摘要
背景:阿尔茨海默氏症痴呆(AD)具有复杂的病理生理学,尚未完全了解。慢性,低水平环境铅(Pb)暴露与认知障碍,高血压和死亡率相关,并且已被提议作为AD的潜在原因。 目的:我们旨在回顾文献,以阐明铅在AD中的潜在作用,并指导未来的研究。 方法:通过一系列系统评价,我们确定了病例对照研究,比较AD与对照对6种铅暴露或积累的测量:血液,骨骼,脑脊液,毛发/指甲,死后病理和尿液。我们尽可能完成了元分析。 结果:通过测量方法确定的AD病例对照研究的数量为:血液15,骨骼0,脑脊液(CSF)5,头发/指甲3,死后3,尿液1。报告全血Pb的7项研究和8项血清Pb研究可能有两项荟萃分析。两者都是消极的。最大的CSF Pb研究显示AD水平较低。类似地,在AD中发现较低的头发Pb水平。 结论:现有的病例对照研究不足以得出Pb在AD中的作用。大多数方法不涉及长期或早期暴露。慢性Pb的优选量度是在骨中,其尚未用于病例对照AD研究中。未来的研究应该测量AD中的骨铅,以及其他生物标志物,如淀粉样蛋白和tau成像,以及脑血管病理学的标志物。
关键词: 铅(Pb),阿尔茨海默氏症,痴呆,毒性,环境,认知。
[1]
Livingston G, Sommerlad A, Orgeta V, Costafreda SG, Huntley J, Ames D, et al. Dementia prevention, intervention, and care. The Lancet 390(10113): 2673-34. (2017).
[2]
Bakulski KM, Rozek LS, Dolinoy DC, Paulson HL, Hu H. Alzheimer’s disease and environmental exposure to lead: the epidemiologic evidence and potential role of epigenetics. Curr Alzheimer Res 9(5): 563-73. (2012).
[3]
World Health Organization, Ed. Global health risks: mortality and
burden of disease attributable to selected major risks. Geneva,
Switzerland: World Health Organization; 62 p. (2009).
[4]
McNeill FE, Fisher M, Chettle DR, Inskip M, Healey N, Bray R, et al. The decrease in population bone lead levels in Canada between 1993 and 2010 as assessed by in vivo XRF. Physiol Meas 39(1): 015005. (2017).
[5]
Satizabal CL, Beiser AS, Chouraki V, Chêne G, Dufouil C, Seshadri S. Incidence of dementia over three decades in the framingham heart study. N Engl J Med 374(6): 523-2. (2016).
[6]
Niklowitz W, Mandybur T. Neurofibrillary changes following childhood lead encephalopathy. J Neuropathol Exp Neurol 34(5): 445-55. (1975).
[7]
Reuben A, Caspi A, Belsky DW, Broadbent J, Harrington H, Sugden K, et al. Association of childhood blood lead levels with cognitive function and socioeconomic status at age 38 years and with iq change and socioeconomic mobility between childhood and adulthood. JAMA 317(12): 1244. (2017).
[8]
Lanphear BP, Rauch S, Auinger P, Allen RW, Hornung RW. Low-level lead exposure and mortality in US adults: a population-based cohort study. Lancet Public Health 3(4): e177-84. (2018).
[9]
Bihaqi SW, Alansi B, Masoud AM, Mushtaq F, Subaiea GM, Zawia NH. Influence of early life lead (pb) exposure on alpha-synuclein, GSK-3beta and caspase-3 mediated tauopathy: implications on Alzheimer’s disease. Curr Alzheimer Res Curr Alzheimer Res 15(12): 1114-22. (2018).
[10]
Shih RA, Hu H, Weisskopf MG, Schwartz BS. Cumulative lead dose and cognitive function in adults: a review of studies that measured both blood lead and bone lead. Environ Health Perspect 115: 483-92. (2007).
[11]
Farooqui Z, Bakulski KM, Power MC, Weisskopf MG, Sparrow D, Spiro A, et al. Associations of cumulative Pb exposure and longitudinal changes in Mini-Mental Status Exam scores, global cognition and domains of cognition: The VA Normat Aging Study. Environ Res 152: 102-8. (2017).
[12]
Bandeen-Roche K, Glass TA, Bolla KI, Todd AC, Schwartz BS. Cumulative lead dose and cognitive function in older adults. Epidemiol Camb Mass 20(6): 831-9. (2009).
[13]
Power MC, Korrick S, Tchetgen Tchetgen EJ, Nie LH, Grodstein F, Hu H, et al. Lead exposure and rate of change in cognitive function in older women. Environ Res 129: 69-75. (2014).
[14]
Weuve J, Korrick SA, Weisskopf MG, Ryan LM, Schwartz J, Nie H, et al. Cumulative exposure to lead in relation to cognitive function in older women. Environ Health Perspect 117(4): 574-80. (2009).
[15]
Arksey H, O’Malley L. Scoping studies: towards a methodological framework. Int J Soc Res Methodol 8(1): 19-32. (2005).
[16]
Esteban-Vasallo MD, Aragonés N, Pollan M, López-Abente G, Perez-Gomez B. Mercury, cadmium, and lead levels in human placenta: a systematic review. Environ Health Perspect 120(10): 1369-77. (2012).
[18]
Xu L, Zhang W, Liu X, Zhang C, Wang P, Zhao X. Circulatory levels of toxic metals (aluminum, cadmium, mercury, lead) in patients with Alzheimer’s disease: a quantitative meta-analysis and systematic review. J Alzheimers Dis 62(1): 361-72. (2018).
[19]
Bocca B, Forte G, Petrucci F, Pino A, Marchione F, Bomboi G, et al. Monitoring of chemical elements and oxidative damage in patients affected by Alzheimer’s disease. Ann Ist Super Sanita 41(2): 197-203. (2005).
[20]
Bocca B, Alimonti A, Bomboi G, Giubilei F, Forte G. Alterations in the level of trace metals in Alzheimer’s disease. Trace Elem Electrolytes 23(4): 270-6. (2006).
[21]
Alimonti A, Ristori G, Giubilei F, Stazi MA, Pino A, Visconti A, et al. Serum chemical elements and oxidative status in Alzheimer’s disease, Parkinson disease and multiple sclerosis. Neurotoxicology 28(3): 450-6. (2007).
[22]
González-Domínguez R, García-Barrera T, Gómez-Ariza JL. Characterization of metal profiles in serum during the progression of Alzheimer’s disease. Metallomics 6(2): 292-300. (2014).
[23]
Paglia G, Miedico O, Cristofano A, Vitale M, Angiolillo A, Chiaravalle AE, et al. Distinctive pattern of serum elements during the progression of Alzheimer’s disease. Sci Rep [Internet]. 2016 Sep [cited 2018 Aug 28];6(1). Available from: http://www.nature.com/articles/srep22769
[24]
Fathabadi B, Dehghanifiroozabadi M, Aaseth J, Sharifzadeh G, Nakhaee S, Rajabpour-Sanati A, et al. Comparison of blood lead levels in patients with Alzheimer’s disease and healthy people. Am J Alzheimers Dis Other Demen 33(8): 541-7. (2018).
[25]
Giacoppo S, Galuppo M, Calabro RS, D’Aleo G, Marra A, Sessa E, et al. Heavy metals and neurodegenerative diseases: an observational study. Biol Trace Elem Res 161(2): 151-60. (2014).
[26]
Hare DJ, Faux NG, Roberts BR, Volitakis I, Martins RN, Bush AI. Lead and manganese levels in serum and erythrocytes in Alzheimer’s disease and mild cognitive impairment: results from the Australian imaging, biomarkers and lifestyle flagship study of ageing. Met Integr Biometal Sci 8(6): 628-32. (2016).
[27]
Pino A, Brescianini S, D’Ippolito C, Fagnani C, Alimonti A, Stazi MA. Discriminant analysis to study trace elements in biomonitoring: an application on neurodegenerative diseases. Ann Ist Super Sanita 41(2): 6. (2005).
[28]
Gerhardsson L, Lundh T, Minthon L, Londos E. Metal concentrations in plasma and cerebrospinal fluid in patients with Alzheimer’s disease. Dement Geriatr Cogn Disord 25(6): 508-15. (2008).
[29]
Gerhardsson L, Blennow K, Lundh T, Londos E, Minthon L. Concentrations of metals, β-amyloid and tau-markers in cerebrospinal fluid in patients with alzheimer’s disease. Dement Geriatr Cogn Disord 28(1): 88-94. (2009).
[30]
Gerhardsson L, Lundh T, Londos E, Minthon L. Cerebrospinal fluid/plasma quotients of essential and non-essential metals in patients with Alzheimer’s disease. J Neural Transm 118(6): 957-62. (2011).
[31]
Basun H, Forssell LG, Wetterberg L, Winblad B. Metals and trace elements in plasma and cerebrospinal fluid in normal aging and Alzheimer’s disease. J Neural Transm Park Dis Dement Sect 3(4): 231-58. (1991).
[32]
Hershey CO, Hershey LA, Varnes A, Vibhakar SD, Lavin P, Strain WH. Cerebrospinal fluid trace element content in dementia: clinical, radiologic, and pathologic correlations. Neurology 33(10): 1350-50. (1983).
[33]
Koseoglu E, Koseoglu R, Kendirci M, Saraymen R, Saraymen B. Trace metal concentrations in hair and nails from Alzheimer’s disease patients: Relations with clinical severity. J Trace Elem Med Biol Organ Soc Miner Trace Elem GMS 39: 124-8. (2017).
[34]
McIntosh KG, Cusack MJ, Vershinin A, Chen ZW, Zimmerman EA, Molho ES, et al. Evaluation of a prototype point-of-care instrument based on monochromatic x-ray fluorescence spectrometry: potential for monitoring trace element status of subjects with neurodegenerative disease. J Toxicol Environ Health A 75(21): 1253-68. (2012).
[35]
Szabo ST, Harry GJ, Hayden KM, Szabo DT, Birnbaum L. Comparison of metal levels between postmortem brain and ventricular fluid in alzheimer’s disease and nondemented elderly controls. Toxicol Sci Off J Soc Toxicol 150(2): 292-300. (2016).
[36]
Uitti RJ, Rajput AH, Rozdilsky B, Bickis M, Wollin T, Yuen WK. Regional metal concentrations in Parkinson’s disease, other chronic neurological diseases, and control brains. Can J Neurol Sci J Can Sci Neurol 16(3): 310-4. (1989).
[37]
Lahiri DK, Maloney B, Zawia NH. The LEARn model: an epigenetic explanation for idiopathic neurobiological diseases. Mol Psychiatry 14(11): 992-1003. (2009).
[38]
Maloney B, Lahiri DK. Epigenetics of dementia: understanding the disease as a transformation rather than a state. Lancet Neurol 15(7): 760-74. (2016).
[39]
Basha MR. The fetal basis of amyloidogenesis: exposure to lead and latent overexpression of amyloid precursor protein and -amyloid in the aging brain. J Neurosci 25(4): 823-9.
[40]
Rodushkin I, Ödman F. Assessment of the contamination from devices used for sampling and storage of whole blood and serum for element analysis. J Trace Elem Med Biol 15(1): 40-5. (2001).
[41]
Ayton S, Lei P, Bush AI. Biometals and their therapeutic implications in Alzheimer’s disease. Neurotherapeutics 12(1): 109-20. (2015).
[42]
Yang Y-W, Liou S-H, Hsueh Y-M, Lyu W-S, Liu C-S, Liu H-J, et al. Risk of Alzheimer’s disease with metal concentrations in whole blood and urine: a case–control study using propensity score matching. Toxicol Appl Pharmacol 356: 8-14. (2018).
[43]
Grashow R, Sparrow D, Hu H, Weisskopf MG. Cumulative lead exposure is associated with reduced olfactory recognition performance in elderly men: The normative aging study. Neurotoxicology 49: 158-64. (2015).
[44]
Keil DE, Berger-Ritchie J, McMillin GA. Testing for toxic elements: a focus on arsenic, cadmium, lead, and mercury. Lab Med 42(12): 735-42. (2011).
[45]
Prince M. Is chronic low-level lead exposure in early life an etiologic factor in Alzheimer’s disease? Epidemiology 9(6): 618-21. (1998).
[46]
Zawia NH, Basha MR. Environmental risk factors and the developmental basis for Alzheimer’s disease. Rev Neurosci 16(4): 325-37. (2005).
Related Journals
Anti-Inflammatory & Anti-Allergy Agents in Medicinal Chemistry
Current Diabetes Reviews
Current Neuropharmacology
Current Neurovascular Research
Central Nervous System Agents in Medicinal Chemistry
Current Respiratory Medicine Reviews
Current Pediatric Reviews
Infectious Disorders - Drug Targets
Endocrine, Metabolic & Immune Disorders - Drug Targets
Current Stem Cell Research & Therapy
Related Books
Frontiers in Clinical Drug Research-Dementia
COVID-19: Causes, Transmission, Diagnosis, and Treatment
Skeletal Muscle Health in Metabolic Diseases
Thyroid and Brain: Understanding the Actions of Thyroid Hormones in Brain Development and Function
Common Lip Diseases: A Clinical Guide
Interventional Pain Surgery
Endoscopy and Fetoscopy Techniques for the Brain and Neuroaxis
Frontiers in Stem Cell and Regenerative Medicine Research
Textbook of Advanced Dermatology: Pearls for Academia and Skin Clinics (Part 2)
Women’s Health: A Comprehensive Guide to Common Health Issues in Women
Article Metrics
54
4
1
1