTs indicating a disruption in microtubule stability and neuronal injury.[7] Researchers have begun investigating other markers in the CSF, such as markers of neuronal injury, like Visinin-Like-Protein-1 (VILIP-1), YKL-40, and Neurogranin (NGRN).[16] Due to the low use of CSF sampling in most countries, efforts have been made to study biomarkers in blood.[16] Through work on blood biomarkers, researchers have been able to find proteins that are elevated in AD patients and have predictive potential.[16] The predictive potential of these plasma markers increases further when coupled with the presence of genetic risk factors, such as the APOE E4 allele.[16] Examples of plasma biomarkers include interleukin, TGF, and micro-RNA.[16]

Genetic risk factors being considered for integration with biomarkers includes ApoE, PSEN1, Bin1, CLU, and SORL1.[15][8][7][6]

APOE gene

 
A 22K fragment of the APOE4 protein (IB68).

Apolipoprotein E (APOE) is a lipoprotein, composed of 299 amino acids, that is expressed throughout the body but particularly important in the brain where it is involved in cholesterol metabolism, specifically in the intracellular and extracellular transport, delivery, and distribution.[15] APOE associates with high-density lipoproteins (HDL).[12] The gene for APOE is located on chromosome 19 and exhibits polymorphisms in the population defined by three alleles of APOE: 𝜀2, 𝜀3, and 𝜀4. [15][18] These alleles differ by only two single nucleotide polymorphisms in exon 4, rs429358 and rs7412 (amino-acid position 112 and 158). [7][15] APOE𝜀3 is the more common of the three and is present in 50-90% of the general population.[15][18] APOE 𝜀4 is the most common risk factor for LOAD, increasing genetic risk up to 33-fold, depending on the population (see the table below).[19] Over 50% of LOAD patients have the 𝜀4 allele and that having even one copy of the 𝜀4 allele increases the risk of developing Alzheimer's by a factor of 4.[7][6][15][18] APOE 𝜀2 has been shown to have a neuroprotective effect with carriers of the allele showing a lower prevalence of AD.[15][18] The neuropathological effects of APOE ε4 are pleiotropic; APOE ε4 impairs uptake of cholesterol by neurons, promotes microglial dysfunction, promotes beta-amyloid aggregation and is increases cerebral angiopathy (CAA).[7][12][18] The increased incidence of AD associated with the APOE ε4 allele has been proposed to be directly linked to Aβ because it modulates Aβ aggregation and clearance, although increasing evidence points to a multitude of actions.[28]

The risk of developing AD with two copies of the APOE𝜀4 allele across various racial-ethnic groups [9][16]
Population APOE𝜀4 Association with AD
Caucasian 12.5
African Americans 5.7
Hispanic 2.2
Japanese 33.1

While extensive research has been done on the APOE4 gene, more information is available for caucasians than for other ethnic and racial groups.[2] The research focusing on the Hispanic and Latino population, suggests that race is a key variable in assessing the risk of carrying the APOE ε4 allele in developing AD.[6][10][15] Genetic studies of Hispanic and Latino populations, show a lower risk of developing AD for individuals with the APOE ε4 than observed in Caucasians.[10] For instance, the prevalence of AD seen in Caribbean Hispanics, compared to White Non-Hispanics, appears to be independent of APOE genotype.[10] Our understanding of ApoE ε4 continues to evolve, though, as Hispanic and Latino representation in research increases leading to larger sample sizes and improved population stratification .[10][2][13]

PSEN1 gene

 
The human gamma-secretase protein complex imaged using cryo-electron microscopy. The structure contains nicastrin (red), presenilin-1 (orange), PEN-2 (blue), and APH-1 (green). This is a transmembrane protein complex that processes amyloid precursor protein (APP) to Aβ peptide.
 
The processing of APP by α, β and γ-secretases

Presenilin 1 (PSEN1) is the catalytic subunit of the transmembrane protein complex gamma-secretase.[29][12] This protein cleaves amyloid precursor protein (APP), after beta-secretase cleavage, to produce Amyloid beta.[12][29] The gene for PSEN1 is located on chromosome 14, q24.2, and consists of 12 exons that encode a 467-amino-acid protein that is predicted to traverse the membrane 9 times.[12] Over 200 pathogenic mutations of this protein exist, many of which account for 18% to 50% of autosomal dominant EOAD cases.[15][12][30] PSEN1 mutations increase the risk of developing AD by increasing the production of amyloid beta-42, compared to amyloid beta-40.[12] Unlike APOE4, PSEN1 mutations tend to have a clear pathological effect in Hispanics and Latinos and tend to express region-specific mutations.[10] Puerto Ricans have a G206A mutation that causes familial AD, Cuban families diagnosed with EAOD commonly exhibit a L174M, mutation, Mexican families exhibit L171P and A431E mutations, and Colombian families exhibit an E280A mutation (particularly in the municipality of Yarumal).[10][31]

BIN1 gene

Bridging Integrator 1 (BIN1) is a widely expressed Bin-Amphiphysin-Rvs (BAR) adaptor protein that is located on chromosome 2, q14.3, and contains 20 exons.[19] BIN1 mainly regulates clathrin-mediated endocytosis. Due to a large number of exons, this gene is subject to alternative splicing, with the major forms varying in the splicing of exons 6a, 10, 12, and 13.[19] Genetic studies indicate that dysfunction in BIN1 is the second most important risk factor for AD.[7][19] The mechanism through which BIN1 contributes to AD, though, is unclear. Studies suggest a range of possible reasons that BIN1 is associated with AD including interactions of BIN1 with the microtubule-associated proteins (i.e. CLIP170), endosomal trafficking of APP and APOE by BIN1, and BIN1 mediated regulation of inflammation through the expression of indoleamine 2,3-dioxygenase (IDO1).[19] The interaction of BIN1 and tau might also be important because elevated levels of BIN1 are associated with increased AD risk through tau load; this result is suggested because of studies of the functional rs59335482 variant.[19] Additionally, endocytic trafficking of APP by BIN1 could be important because trafficking determines if APP will undergo the non-amyloidogenic or the amyloidogenic pathway.[19] For example, if APP is transported to the endosome, it will likely be cleaved by beta-secretase and undergo amyloidogenic processing, but if it accumulates on the cell surface it will be likely cleaved by alpha-secretase and undergo non-amyloidogenic processing.[19] Lastly, BIN1 facilitates the kynurenine pathway of tryptophan metabolism by regulating the expression of the rate-limiting enzyme indoleamine 2,3-dioxygenase (IDO1).[19] For the IDO1 mechanism, increased BIN1 expression could increase levels of a toxic tryptophan derivative IDO1.[19] These metabolites have been suggested to be involved in AD pathology and cognitive decline, as they co-localize with the plaques and NFTs in patient brains.[19]

Genome-wide association studies (GWAS) in the Hispanic/Latino population indicate that polymorphisms in the BIN1, ABAC7 and CD2AP genes are more significant in Caribbean Hispanics.[8] For instance, one BIN1 mutation that has been explored in this Caribbean Hispanics is rs13426725.[19] Other variants that increase the risk of AD include rs6733839.[19]

SORL1 gene

 
The X-ray crystallography structure of human SORL1 in complex with A-beta derived peptide

Sortilin-related receptor 1 (SORL1) is a 250-kDa membrane protein with seven distinct domains that make it a member of two receptor families: the low-density lipoprotein receptor (LDLR) family of ApoE receptors and the vacuolar protein sorting 10 (VPS10) domain receptor family.[28][8] In humans, the SORL1 gene is located on chromosome 11, specifically q232-q24.2.[28] As a protein SORL1 is highly expressed in the brain.[28] SORL1 is an intracellular protein that is expressed in early endosomes and the trans-Golgi network.[28] SORL1 plays an important role in the intracellular trafficking of APP.[28][8] The protein can bind to APP expressed in endosomes and allow APP to be transported back to the cell surface, which prevents amyloidogenic processing and the production of cytotoxic Aβ40 and Aβ42.[28][32] Moreover, SORL1 has been shown to facilitate cholesterol transport through its tendency to bind to APOE-lipoprotein complexes.[28] Strong disease-linked polymorphisms in SORL1 combine with its role in APP trafficking render SORL1 a biomarker of strong interest for LOAD.[28][32] Decreased levels of SORL1 transcript and protein have been observed in the brains of AD patients.[28][32]

Analysis of SORL1 polymorphisms in the Hispanic/Latino population using GWAS and whole-genome sequencing (WGS) have shown that several SORL1 mutations are seen in Caribbean Hispanics.[8][32] Two rare polymorphisms in SORL1 associated with AD were observed in this population, rs117260922-E270K and rs143571823-T947M, as well as a common variant (rs2298813-A528T) .[8][32] These polymorphisms are not specific to Hispanics/Latinos as they are also observed in non-Hispanic white individuals.[8]

ATP binding cassette transporters

 
The Cryo-EM structure of Human ABCA1

Adenosine triphosphate (ATP)-binding cassette transporters are a large family of ABC transporters that regulates the efflux of cholesterol in neuronal cells.[7] Two members of the ATP binding cassette transporter family have been implicated in LOAD: ABC Subfamily A Member 1 (ABCA1) and ABC Subfamily A member 7 (ABCA7).[8][6][19] ABCA1 is a 220-240 kDa protein whose gene is located in chromosome 9q31.1[33] Its putative role in AD is tied to its role in stabilizing ApoE lipidation and degrading amyloid beta expressed in the brain.[8][7] ABCA7 exhibits strong genetic linkage to AD; it is involved in lipid and cholesterol processing, as well as immune system function.[34][19] ABCA7 exhibits tighter association with amyloid deposition than ABCA1.[34] The research on ABCA7 mutations in the Hispanic/Latino population is a bit controversial. Some studies propose that mutations in ABCA7 are more common in Caucasian patients, whereas Hispanics/Latinos are more likely to express a BIN1 mutation.[8] But researchers have still found polymorphisms specific to this population, one example being a 44-base pair frameshift deletion in ABCA7 increases AD risk in African Americans and Caribbean Hispanics.[6]

Clusterin

Clusterin (CLU), also known as apolipoprotein J, is an 82 kDa glycoprotein protein that is located on chromosome 8.[7][35][16] It has multiple physiological functions, some examples being lipid transport, immune modulation, and cell death.[16][35] CLU is known to have the ability to clear Aβ peptides and prevent their aggregation, which suggests that CLU has a neuroprotective effect.[16][35][7] While one might expect AD to be associated with lower levels of a neuroprotective protein, biomarker studies indicate that CLU is upregulated in the plasma, CSF, hippocampus, and cortex of AD patients.[16][35][7] One theory explaining this apparent contradiction is CLU is actually reduced early in life, increasing risk of developing AD.[16] In this scenario, CLU might increase in subjects with AD as a compensatory response to the disease; further research is clearly necessary to clairy this area.[16] However, genetic studies show that CLU is the third most significant risk factor for LOAD, which has propelled extensive genetic research related to CLU and AD.[35] Two CLU variants of interest, that are associated with reduced AD frequency, are rs11136000 and rs9331896.[16] However, little is know about the relationship between CLU and AD risk in the Hispanic/Latino community.[36]

Comorbidities

Studies have shown that metabolic disorders, such as diabetes, cardiovascular disease, hypertension, obesity, and depression can increase one's risk of developing AD as well as increase the rate at which it progresses.[9][10][37] In the United States, 33% of the total population suffers from a metabolic disorder (i.e. diabetes and hypertension).[10] Hispanic and Latino adults are at an increased risk of developing these conditions compared to Caucasians.[2] As of 2017, it has been reported that 35% of all Latinos suffer from an AD comorbidity, with 17% suffering from diabetes and 25.4% suffering from hypertension.[10] The high prevalence of cardiovascular and metabolic conditions is thought to contribute to the higher risk of Alzheimer's Disease seen in Hispanics and Latinos.[10][2][13][37]

Hypertension

 
The clinical stages of hypertension

Hypertension is a condition characterized by persistently high blood pressure.[38][39] Two measurements are taken to quantify blood pressure: systolic and diastolic blood pressure.[39] A patient is diagnosed as hypertensive when their systolic blood pressure is greater than 140 mmHg or diastolic blood pressure is greater than 90 mmHg. Not many people with hypertension are aware that they have the condition.[39][38] In 2010, 31.1% of adults worldwide had hypertension, but only 45.6% of them were aware they had the condition.[39] Hypertension is more apparent in the Hispanic/Latino population, as in 2008 the incidence rate of hypertension for Hispanic adults aged 45–84 was 65.7%, compared to 56.8% for non-Hispanic whites of the same age.[2][40] Hispanic/Latinos are more likely to be unaware of their condition, compared to non-Hispanics, and be less likely to seek treatment, which increases the risk of developing cardiovascular disease and AD.[40][39] Hypertension can be reduced by lifestyle changes (e.g., weight loss and exercise) and pharmacological intervention.[37][38] Multiple studies suggest that use of antihypertensive drugs might reduce the risk of dementia and AD.[37][18]

Diabetes

Type-II diabetes is a metabolic condition characterized by high blood sugar and defective insulin secretion by pancreatic β-cells.[41][42] A patient is diagnosed with diabetes when their fasting blood glucose levels are above 7.0 mmol/L (126 mg/dL) or above 11.1 mmol/L (200 mg/dl) two hours after an oral dose of glucose.[42] As with hypertension, diabetes is more common in the Hispanic/Latino population than in the Caucasian population.[43] In the U.S., Hispanic/Latinos are reported to have a diabetes prevalence of 22.6%, compared to 11.3% in non-Hispanic whites.[43] This increased risk is associated with genetic factors, environmental factors (i.e. diet), and socioeconomic status.[40][44] Recently AD has also been characterized as a metabolic disease of glucose regulation, as patients experience alterations in brain insulin responsiveness that leads to oxidative stress and inflammation.[43] Changes in cerebral glucose signaling associated with AD have been proposed to as type three diabetes, although this has not been adopted as an official designation.[43][45] Older diabetic Mexican Americans are twice as likely to develop dementia than those without diabetes.[43] Additionally, the longer a patient is diabetic, the faster the rate of cognitive decline within the same and racial and age group.[43]

Lifestyle

Many of the comorbidities for AD can be reduced through lifestyle changes.[39][41] Hypertension can be treated by reducing sodium intake, increasing potassium intake, reducing alcohol consumption, and engaging in at least 150 min of moderate-intensity or 75 min of vigorous-intensity physical activity per week.[39] Similarly, diabetes can also be treated by increasing physical activity and changing diet.[41] The same lifestyle changes are recommended for AD patients.[7]

Hispanics and Latinos in clinical research

 
The distribution of Hispanics and Latinos in the United States

The terms Latino and Hispanic are used interchangeably in formal and informal settings.[46] The term "Hispanic" specifically denotes those who can trace their ancestry to a Spanish-speaking country, such as Spain and most of Latin America, the exceptions being Brazil, Guyana, Suriname, and French Guiana.[10] The term "Latino" denotes those who can trace their ancestry to Latin America and the Caribbean.[10] The diversity among Hispanic and Latino groups has led to proposals that the Latino/Hispanic population in the U.S. should not be treated as a homogenous group, and also to define subgroups based on their country of origin.[2]

Socioeconomic status

The socioeconomic status of the Hispanic/Latino population population is thought to contribute to their low participation in clinical trials.[13][2][10] In the U.S., the income and socioeconomic status of Hispanics and Latinos are lower when compared to White Non-Hispanics.[10] In 2015, a study reported that 25% of the Hispanic/Latino population lives in poverty and their median family income was $17,800 lower than their white counterparts.[10]

Studies from 2017 showed that the difference in income is present across many income brackets, with only 38.6% of Latinos reporting a household income between $50,000 and $149,999, in comparison to 45.6% of Non-Hispanic whites.[10] A similar trend was seen with levels of higher education and medical literacy attained by Hispanics and Latinos.[10][2] As of 2013, it was reported that 22% of Latino adults (25 years and over) had earned an associate degree or higher, compared to the 46% seen in White Non-Hispanics.[10] This trend is also seen with advanced degrees, as Latinos only account for 7% of Master's degrees and 1% Doctorate degrees awarded in the U.S.[10] The lower measures of socioeconomic achievement and education level have been proposed to be associated with high mortality and dementia rates.[2][10][13] In contrast, high educational levels are correlated with lower rates of dementia.[7]

Hispanic and Latinos that are 65 years and older make up one of the largest groups of uninsured individuals in the U.S.[2] This makes it difficult for these seniors to obtain the clinical care necessary for management of AD.[7][6][2] The cost of care for insured patients 65 years and older was estimated to be $25,213 per person, compared to the estimated $7750 for senior patients without AD.[47] Increasing efforts are being made to include minorities in clinical research, for instance by providing travel support for participants.[13][10]

The Cost of AD Care in 2020[47]
Payment Source Cost in Billions ($)
Medicare $155
Medicaid $51
Out of Pocket $66
Other $33
TOTAL $305

Language barrier

Putative language barriers can also interfere with healthcare for the Hispanic and Latino community. Clinical trials can require participants to be fluent in English, which can potentially exclude older Hispanic and Latino subjects, who might not be fluent in English.[10][2] Only 40% of the older generation, Latinos over the age of 69, are fluent.[10] Proficiency in English is less of an issue for younger Latinos, with 90% of the population between the ages of 5 and 17 speaking the language fluently.[10] Weak communication between physician and patient can also impair medical care.[2][10] For instance, this issue occurs with clinical notes, which are typically translated from the English version of the same document for Spanish-speaking individuals.[2] The medical community is attempting to address this issue by recruiting staff and physicians able to communicate with participants in their native language, as well as providing training on cultural sensitivity.[10][13]

See also

References

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External links

  • National Institute of Aging Summary of its Studies of AD in the Hispanic/Latino Population

March 04, 2023
alzheimer, disease, hispanic, latino, population, alzheimer, disease, hispanic, latino, population, becoming, topic, interest, research, hispanics, latinos, disproportionately, affected, alzheimer, disease, underrepresented, clinical, research, neurodegenerati. Alzheimer s disease AD in the Hispanic Latino population is becoming a topic of interest in AD research as Hispanics and Latinos are disproportionately affected by Alzheimer s Disease and underrepresented in clinical research 1 2 AD is a neurodegenerative disease characterized by the presence of amyloid beta plaques and neurofibrillary tangles that causes memory loss and cognitive decline in its patients 3 However pathology and symptoms have been shown to manifest differently in Hispanic Latinos as different neuroinflammatory markers are expressed and cognitive decline is more pronounced 4 5 Additionally there is a large genetic component of AD with mutations in the amyloid precursor protein APP Apolipoprotein E APOE presenilin 1 PSEN1 bridging Integrator 1 BIN1 SORL1 and Clusterin CLU genes increasing one s risk to develop the condition 6 7 8 However research has shown these high risk genes have a different effect on Hispanics and Latinos then they do in other racial and ethnic groups 9 Additionally this population experiences higher rates of comorbidities that increase their risk of developing AD 9 Hispanics and Latinos also face socioeconomic and cultural factors such as low income and a language barrier that affect their ability to engage in clinical trials and receive proper care 10 2 Contents 1 Alzheimer s disease 1 1 Hispanic Latino population 1 2 Types 1 3 Pathology and symptoms 1 3 1 Amyloid beta plaques and neurofibrillary tangles 1 3 2 Chronic inflammation 1 3 3 Neurodegeneration 1 3 4 Mild cognitive impairment 1 4 Brain imaging 1 5 Biomarkers 1 5 1 APOE gene 1 5 2 PSEN1 gene 1 5 3 BIN1 gene 1 5 4 SORL1 gene 1 5 5 ATP binding cassette transporters 1 5 6 Clusterin 1 6 Comorbidities 1 6 1 Hypertension 1 6 2 Diabetes 1 6 3 Lifestyle 2 Hispanics and Latinos in clinical research 2 1 Socioeconomic status 2 2 Language barrier 3 See also 4 References 5 External linksAlzheimer s disease Edit A healthy brain left and the brain of a late stage Alzheimer s brain right Alzheimer s disease is the most common form of dementia accounting for 60 of all cases and is the sixth leading cause of death in the elderly 11 12 The disease typically presents itself with intracellular aggregation of hyper phosphorylated tau forming neurofibrillary tangles NFTs and the extracellular aggregation of amyloid beta Ab forming neuritic plaques 7 As of 2020 5 4 million Americans have been diagnosed with Alzheimer s disease and this number is projected to reach 15 22 million by 2050 6 10 Hispanics and Latinos account for 55 million of the population and this population is projected to rise to 97 million accounting for 25 of the U S population in 2050 10 Hispanic Latino population Edit Hispanics and Latinos make up 18 of the U S population however they are underrepresented in clinical research 2 13 The National Institute of Health NIH reported that Hispanic and Latinos accounted for less than 8 of reported clinical trial participants 10 One proposed reason for the lack of representation is that the Hispanic Latino population includes many people from different countries and with this diverse background come different characteristics and comorbidities associated with AD 10 Hispanic and Latinos have a higher prevalence of AD compared to White non Hispanics 10 2 Studies estimate that 12 of older Hispanic and Latino adults were diagnosed with AD the highest proportion compared to all other ethnic groups 2 Hispanic and Latinos are the fastest growing population in the U S and Hispanic Latino seniors those who are 65 and older are expected to have the largest rise in AD and dementia cases compared to other populations reaching 3 5 million by 2060 10 In 2011 the National Alzheimer s Disease Project Act was signed into law 2 The goal of this act was for The National Institute of Aging to accelerate research and clinical care of patients with AD this act also has the benefit of seeking to improve the inclusion of underrepresented populations in AD research and clinical trials 2 Types Edit There exist two types of Alzheimer s disease familial Alzheimer s disease also called Early onset Alzheimer s disease EOAD and sporadic Alzheimer s Disease also called Late onset Alzheimer s Disease LOAD 6 14 EOAD is the less common of the two accounting for 5 10 and patients with EOAD are typically diagnosed with familial AD before they turn 65 years old 6 14 LOAD is more common and accounts for 90 of AD cases and its patients experience onset after they turn 65 12 7 EOAD has been shown to have 2 types of inheritance patterns mendelian mEOAD and non mendelian nmEOAD sporadic patterns 6 The three main genes that implicated in familial AD are amyloid precursor protein APP Presenilin 1 PSEN 1 presenilin 2 PSEN 2 6 14 7 Onset of sporadic AD has both genetic and environmental risk factors 14 Some genes of interest in LOAD are the APOE gene specifically the ApoE4 allele bridging Integrator 1 BIN1 SORL1 and clusterin CLU 6 7 15 16 8 Pathology and symptoms Edit Amyloid beta plaques and neurofibrillary tangles Edit Comparing the formation of the plaques as a result of neuroinflammation between wild type PP mice AD transgenic mice 3xTgAD and AD patients The inflammation induced accumulation of APP fragments red represents the seeding point for the aggregation of Amyloid beta peptides green Neuritic plaques and neurofibrillary Tangles NFTs are the main pathological component of AD 7 17 Neuritic plaques are composed mainly of the peptide Ab but also include other components 18 APP is processed through either of two pathways the first is termed the amyloidogenic pathway and produces Ab 18 The second pathway is the non amyloidogenic pathway and does not produce Ab 18 In the amyloidogenic pathway APP the parent protein is trafficked to endosomes cleaved by beta secretase BACE after which it moves back to the cell surface to be cleaved by gamma secretase thus releasing the Ab peptide 7 8 17 18 This form of APP processing produces multiple Ab peptides of which Ab40 and Ab42 peptide are most abundantly produced produced 7 19 APP can also be cleaved by alpha and gamma secretase and undergo non amyloidogenic processing 17 19 NFTs form when the tau protein which is involved in microtubule stability is hyperphosphorylated dissociates from microtubules and then aggregates with other p tau monomers forming tau oligomers fibrils and eventually NFTs 7 These types of pathologies do not differ across ethnic groups 7 Chronic inflammation Edit Neuroinflammation is another pathological component of AD pathology and is associated with an increase in levels of inflammatory markers 7 20 Researchers have also identified many genes linked to immune function that are risk factors for AD such as TREM2 20 TREM2 are highly expressed in microglia the immune cell of the brain tying the progression of AD with dysfunction in microglial activity 21 Neuroinflammation Ab and tau pathologies interact in Alzheimer s disease and their progress can be monitored with biomarkers 20 For example studies have found the neuroinflammatory marker YKL 40 in the cerebrospinal fluid CSF of AD patients 16 4 This protein increases years before the onset of AD symptoms and correlates with other neurodegenerative biomarkers which suggests a potential to predict disease progression 4 While YKL 40 has not been shown to associate with the APOE e4 allele there is research to link this biomarker to AD in the Hispanic population 4 Neurodegeneration Edit Along with the plaques and inflammation patients with AD also suffer from neurodegeneration characterized by loss of neurons and synapses the communication tool for neurons 17 7 As a result the entire brain shrinks in volume termed brain atrophy the ventricles grow larger and the hippocampus and cortex shrink in size 7 17 As all these pathologies progress patients begin to experience a decline in memory cognitive abilities and independence The accumulation of neurofibrillary tangles and loss of synaptic fields correlate most closely with cognitive loss 7 Mild cognitive impairment Edit Mild cognitive impairment MCI precedes the overt diagnosis of AD 3 22 23 To be diagnosed with MCI a patient must show memory impairment a progressive decline in cognitive abilities without presenting symptoms of Parkinson s disease cerebrovascular diseases and behavioral or language disorders 23 Studies show that older Hispanic Latinos exhibit a higher prevalence of dementia than caucasians 5 24 Demographic and linguistic factors can prevent a proper MCI diagnosis 25 26 For instance subjects for whom English might not be the primary language require use of a translator to perform the cognitive testing which could affect testing results but such experimental weaknesses are frequently not described 25 26 PiB PET scan of an AD patient left compared to an age matched control right Pittsburgh Compound B PIB is easily taken up into the brains of AD patients and is used to detect Amyloid beta Brain regions that are colored red and yellow correspond to a high concentration of PiB suggesting high amounts of amyloid deposit Brain imaging Edit Positron emission tomography PET is a brain imaging technique that uses a small amount of radioactive substance called a tracer to measure energy use or a specific molecule in different brain regions 27 In AD research tracers can be used to detect neuritic plaques containing Ab and tau Depending on the tracer used the signal can be used to determine the presence of neuritic plaques and NFTs 27 The role of genetic mutations in Alzheimer s Disease Biomarkers Edit Establishing biomarkers for the early detection of AD is an ongoing are of research because pathological changes occur years before symptoms become apparent 7 16 Common biomarkers for AD include amyloid beta and hyperphosphorylated tau both of which can be found in brain tissue and cerebrospinal fluid CSF 7 Ab provides a biomarker of neuritic plaques which form when APP cleavage results in an increase in the Ab42 Ab40 ratio 7 Hyperphosphorylated tau serves as a biomarker of neurofibrillary tangles NFTs with the presence of NFTs indicating a disruption in microtubule stability and neuronal injury 7 Researchers have begun investigating other markers in the CSF such as markers of neuronal injury like Visinin Like Protein 1 VILIP 1 YKL 40 and Neurogranin NGRN 16 Due to the low use of CSF sampling in most countries efforts have been made to study biomarkers in blood 16 Through work on blood biomarkers researchers have been able to find proteins that are elevated in AD patients and have predictive potential 16 The predictive potential of these plasma markers increases further when coupled with the presence of genetic risk factors such as the APOE E4 allele 16 Examples of plasma biomarkers include interleukin TGF and micro RNA 16 Genetic risk factors being considered for integration with biomarkers includes ApoE PSEN1 Bin1 CLU and SORL1 15 8 7 6 APOE gene Edit A 22K fragment of the APOE4 protein IB68 Apolipoprotein E APOE is a lipoprotein composed of 299 amino acids that is expressed throughout the body but particularly important in the brain where it is involved in cholesterol metabolism specifically in the intracellular and extracellular transport delivery and distribution 15 APOE associates with high density lipoproteins HDL 12 The gene for APOE is located on chromosome 19 and exhibits polymorphisms in the population defined by three alleles of APOE 𝜀2 𝜀3 and 𝜀4 15 18 These alleles differ by only two single nucleotide polymorphisms in exon 4 rs429358 and rs7412 amino acid position 112 and 158 7 15 APOE𝜀3 is the more common of the three and is present in 50 90 of the general population 15 18 APOE 𝜀4 is the most common risk factor for LOAD increasing genetic risk up to 33 fold depending on the population see the table below 19 Over 50 of LOAD patients have the 𝜀4 allele and that having even one copy of the 𝜀4 allele increases the risk of developing Alzheimer s by a factor of 4 7 6 15 18 APOE 𝜀2 has been shown to have a neuroprotective effect with carriers of the allele showing a lower prevalence of AD 15 18 The neuropathological effects of APOE e4 are pleiotropic APOE e4 impairs uptake of cholesterol by neurons promotes microglial dysfunction promotes beta amyloid aggregation and is increases cerebral angiopathy CAA 7 12 18 The increased incidence of AD associated with the APOE e4 allele has been proposed to be directly linked to Ab because it modulates Ab aggregation and clearance although increasing evidence points to a multitude of actions 28 The risk of developing AD with two copies of the APOE𝜀4 allele across various racial ethnic groups 9 16 Population APOE𝜀4 Association with ADCaucasian 12 5African Americans 5 7Hispanic 2 2Japanese 33 1While extensive research has been done on the APOE4 gene more information is available for caucasians than for other ethnic and racial groups 2 The research focusing on the Hispanic and Latino population suggests that race is a key variable in assessing the risk of carrying the APOE e4 allele in developing AD 6 10 15 Genetic studies of Hispanic and Latino populations show a lower risk of developing AD for individuals with the APOE e4 than observed in Caucasians 10 For instance the prevalence of AD seen in Caribbean Hispanics compared to White Non Hispanics appears to be independent of APOE genotype 10 Our understanding of ApoE e4 continues to evolve though as Hispanic and Latino representation in research increases leading to larger sample sizes and improved population stratification 10 2 13 PSEN1 gene Edit The human gamma secretase protein complex imaged using cryo electron microscopy The structure contains nicastrin red presenilin 1 orange PEN 2 blue and APH 1 green This is a transmembrane protein complex that processes amyloid precursor protein APP to Ab peptide The processing of APP by a b and g secretasesPresenilin 1 PSEN1 is the catalytic subunit of the transmembrane protein complex gamma secretase 29 12 This protein cleaves amyloid precursor protein APP after beta secretase cleavage to produce Amyloid beta 12 29 The gene for PSEN1 is located on chromosome 14 q24 2 and consists of 12 exons that encode a 467 amino acid protein that is predicted to traverse the membrane 9 times 12 Over 200 pathogenic mutations of this protein exist many of which account for 18 to 50 of autosomal dominant EOAD cases 15 12 30 PSEN1 mutations increase the risk of developing AD by increasing the production of amyloid beta 42 compared to amyloid beta 40 12 Unlike APOE4 PSEN1 mutations tend to have a clear pathological effect in Hispanics and Latinos and tend to express region specific mutations 10 Puerto Ricans have a G206A mutation that causes familial AD Cuban families diagnosed with EAOD commonly exhibit a L174M mutation Mexican families exhibit L171P and A431E mutations and Colombian families exhibit an E280A mutation particularly in the municipality of Yarumal 10 31 BIN1 gene Edit Bridging Integrator 1 BIN1 is a widely expressed Bin Amphiphysin Rvs BAR adaptor protein that is located on chromosome 2 q14 3 and contains 20 exons 19 BIN1 mainly regulates clathrin mediated endocytosis Due to a large number of exons this gene is subject to alternative splicing with the major forms varying in the splicing of exons 6a 10 12 and 13 19 Genetic studies indicate that dysfunction in BIN1 is the second most important risk factor for AD 7 19 The mechanism through which BIN1 contributes to AD though is unclear Studies suggest a range of possible reasons that BIN1 is associated with AD including interactions of BIN1 with the microtubule associated proteins i e CLIP170 endosomal trafficking of APP and APOE by BIN1 and BIN1 mediated regulation of inflammation through the expression of indoleamine 2 3 dioxygenase IDO1 19 The interaction of BIN1 and tau might also be important because elevated levels of BIN1 are associated with increased AD risk through tau load this result is suggested because of studies of the functional rs59335482 variant 19 Additionally endocytic trafficking of APP by BIN1 could be important because trafficking determines if APP will undergo the non amyloidogenic or the amyloidogenic pathway 19 For example if APP is transported to the endosome it will likely be cleaved by beta secretase and undergo amyloidogenic processing but if it accumulates on the cell surface it will be likely cleaved by alpha secretase and undergo non amyloidogenic processing 19 Lastly BIN1 facilitates the kynurenine pathway of tryptophan metabolism by regulating the expression of the rate limiting enzyme indoleamine 2 3 dioxygenase IDO1 19 For the IDO1 mechanism increased BIN1 expression could increase levels of a toxic tryptophan derivative IDO1 19 These metabolites have been suggested to be involved in AD pathology and cognitive decline as they co localize with the plaques and NFTs in patient brains 19 Genome wide association studies GWAS in the Hispanic Latino population indicate that polymorphisms in the BIN1 ABAC7 and CD2AP genes are more significant in Caribbean Hispanics 8 For instance one BIN1 mutation that has been explored in this Caribbean Hispanics is rs13426725 19 Other variants that increase the risk of AD include rs6733839 19 SORL1 gene Edit The X ray crystallography structure of human SORL1 in complex with A beta derived peptide Sortilin related receptor 1 SORL1 is a 250 kDa membrane protein with seven distinct domains that make it a member of two receptor families the low density lipoprotein receptor LDLR family of ApoE receptors and the vacuolar protein sorting 10 VPS10 domain receptor family 28 8 In humans the SORL1 gene is located on chromosome 11 specifically q232 q24 2 28 As a protein SORL1 is highly expressed in the brain 28 SORL1 is an intracellular protein that is expressed in early endosomes and the trans Golgi network 28 SORL1 plays an important role in the intracellular trafficking of APP 28 8 The protein can bind to APP expressed in endosomes and allow APP to be transported back to the cell surface which prevents amyloidogenic processing and the production of cytotoxic Ab40 and Ab42 28 32 Moreover SORL1 has been shown to facilitate cholesterol transport through its tendency to bind to APOE lipoprotein complexes 28 Strong disease linked polymorphisms in SORL1 combine with its role in APP trafficking render SORL1 a biomarker of strong interest for LOAD 28 32 Decreased levels of SORL1 transcript and protein have been observed in the brains of AD patients 28 32 Analysis of SORL1 polymorphisms in the Hispanic Latino population using GWAS and whole genome sequencing WGS have shown that several SORL1 mutations are seen in Caribbean Hispanics 8 32 Two rare polymorphisms in SORL1 associated with AD were observed in this population rs117260922 E270K and rs143571823 T947M as well as a common variant rs2298813 A528T 8 32 These polymorphisms are not specific to Hispanics Latinos as they are also observed in non Hispanic white individuals 8 ATP binding cassette transporters Edit The Cryo EM structure of Human ABCA1 Adenosine triphosphate ATP binding cassette transporters are a large family of ABC transporters that regulates the efflux of cholesterol in neuronal cells 7 Two members of the ATP binding cassette transporter family have been implicated in LOAD ABC Subfamily A Member 1 ABCA1 and ABC Subfamily A member 7 ABCA7 8 6 19 ABCA1 is a 220 240 kDa protein whose gene is located in chromosome 9q31 1 33 Its putative role in AD is tied to its role in stabilizing ApoE lipidation and degrading amyloid beta expressed in the brain 8 7 ABCA7 exhibits strong genetic linkage to AD it is involved in lipid and cholesterol processing as well as immune system function 34 19 ABCA7 exhibits tighter association with amyloid deposition than ABCA1 34 The research on ABCA7 mutations in the Hispanic Latino population is a bit controversial Some studies propose that mutations in ABCA7 are more common in Caucasian patients whereas Hispanics Latinos are more likely to express a BIN1 mutation 8 But researchers have still found polymorphisms specific to this population one example being a 44 base pair frameshift deletion in ABCA7 increases AD risk in African Americans and Caribbean Hispanics 6 Clusterin Edit Clusterin CLU also known as apolipoprotein J is an 82 kDa glycoprotein protein that is located on chromosome 8 7 35 16 It has multiple physiological functions some examples being lipid transport immune modulation and cell death 16 35 CLU is known to have the ability to clear Ab peptides and prevent their aggregation which suggests that CLU has a neuroprotective effect 16 35 7 While one might expect AD to be associated with lower levels of a neuroprotective protein biomarker studies indicate that CLU is upregulated in the plasma CSF hippocampus and cortex of AD patients 16 35 7 One theory explaining this apparent contradiction is CLU is actually reduced early in life increasing risk of developing AD 16 In this scenario CLU might increase in subjects with AD as a compensatory response to the disease further research is clearly necessary to clairy this area 16 However genetic studies show that CLU is the third most significant risk factor for LOAD which has propelled extensive genetic research related to CLU and AD 35 Two CLU variants of interest that are associated with reduced AD frequency are rs11136000 and rs9331896 16 However little is know about the relationship between CLU and AD risk in the Hispanic Latino community 36 Comorbidities Edit Studies have shown that metabolic disorders such as diabetes cardiovascular disease hypertension obesity and depression can increase one s risk of developing AD as well as increase the rate at which it progresses 9 10 37 In the United States 33 of the total population suffers from a metabolic disorder i e diabetes and hypertension 10 Hispanic and Latino adults are at an increased risk of developing these conditions compared to Caucasians 2 As of 2017 it has been reported that 35 of all Latinos suffer from an AD comorbidity with 17 suffering from diabetes and 25 4 suffering from hypertension 10 The high prevalence of cardiovascular and metabolic conditions is thought to contribute to the higher risk of Alzheimer s Disease seen in Hispanics and Latinos 10 2 13 37 Hypertension Edit The clinical stages of hypertensionHypertension is a condition characterized by persistently high blood pressure 38 39 Two measurements are taken to quantify blood pressure systolic and diastolic blood pressure 39 A patient is diagnosed as hypertensive when their systolic blood pressure is greater than 140 mmHg or diastolic blood pressure is greater than 90 mmHg Not many people with hypertension are aware that they have the condition 39 38 In 2010 31 1 of adults worldwide had hypertension but only 45 6 of them were aware they had the condition 39 Hypertension is more apparent in the Hispanic Latino population as in 2008 the incidence rate of hypertension for Hispanic adults aged 45 84 was 65 7 compared to 56 8 for non Hispanic whites of the same age 2 40 Hispanic Latinos are more likely to be unaware of their condition compared to non Hispanics and be less likely to seek treatment which increases the risk of developing cardiovascular disease and AD 40 39 Hypertension can be reduced by lifestyle changes e g weight loss and exercise and pharmacological intervention 37 38 Multiple studies suggest that use of antihypertensive drugs might reduce the risk of dementia and AD 37 18 Diabetes Edit Type II diabetes is a metabolic condition characterized by high blood sugar and defective insulin secretion by pancreatic b cells 41 42 A patient is diagnosed with diabetes when their fasting blood glucose levels are above 7 0 mmol L 126 mg dL or above 11 1 mmol L 200 mg dl two hours after an oral dose of glucose 42 As with hypertension diabetes is more common in the Hispanic Latino population than in the Caucasian population 43 In the U S Hispanic Latinos are reported to have a diabetes prevalence of 22 6 compared to 11 3 in non Hispanic whites 43 This increased risk is associated with genetic factors environmental factors i e diet and socioeconomic status 40 44 Recently AD has also been characterized as a metabolic disease of glucose regulation as patients experience alterations in brain insulin responsiveness that leads to oxidative stress and inflammation 43 Changes in cerebral glucose signaling associated with AD have been proposed to as type three diabetes although this has not been adopted as an official designation 43 45 Older diabetic Mexican Americans are twice as likely to develop dementia than those without diabetes 43 Additionally the longer a patient is diabetic the faster the rate of cognitive decline within the same and racial and age group 43 Lifestyle Edit Many of the comorbidities for AD can be reduced through lifestyle changes 39 41 Hypertension can be treated by reducing sodium intake increasing potassium intake reducing alcohol consumption and engaging in at least 150 min of moderate intensity or 75 min of vigorous intensity physical activity per week 39 Similarly diabetes can also be treated by increasing physical activity and changing diet 41 The same lifestyle changes are recommended for AD patients 7 Hispanics and Latinos in clinical research Edit The distribution of Hispanics and Latinos in the United States The terms Latino and Hispanic are used interchangeably in formal and informal settings 46 The term Hispanic specifically denotes those who can trace their ancestry to a Spanish speaking country such as Spain and most of Latin America the exceptions being Brazil Guyana Suriname and French Guiana 10 The term Latino denotes those who can trace their ancestry to Latin America and the Caribbean 10 The diversity among Hispanic and Latino groups has led to proposals that the Latino Hispanic population in the U S should not be treated as a homogenous group and also to define subgroups based on their country of origin 2 Socioeconomic status Edit The socioeconomic status of the Hispanic Latino population population is thought to contribute to their low participation in clinical trials 13 2 10 In the U S the income and socioeconomic status of Hispanics and Latinos are lower when compared to White Non Hispanics 10 In 2015 a study reported that 25 of the Hispanic Latino population lives in poverty and their median family income was 17 800 lower than their white counterparts 10 Studies from 2017 showed that the difference in income is present across many income brackets with only 38 6 of Latinos reporting a household income between 50 000 and 149 999 in comparison to 45 6 of Non Hispanic whites 10 A similar trend was seen with levels of higher education and medical literacy attained by Hispanics and Latinos 10 2 As of 2013 it was reported that 22 of Latino adults 25 years and over had earned an associate degree or higher compared to the 46 seen in White Non Hispanics 10 This trend is also seen with advanced degrees as Latinos only account for 7 of Master s degrees and 1 Doctorate degrees awarded in the U S 10 The lower measures of socioeconomic achievement and education level have been proposed to be associated with high mortality and dementia rates 2 10 13 In contrast high educational levels are correlated with lower rates of dementia 7 Hispanic and Latinos that are 65 years and older make up one of the largest groups of uninsured individuals in the U S 2 This makes it difficult for these seniors to obtain the clinical care necessary for management of AD 7 6 2 The cost of care for insured patients 65 years and older was estimated to be 25 213 per person compared to the estimated 7750 for senior patients without AD 47 Increasing efforts are being made to include minorities in clinical research for instance by providing travel support for participants 13 10 The Cost of AD Care in 2020 47 Payment Source Cost in Billions Medicare 155Medicaid 51Out of Pocket 66Other 33TOTAL 305Language barrier Edit Putative language barriers can also interfere with healthcare for the Hispanic and Latino community Clinical trials can require participants to be fluent in English which can potentially exclude older Hispanic and Latino subjects who might not be fluent in English 10 2 Only 40 of the older generation Latinos over the age of 69 are fluent 10 Proficiency in English is less of an issue for younger Latinos with 90 of the population between the ages of 5 and 17 speaking the language fluently 10 Weak communication between physician and patient can also impair medical care 2 10 For instance this issue occurs with clinical notes which are typically translated from the English version of the same document for Spanish speaking individuals 2 The medical community is attempting to address this issue by recruiting staff and physicians able to communicate with participants in their native language as well as providing training on cultural sensitivity 10 13 See also EditRace and health in the United StatesReferences Edit Marquez David X Perez Adriana Johnson Julene K Jaldin Michelle Pinto Juan Keiser Sahru Tran Thi Martinez Paula Guerrero Javier Portacolone Elena 26 July 2022 Increasing engagement of Hispanics Latinos in clinical trials on Alzheimer s disease and related dementias Alzheimer s amp Dementia Translational Research amp Clinical Interventions 8 1 e12331 doi 10 1002 trc2 12331 ISSN 2352 8737 PMC 9322823 PMID 35910673 a b c d e f g h i j k l m n o p q r s t u Massett Holly A Mitchell Alexandra K Alley Leah Simoneau Elizabeth Burke Panne Han Sae H Gallop Goodman Gerda McGowan Melissa 2021 06 29 Gleason Carey ed Facilitators Challenges and Messaging Strategies for Hispanic Latino Populations Participating in Alzheimer s Disease and Related Dementias Clinical Research A Literature Review Journal of Alzheimer s Disease 82 1 107 127 doi 10 3233 JAD 201463 PMID 33998537 S2CID 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Latinos in the US and Latin America Frontiers in Endocrinology 8 298 doi 10 3389 fendo 2017 00298 ISSN 1664 2392 PMC 5687125 PMID 29176960 Umpierrez Guillermo E Gonzalez Amparo Umpierrez Denise Pimentel Diana 2007 10 01 Diabetes Mellitus in the Hispanic Latino Population An Increasing Health Care Challenge in the United States The American Journal of the Medical Sciences 334 4 274 282 doi 10 1097 MAJ 0b013e3180a6efe3 ISSN 0002 9629 PMID 18030184 Nguyen Thuy Trang Ta Qui Thanh Hoai Nguyen Thi Kim Oanh Nguyen Thi Thuy Dung Van Giau Vo 2020 04 30 Type 3 Diabetes and Its Role Implications in Alzheimer s Disease International Journal of Molecular Sciences 21 9 3165 doi 10 3390 ijms21093165 ISSN 1422 0067 PMC 7246646 PMID 32365816 Greenwood Shannon 2020 08 11 About One in Four U S Hispanics Have Heard of Latinx but Just 3 Use It Pew Research Center s Hispanic Trends Project Retrieved 2022 11 15 a b Winston Wong PharmD 2020 08 17 Economic Burden of Alzheimer Disease and Managed Care Considerations Supplements and Featured Publications Addressing Unmet Needs in Alzheimer Disease Implications of Delayed Diagnosis and Examining New and Emerging Therapies 26 8 External links EditNational Institute of Aging Summary of its Studies of AD in the Hispanic Latino Population Retrieved from https en wikipedia org w index php title Alzheimer 27s disease in the Hispanic Latino population amp oldid 1140032831, wikipedia, wiki, book, books, library,

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