Abstract
The eye is said to be the window into the brain. Alzheimer’s disease (AD) and glaucoma both being diseases of the elderly, have several epidemiological and histological overlaps in pathogenesis. Both these diseases are neurodegenerative conditions. Over the years, a consensus has developed that both may be two ends of a singular spectrum of diseases. Epidemiological studies have shown that more Alzheimer’s patients may be suffering from glaucoma than general healthy population. Retinal ganglion cell damage is a characteristic of both diseases, along with discovery of amyloid-β and tau protein deposition in the retina and aqueous humor of eye. The latter two proteins are known to be pathognomonic of AD. Other pathways such as the insulin receptor pathway also seem to be affected in both diseases similarly. In spite of these overlaps, there are few missing links which still need more evidence, namely, intraocular pressure mechanisms, cerebrospinal fluid pressure and trans-lamina cribrosa pressure gradients, vascular autoregulation factors, etc. Several factors point towards a common pathogenesis at some level for both diseases and prospective studies are necessary to study the natural course of both diseases.
摘要
眼睛是通往大脑的窗户。阿尔兹海默症 (Alzheimer’s disease, AD) 与青光眼均为老年性疾病, 在发病机制、流行病学以及组织病理学上有相同之处, 另外它们都是神经退行性疾病。多年来, 已经达成共识, 即这两者可能属于同一疾病谱。流行病学研究表明阿尔兹海默症患者青光眼的发病人数比一般健康人群多。视网膜神经节细胞损伤是这两种疾病的共同特征, 另外在视网膜和房水中发现β-淀粉样蛋白和tau蛋白沉积物, 后两种蛋白被认为是AD的病理学特征。其他通路如胰岛素受体通路在这两种疾病中均相似地受到影响。尽管两种疾病存在以上交叉, 但在球内压力机制、脑脊液压力和跨筛板压力梯度、血管自动调节因子等方面仍缺乏需要更多证据支持的关联。一些因素在一些程度上已经阐释了这两种疾病的共同发病机制, 前瞻性研究需要研究这两种疾病的自然病程.
Similar content being viewed by others
Background
Alzheimer’s dementia (AD) is the most common cause of dementia worldwide, which leads to a substantial reduction in activities of daily living among the affected population. AD manifests in the elderly population along with other comorbidities and we are at a very early stage of determining the risk factors associated with it. As age is the most important known risk factor and the average age of the global population is on the rise, it is imperative for us to identify the early changes of Alzheimer’s and correlate with the other comorbidities that are present in this age range to establish any missing links in the development of the dreaded condition. Glaucoma is another multifactorial neurodegenerative condition affecting various age groups leading to irreversible loss of vision. Glaucoma for the aged population mainly refers to open angle glaucoma (OAG). Over the years it has been realized that although intraocular pressure (IOP) is the only modifiable and definitely measurable risk factor associated with glaucoma, a background neurodegeneration in the retina and optic nerve is responsible for the visual function loss in these eyes. The pathogenesis of this neurodegeneration has been the topic of recent studies. Present research points to a link between neurodegeneration in the brain and the optic nerve and inner retinal layers, which are an extension of the central nervous system in the form of a peripheral sense organ (the eye). In this review, we have tried to look into the common pathways involved in the pathogenesis and possibilities in management of these diseases that the future may hold for us.
Overlapping features of AD and glaucoma
Epidemiology
Increasing age is a well-known risk factor for AD [1]. Studies have investigated the occurrence of glaucoma especially OAG in AD patients. The Beaver Dam study found that subjects of ages >75 years had a 4.7% prevalence of glaucoma (OAG) as compared with <1% in subjects <55 years [2]. Also, The Baltimore Eye Survey showed that irrespective of race, a higher prevalence of open angle glaucoma was associated with increasing age [3].
Bayer et al. had described the presence of glaucomatous field changes along with cup/disk ratio >0.8 in 29 out of 112 AD patients in a German population [4]. This indicated a prevalence of 25.9% in these patients, as compared with 2.6–4.7% in the general population, as revealed in a number of glaucoma surveys [4]. Moreover, ocular hypertension with normal visual fields and optic nerve heads was also not observed in AD group, as compared with 7.8% in the normal population, thereby suggesting that the optic nerve in AD patients may be less resistant to elevated IOP [4]. Tamura et al. studied 172 AD patients in Japanese population and found that OAG was found in 23.8% of AD patients as compared with 9.9% in healthy controls (n = 176) [5]. A retrospective chart review of Canadian AD patients (age > 66 years) found the prevalence of glaucoma as 6.8%, compared with 4.1% in the age-matched control group (p = 0.02) [6].
Approaching the idea in the reverse direction, cognitive status assessment has also been performed for elderly patients with glaucoma in some studies. Yochim et al. evaluated a sample of 41 patients of glaucoma (mean age 70 ± 9.2 years, 70% females) with a battery of dementia questionnaires to assess the cognitive status. After controlling for age, 44% of patients showed an obvious cognitive impairment, while 12.2% had a mild cognitive impairment [7]. In contrast to this, Kessing et al. evaluated a Danish population with OAG (n = 11,721) and found no association with increased rate of AD development. However, since their study included patients identified by hospital admissions for surgeries, they may have included the most advanced stages of glaucoma leading to selection bias; moreover, a comorbidity matching was also not performed [8].
Recent retrospective studies also have found a positive association between OAG and AD. Lin et al. demonstrated that OAG patients were at a higher risk of AD with an incidence rate of 2.85 per 1000 person-years over a period of 8 years follow-up [9]. In 1351 Taiwanese newly diagnosed AD patients aged >65 years, Lai et al. evaluated the prevalence of glaucoma and compared it against 5329 non-dementia controls, and found an adjusted odds ratio of 1.50 for AD subjects with glaucoma [10]. Compared with retrospective case series, propensity matched longitudinal follow-up studies have come up with more reliable data regarding the association. Ou et al. evaluated OAG patients (n = 63,325; both high and normal tension) aged 68+ years and matched control population (by propensity score matching) without having a diagnosis of AD or other dementia and followed them up for 14 years [11]. They found that there were no statistically significant differences in the percentage of persons in both groups diagnosed with AD or other dementia. Moreover, without controlling for other covariates (retinal degeneration, cataract, gender, race, age, etc), persons with OAG had a reduced rate of AD diagnosis compared with non-OAG controls. However, even this study may have suffered from hidden biases, since AD may have manifested prior to OAG and the available methods of detection might not have picked up the diagnosis of AD or a subclinical cognitive impairment. Moon et al. evaluated 1469 OAG patients and 7345 nonglaucomatous subjects (propensity score matched) over a 10-year follow-up period in Korea. They observed that the OAG group had a significantly higher incidence of AD. Moreover, the risk of developing AD in OAG patients was higher in older age groups (ages > 65 years). However, again the underestimation of the final diagnosis may have been a limitation in this study [12].
OAG includes high-tension glaucoma and normal tension glaucoma (NTG) and currently the consensus regarding absolute distinction between the two patterns of diseases is not well-defined; however, it may be prudent to comment on their association with AD separately. In relation with NTG, however, there are conflicting reports. Bach-Holm et al. identified 69 Danish patients with a diagnosis of NTG with an average follow-up of 12.7 years and found that none of them developed AD [13]. Interestingly, a lot of these NTG patients were using topical alpha-adrenergic agonists (Brimonidine). Based on the recent hypothesis that brimonidine has an additional neuroprotective action in glaucomatous eyes, it has been under investigation for use in AD patients also [14]. However, Bayer et al. have studied NTG in the AD patients and have found a prevalence of 50% NTG in the AD population [4]. Tamura et al. have also found NTG in almost all of their AD subjects [5]. Chen et al. evaluated 15,317 Taiwanese NTG patients (mean age 62.1 ± 12.5 years) and compared them with 61,268 age- and gender-matched controls without glaucoma. NTG patients were seen to have significantly higher cumulative hazard for AD than controls (p < 0.0001). Moreover, after adjustment for confounders, NTG group was found to have a significantly higher risk of AD (adjusted hazards ratio 1.52) [15].
Studies on NTG have found a raised level of neurotoxic amyloid-β in the plasma, which is also a typical finding in AD [4]. These studies formed the basis of the possibility of glaucoma being a manifestation of AD in the eye, calling it the ocular AD [16]. Considering this overlap of glaucoma and AD, some trials had been designed with Memantine (NMDA-receptor antagonist) for OAG, a neuroprotective drug used in AD. However, results from studies were inconclusive in this regard [17]. A recent randomized controlled trial evaluated the effectiveness of oral memantine in OAG population and found that daily memantine treatment did not delay the progression of glaucomatous damage [18]. Recently, clinical trials are being designed to focus on developing neuroprotective treatments for NTG patients and have not included the glaucoma patients with high IOP [13]. Chen et al. found that the glaucoma eye drops used in their NTG patients were neither significant risk factors nor protective factors for development of AD [15].
Genetic overlaps
Several studies have observed genetic overlaps between AD and glaucoma. The genotype of the Apolipoprotein E (APOE) gene has been studied most commonly in this regard, since it is one of the major risk factors for AD. APOE is important in lipid metabolism and transport of cholesterol and triglyceride [19,20,21,22].
In the retina, ApoE protein is synthesized by Müller cells, absorbed by RGCs and transported to the optic nerve and this is a cycle of metabolism and neuronal survival for the RGCs. ApoE is also involved in other cellular functions, such as tissue repair, cell growth and differentiation, and immune mechanisms [23]. Copin et al. found that polymorphism of APOE promoter gene may affect visual field loss and optic nerve damage in POAG patients [24].
There was no proper consensus about the exact association between APOE gene and POAG, even after multiple studies had been done. A recent metanalysis included 12 such studies on APOE gene and POAG. The authors found significant association between APOE gene and POAG in the genetic models of ε4/ε4 versus ε3/ε3 and concluded that ε4/ε4 genotype is associated with increased risk of OAG among Asians [25]. Moreover, this risk was not different between high-pressure glaucoma and NTG populations [25]. Individuals with APOE ε4 have been seen to have severe amyloid plaques, neurofibrillary tangles, and more mitochondrial damage than patients with other polymorphisms [26]. Similarly, APOE polymorphisms in OAG may lead to increased degeneration of RGCs and axons.
In contrast to the above findings, Tamura et al. had reported the prevalence of APOE ε4 in AD patients with and without OAG, and found no significant difference, thereby suggesting that other genetic factors apart from APOE may be responsible for their association.
Pathological changes
Retinal ganglion cells and nerve fiber layer
Histopathological changes of an Alzheimer’s brain, namely neuronal apoptosis, amyloid-β plaques, neurofibrillary tangles, and vacuolar degeneration have also been observed within the retina [27,28,29]. On autopsy analysis of specimens of retina from AD patients, apart from an extensive optic nerve axonal degeneration, a reduction in the number of retinal ganglion cells (RGCs) in the ganglion cell layer (GCL) has also been observed [29, 30]. Nerve fiber layer thinning has been hypothesized to occur due to a degeneration of the RGC axons, which may precede the cognitive impairment in AD [31, 32]. Histologically observed loss of large M cells of the GCL has been postulated to be responsible for contrast sensitivity dysfunction in AD [31,32,33]. This progressive death of neurons and accumulation of neurofibrillary tangles (tau protein) and amyloid-β plaques may also damage the lateral geniculate body neurons connected to the damaged RGCs and affect various layers and cell types within the cortex, destroying the cortical pathways of higher learning and leading to cortico-cortical disconnection [34]. It has been proposed that GCL thinning may be an important prognostic indicator for AD patients [35].
Optical coherence tomography (OCT) has become a very useful noninvasive tool for diagnosis of macular diseases and optic disc changes, with various currently available algorithms to separately analyze the individual layers of the retina [36]. Retinal nerve fiber layer thinning has been noted in a number of studies conducted in AD patients using OCT [37]. This degeneration of nerve fiber layer in AD patients has been seen to occur in all quadrants of the optic disc, with a preference towards the superior and inferior quadrants, the reason for which is unknown [38, 39]. This nerve fiber layer thinning has been believed to be secondary to damage to ganglion cell bodies [31, 32].
OCT studies in glaucoma have found a preferential thinning of nerve fiber layer in the superior and inferior quadrants, similar to that seen in AD [40]. RGCs are the end point of damage in glaucoma patients as well [41]. Glaucomatous changes manifest as nerve fiber layer thinning and glial cell activation secondary to RGC apoptosis, which has also been observed in AD [38, 42,43,44,45]. The loss of the RGCs, their axons and the final loss of supporting glial cells leads to the excavation of the optic nerve head characteristic of glaucoma [46]. The damage to RGCs occurs by means of various combinations of apoptosis, oxidative stress, mitochondrial dysfunction, excitotoxicity, and insulin resistance [47,48,49].
Amyloid precursor protein and beta-amyloid
RGC and retinal pigment epithelial cells are responsible for amyloid precursor protein (APP) synthesis and secretion in the posterior segment of the eye [50]. Healthy individuals process APP with alpha-esterase into alpha-amyloid. However, in diseased individuals, APP is converted into beta-amyloid by beta-esterase. Beta-amyloid may reach toxic levels with a high penetrance, aggressively targeting neurons [51, 52]. Caspases 3 and 9 have been linked to APP misprocessing which eventually leads to cellular death [53,54,55]. The amyloid metabolism may be guided by caspase-activation in both glaucoma and AD.
Few studies have reported a deposition of amyloid-β peptides in the RGC layer in AD with a possible immunological pathway of RGC destruction, which is reflected as a loss of scotopic threshold response [56,57,58]. Guo et al. demonstrated in mouse models of AD that amyloid-β levels were upregulated in RGCs of rodent retina and RGC apoptosis could be induced by injecting intravitreal amyloid-β [59]. Interestingly, hyperspectral imaging of retina strongly suggests that this early amyloid-β beta related retinal dysfunction may begin during the asymptomatic stage [60]. Recently, hyperspectral imaging was performed in patients with confirmed amyloid-β deposition in brain detected using positron emission tomography (PET), and the model developed by the authors could accurately predict brain Aβ PET status in a validation cohort of AD patients and also, in a cohort of mice model of AD [61].
Beta-amyloid deposited in extracellular spaces eventually start an inflammatory cascade by triggering TNF-alpha, cytokines, etc leading to pathological changes characteristic of AD. Neuroinflammation is also believed to be the causative factor behind the development of glaucoma and Parkinson’s disease [62]. Szekely et al. however found inconclusive evidence of beneficial effects of anti-inflammatory therapy (nonsteroidal) on neuroprotection [63].
Janciauskiene et al. have uniquely demonstrated the presence of amyloid-β peptides (A-β1-38, A-β1-40, and A-β1-42) in aqueous humor of glaucoma patients (pseudoexfoliation), strengthening the concept of a link between age-related eye diseases and AD [64, 65]. Guo et al. have demonstrated, using experimental glaucoma models, that amyloid-β colocalizes with RGCs inducing significant apoptosis in vivo in a dose- and time-dependent manner. They have further demonstrated that targeting and inhibiting different components of amyloid-β formation and aggregation pathways may be effective therapeutic strategies in glaucoma management [59].
Mitochondrial dysfunction may occur because of amyloid-β induced opening of mitochondrial pores, which may play a role in apoptosis. Moreover, Osborne et al. have observed that the mitochondria in glaucomatous RGCs are in a low energy state because of reduced vascular perfusion and are incapable of getting rid of excess reactive oxygen free radicles [66,67,68,69]. In this regard, antioxidant molecules such as Vitamins C and E and Gingko biloba have been studied for their neuroprotective effect in glaucoma [51, 70, 71].
Tau protein
Tau protein also has been postulated as a common pathogenetic factor, with its presence in cerebrospinal fluid (CSF) of AD patients and in the horizontal cells of retina, optic nerve, and peripapillary region in glaucoma patients [72,73,74,75]. In mouse models of Alzheimer’s disease, investigators have found early accumulation of tau proteins in the retina prior to beginning of cognitive defects [76]. Tau accumulation has also been observed in the cell body and dendrites of RGCs in glaucoma, leading to neuronal death [77]. Tau protein is believed to affect the overall retinal function by causing dysfunction in axonal transport and functionality [77]. The decrease of tau burden in the retina appears to have a widespread beneficial effect on the overall health of RGCs leading to improvements in axonal transport and functionality.
Till date it is unclear whether in glaucoma, axons are damaged before the ganglion cells and whether glial cells are affected before or after RGC loss as a reactionary mechanism [78]. However, in mouse models of AD, it has been observed that RGC cell bodies get affected prior to the dendrites, which also precedes the loss of dendrites in hippocampal pyramidal neurons with frank pathological changes of AD [79].
Insulin receptors and neurodegeneration
Insulin receptors (IRs) have been found to be necessary for the physiological functioning of the visual system, including the RGCs [80]. IR is a transmembrane receptor activated by insulin and is expressed in the central nervous system. Although their exact function in CNS has not been studied in detail, they are believed to be involved in neuronal functions and control many cellular processes, such as cell growth and differentiation [81]. Reduced IR expression has been seen in AD and Parkinson’s disease [82, 83]. IRs may prevent the formation and increase the degradation of AD amyloid plaques, and inhibit the neurofibrillary tangle formation [84, 85]. Human RGCs have shown expression of insulin and insulin-like growth factor (IGF-1) immunohistochemically, and may be mediators of RGC survival [86, 87]. One study found that the neurodegeneration typical of AD includes aberrations in expressions of insulin and associated genes, with more significant affection in advanced cases [82, 88]. It has been hypothesized that insulin and IGF-1 pathways control neuronal viability, tau protein expression and mitochondrial function. Insulin resistance has been reported to be associated with a rise in IOP and insulin induced hypoglycaemia lowers IOP acutely [89, 90].
Malfunctioning of IRs thus play a role in neurodegeneration and may be a common risk factor responsible for AD and glaucoma. Further studies are needed to elucidate this mechanism.
Missing links
Intraocular pressure
Although IOP is a modifiable risk factor for glaucomatous damage, previous damage to optic nerve head due to chronic raised IOP is mostly irreversible. It has been noted that an abnormally high trans-lamina cribrosa pressure difference, due to high IOP or low cerebrospinal fluid pressure (CSFP), may result in glaucomatous optic nerve damage [91]. Moreover, rather than steady stress, repeated mechanical stress due to fluctuating IOP may be more harmful to the optic nerve head neurons with faster progression of visual field damage [92,93,94,95].
Cerebrospinal fluid (CSF) pressure
In a study measuring CSF pressure in glaucoma patients, it was found that CSF pressure was lowest in NTG patients, higher in HTG patients and highest in normal controls [96]. Also, the trans-lamina cribrosa pressure difference was highest in the HTG patients, followed in order by NTG patients and normal controls. In cases of normal-pressure hydrocephalus patients, trans-lamina cribrosa pressure has been seen to fluctuate, due to CSFP fluctuations and ICP is not steadily normal, unlike what the name of the disease suggests [97,98,99]. This leads to shear stress on the lamina leading to RGC degeneration. Silverberg et al. studied patients with AD and found a gross overlap between AD and normal-pressure hydrocephalus, and hypothesized that these diseases may represent two ends of CSF circulatory failure [100]. Moreover, Wostyn et al. also hypothesized that the patient groups having low to normal CSF pressure may have a causal association with glaucoma [101].
CSF changes
CSF turnover has been seen to slow down with age, secondary to reduced secretion and resistance to drainage, causing accumulation of neurotoxins along optic nerve. These ageing changes in CSF are seen in AD patients. Moreover, a new concept of CSF sequestration has been proposed by Killer et al. which states that CSF may collect around the optic nerve at the ending of the subarachnoid space leading to a compartment syndrome associated with accumulation of toxins [102]. The accumulated toxins include amyloid-β proteins, which are integral to the pathophysiology of AD.
Vascular flow regulation
Apart from elevated IOP, certain vascular dysregulation factors may contribute to the initial glaucomatous insult to the optic nerve, in the form of changes in axoplasmic flow and microcirculation at the lamina cribrosa, with additional changes in laminar connective tissues [103]. Moreover, this also leads to reduction of factors, such as brain-derived neurotrophic factor, with release of neurotoxic factors within the retina, namely glutamate, nitric oxide and free radicals. Moreover, retinal hemodynamic changes in AD patients are similar to glaucoma patients who also demonstrate narrowing of vessels with reduced flow [104]. This vascular theory suggests that glaucomatous optic neuropathy results from inadequate blood supply to the optic nerve head due to either increased IOP or risk factors causing reduced ocular blood flow [105]. The reduction in blood flow in glaucoma occurs in both early and late stages [106, 107]. These vascular disturbances are more pronounced in normal-tension glaucoma [108,109,110]. Recently, damage in glaucoma has been realized as more of a reperfusion injury rather than an ischemic change [111, 112]. Postischemic injury brains have been found to contain APP plaques and phosphorylated tau protein in different parts and this has suggested an association between brain ischemia and AD [113,114,115]. General consensus has been formed that amyloid plaques and neurofibrillary tangles are products of neuronal ischemic injury [116, 117].
Conclusion
To summarize, AD and glaucoma share multiple common biochemical and pathological changes. Both AD and glaucoma are slowly progressing age-related neurodegenerative disorders and may after all be manifestations of the same pathogenetic process with heterogenous presentations. We have collated certain overlapping epidemiological and pathologic changes that link the two diseases. But some missing links need to be further explored to better understand the relation between the two pathologies. Long-term prospective cohort studies are required to determine natural history of AD and its relation to glaucoma and related disorders.
References
Guerreiro R, Bras J. The age factor in Alzheimer’s disease. Genome Med. 2015;7:106.
Klein BE, Klein R, Sponsel WE, Franke T, Cantor LB, Martone J, et al. Prevalence of glaucoma. The Beaver Dam Eye Study. Ophthalmology. 1992;99:1499–504.
Tielsch JM, Sommer A, Katz J, Royall RM, Quigley HA, Javitt J. Racial variations in the prevalence of primary open-angle glaucoma. The Baltimore Eye Survey. J Am Med Assoc. 1991;266:369–74.
Bayer AU, Ferrari F, Erb C. High occurrence rate of glaucoma among patients with Alzheimer’s disease. Eur Neurol. 2002;47:165–8.
Tamura H, Kawakami H, Kanamoto T, Kato T, Yokoyama T, Sasaki K, et al. High frequency of open-angle glaucoma in Japanese patients with Alzheimer’s disease. J Neurol Sci. 2006;246:79–83.
Pelletier AA, Théorět MÈ, Boutin T, Kergoat MJ, Massoud F, Latour J, et al. Prevalence of glaucoma in hospitalized older adults with Alzheimer’s disease. Can J Neurol Sci. 2014;41:206–9.
Yochim BP, Mueller AE, Kane KD, Kahook MY. Prevalence of cognitive impairment, depression, and anxiety symptoms among older adults with glaucoma. J Glaucoma. 2012;21:250–4.
Kessing LV, Lopez AG, Andersen PK, Kessing SV. No increased risk of developing Alzheimer disease in patients with glaucoma. J Glaucoma. 2007;16:47–51.
Lin IC, Wang YH, Wang TJ, Wang IJ, Shen YD, Chi NF, et al. Glaucoma, Alzheimer’s disease, and Parkinson’s disease: an 8-year population-based follow-up study. PLoS ONE 2014;9:e108938.
Lai SW, Lin CL, Liao KF. Glaucoma may be a non-memory manifestation of Alzheimer’s disease in older people. Int Psychogeriatr. 2017;29:1–7.
Ou Y, Grossman DS, Lee PP, Sloan FA. Glaucoma, Alzheimer’s disease and other dementia: a longitudinal analysis. Ophthalmic Epidemiol. 2012;19:285–9.
Moon JY, Kim HJ, Park YH, Park TK, Park EC, Kim CY, et al. Association between Open-Angle Glaucoma and the Risks of Alzheimer’s and Parkinson’s Diseases in South Korea: A 10-year Nationwide Cohort Study. Sci Rep. 2018;24:11161.
Bach-Holm D, Kessing SV, Mogensen U, Forman JL, Andersen PK, Kessing LV. Normal tension glaucoma and Alzheimer disease: comorbidity? Acta Ophthalmol. 2012;90:683–5.
Krupin T. A clinical trial studying neuroprotection in low-pressure glaucoma. Eye. 2007;21:S51–4.
Chen Y-Y, Lai Y-J, Yen Y-F. Association between normal tension glaucoma and the risk of Alzheimer’s disease: a worldwide population-based cohort study in Taiwan. BMJ Open 2018;8:e022987.
McKinnon SJ. Glaucoma: ocular Alzheimer’s disease? Front Biosci. 2003;1:1140–56.
Osborne NN. Recent clinical findings with memantine should not mean that the idea of neuroprotection in glaucoma is abandoned. Acta Ophthalmol. 2009;87:450–4.
Weinreb RN, Liebman JM, Cioffi GA, Goldberg I, Brandt JD, Johnson CA, et al. Oral memantine for the treatment of glaucoma: design and results of 2 randomised, placebo-controlled, phase 3 studies. Ophthalmol. 2018. https://doi.org/10.1016/j.ophtha.2018.06.017.
Ordovas JM, Schaefer EJ. Genetic determinants of plasma lipid response to dietary intervention: the role of the APOA1/C3/A4 gene cluster and the APOE gene. Br J Nutr. 2000;83 Suppl 1 :S127–36.
Eichner JE, Dunn ST, Perveen G, Thompson DM, Stewart KE, Stroehla BC. Apolipoprotein E polymorphism and cardiovascular_disease: review. Am J Epidemiol. 2002;155:487–95.
Dallongeville J, Lussier-Cacan S, Davignon J. Modulation of plasma triglyceride levels by apoE phenotype: a meta-analysis. J Lipid Res. 1992;33:447–54.
Lahiri DK, Sambamurti K, Bennett DA. Apolipoprotein gene and its interaction with the environmentally driven risk factors: molecular, genetic and epidemiological studies of Alzheimer’s disease. Neurobiol Aging. 2004;25:651–60.
Amaratunga A, Abraham CR, Edwards RB, Sandell JH, Schreiber BM, Fine RE. Apolipoprotein E is synthesized in the retina by Muller glial cells, secreted into the vitreous, and rapidly transported into the optic nerve by retinal ganglion cells. J Biol Chem. 1996;271:5628–32.
Copin B, Brezin AP, Valtot F, Dascotte JC, Bechetoille A, Garchon HJ. Apolipoprotein E-promoter single-nucleotide polymorphisms affect the phenotype of primary open-angle glaucoma and demonstrate interaction with the myocilin gene. Am J Hum Genet. 2002;70:1575–81.
Liao R, Ye M, Xu X. An updated meta-analysis: apolipoprotein E genotypes and risk of primary open-angle glaucoma. Mol Vis. 2014;20:1025–36.
Bekris LM, Yu CE, Bird TD, Tsuang DW. Genetics of Alzheimer disease. J Geriatr Psychiatry Neurol. 2010;23:213–27.
Whitehouse P, Price D, Clark A, Coyle J, DeLong M. Alzheimer disease: evidence for selective loss of cholinergic neurons in the nucleus basalis. Ann Neurol. 1981;10:122–6.
van de Nes J, Nafe R, Schlote W. Non-tau based neuronal degeneration in Alzheimer’s disease-an immunocytochemical and quantitative study in the supragranular layers of the middle temporal neocortex. Brain Res. 2008;1213:152–65.
Hinton D, Sadun A, Blanks J, Miller C. Optic-nerve degeneration in Alzheimer’s disease. N. Engl J Med. 1986;315:485–7.
Sadun A, Bassi C. Optic nerve damage in Alzheimer’s disease. Ophthalmology 1990;97:9–17.
Ascaso FJ, Cruz N, Modrego PJ, Lopez-Anton R, Santabarbara J, Pascual LF, et al. Retinal alterations in mild cognitive impairment and Alzheimer’s disease: an optical coherence tomography study. J Neurol. 2014;261:1522–30.
Garcia-Martin ES, Rojas B, Ramirez A, de Hoz R, Salazar RJ, Yubero R, et al. Macular thickness as a potential biomarker of mild Alzheimer’s disease. Ophthalmology. 2014;121:1149–53.
Livingstone MS, Hubel DH. Psychophysical evidence for separate channels for the perception of form, color, movement, and depth. J Neurosci. 1987;7:3416–68.
Braak H, Braak E. Staging of Alzheimer-related cortical destruction. Int Psychogeriatr. 1997;9:257–61.
Cheung CY, Ong YT, Hilal S, Ikram MK, Low S, Ong YL, et al. Retinal ganglion cell analysis using high-definition optical coherence tomography in patients with mild cognitive impairment and Alzheimer’s disease. J Alzheimer’s Dis. 2015;45:45–56.
Jaffe GJ, Caprioli J. Optical coherence tomography to detect and manage retinal disease and glaucoma. Am J Ophthalmol. 2004;137:156–69.
Iseri PK, Altinaş O, Tokay T, Yüksel N. Relationship between cognitive impairment and retinal morphological and visual functional abnormalities in Alzheimer disease. J Neuroophthalmol. 2006;26:18–24.
Blanks JC, Schmidt SY, Torigoe Y, Porrello KV, Hinton DR, Blanks RH. Retinal pathology in Alzheimer’s disease. II. Regional neuron loss and glial changes in GCL. Neurobiol Aging 1996;17:385–95.
Blanks JC, Torigoe Y, Hinton DR, Blanks RH. Retinal pathology in Alzheimer’s disease. I. Ganglion cell loss in foveal/parafoveal retina. Neurobiol Aging 1996;17:377–84.
Parisi V. Correlation between morphological and functional retinal impairment in patients affected by ocular hypertension, glaucoma, demyelinating optic neuritis and Alzheimer’s disease. Semin Ophthalmol. 2003;18:50–7.
Weinreb RN, Khaw PT. Primary open-angle glaucoma. Lancet. 2004;363:1711–20.
Blanks JC, Hinton DR, Sadun AA, Miller CA. Retinal ganglion cell degeneration in Alzheimer’s disease. Brain Res. 1989;6:364–72.
Blanks JC, Torigoe Y, Hinton DR, Blanks RH. Retinal pathology in Alzheimer’s disease. Ganglion cell loss in foveal/parafoveal retina. Neurobiol Aging. 1996;17:377–84.
Hedges TR, Perez Galves R, Speigelman D, Barbas NR, Peli E, Yardley CJ. Retinal nerve fiber layer abnormalities in Alzheimer’s disease. Acta Ophthalmol Scand. 1996;74:271–5.
Flammer J, Mozaffarieh M. What is the present pathogenetic concept of glaucomatous optic neuropathy? Surv Ophthalmol. 2007;52:162–73.
Hernandez MR. The optic nerve head in glaucoma: role of astrocytes in tissue remodeling. Prog Retin Eye Res. 2000;19:297–321.
Cheung W, Guo L, Cordeiro MF. Neuroprotection in glaucoma: drug-based approaches. Optom Vis Sci. 2008;85:406–16.
Kumar M, Tanwar M, Faiq MA, Pani J, Shamsi MB, Dada T, et al. Mitochondrial DNA nucleotide changes in primary congenital glaucoma patients. Mol Vis. 2013;19:220–30.
Tanwar M, Dada T, Sihota R, Dada R. Mitochondrial DNA analysis in primary congenital glaucoma. Mol Vis. 2010;16:518–33.
Ohno-Matsui K. Parallel findings in age-related macular degeneration and Alzheimer’s disease. Prog Retin Eye Res. 2011;30:217–38.
Hardy J, Selkoe DJ. The amyloid hypothesis of Alzheimer’s disease: progress and problems on the road to therapeutics. Science. 2002;297:353–6.
Benilova I, Karran E, De SB. The toxic Abeta oligomer and Alzheimer’s disease: an emperor in need of clothes. Nat Neurosci. 2012;15:349–57.
McKinnon SJ1, Lehman DM, Kerrigan-Baumrind LA, Merges CA, Pease ME, Kerrigan DF, et al. Caspase activation and amyloid precursor protein cleavage in rat ocular hypertension. Investig Ophthalmol Vis Sci. 2002;43:1077–87.
Elmore S. Apoptosis: a review of programmed cell death. Toxicol Pathol. 2007;35:495–516.
Gupta A. Leptin as a neuroprotective agent in glaucoma. Med Hypoth. 2012;81:797–802.
Alexandrov PN, Pogue A, Bhattacharjee S, Lukiw WJ. Retinal amyloid peptides and complement factor H in transgenic models of Alzheimer’s disease. Neuroreport. 2011;22:623–27.
Dutescu RM, Li QX, Crowston J, Masters CL, Baird PN, Culvenor JG, et al. Amyloid precursor protein processing and retinal pathology in mouse models of Alzheimer’s disease. Graefe’s Arch Clin Exp Ophthalmol. 2009;47:1213–21.
Gupta VK, Chitranshi N, Gupta VB, Golzan M, Dhher Y, Wall RV, et al. Amyloid beta accumulation and inner retial degeneration degenerative changes in Alzheimer’s disease transgenic mouse. Neurosci Lett. 2016;623:52–56.
Guo L, Salt TE, Luong V, Wood N, Cheung W, Maass A, et al. Targeting amyloid-beta in glaucoma treatment. Proc Natl Acad Sci. 2007;104:13444–9.
More SS, Vince R. Hyperspectral imaging signatures detect amyloidopathy in alzheimer’s mouse retina well before onset of cognitive decline. ACS Chem Neurosci. 2015;6:306–15.
Hadoux X, Hui F, Lim JKH, et al. Non-invasive in vivo hyperspectral imaging of the retina for potential biomarker use in Alzheimer’s disease. Nat Commun. 2019;10:4227. https://doi.org/10.1038/s41467-019-12242-1.
McKinnon SJ. The cell and molecular biology of glaucoma: common neurodegenerative pathways and relevance to glaucoma. Investig Ophthalmol Vis Sci. 2012;53:2485–7.
Szekely CA, Zandi PP. NSAIDs and Alzheimer’s disease: the epidemiological evidence. CNS Neurol Disord Drug Targets. 2010;9:132–9.
Janciauskiene S, Westin K, Grip O, Krakau T. Detection of Alzheimer peptides and chemokines in the aqueous humor. Eur J Ophthalmol. 2011;21:104–11.
Janciauskiene S, Krakau T. Alzheimer’s peptide and serine proteinase inhibitors in glaucoma and exfoliation syndrome. Doc Ophthalmol. 2003;106:215–23.
Loeffler KU, Edward DP, Tso MO. Tau-2 immunoreactivity of corpora amylacea in the human retina and optic nerve. Investig Ophthalmol Vis Sci. 1993;34:2600–3.
Osborne NN, Lascaratos G, Bron AJ, Childlow G, Wood JP. A hypothesis to suggest that light is a risk factor in glaucoma and the mitochondrial optic neuropathies. Br J Ophthalmol. 2006;90:237–41.
Osborne NN, Alvarez CN, Del Olmo Aguado S. Targeting mitochondrial dysfunction as in aging and glaucoma. Drug Discov Today. 2014;19:1613–22.
Osborne NN, Del Olmo, Aguado S. Maintenance of retinal ganglion cell mitochondrial functions as a neuroprotective strategy in glaucoma. Curr Opin Pharm. 2013;13:16–22.
Osborne NN. Mitochondria: their role in ganglion cell death and survival in primary open angle glaucoma. Exp Eye Res. 2010;90:750–7.
Izzotti A, Bagnis A, Sacca SC. The role of oxidative stress in glaucoma. Mutat Res. 2006;612:105–14.
Jensen M, Basun H, Lannfelt L. Increased cerebrospinal fluid tau in patients with Alzheimer’s disease. Neurosci let. 1995;186:189–91.
Gupta N, Fong J, Ang LC, Yucel YH. Retinal tau pathology in human glaucomas. Can J Ophthalmol. 2008;43:53–60.
Gasparini L, Crowther RA, Martin KR, Berg N, Coleman M, Goedert M, et al. Tau inclusions in retinal ganglion cells of human P301S tau transgenic mice: effects on axonal viability. Neurobiol Aging. 2011;32:419–33.
Schon C, Hoffmann NA, Ochs SM, Burgold S, Filser S, Steinbach S, et al. Long-term in vivo imaging of fibrillar tau in the retina of P301S transgenic mice. PLoS ONE 2012;7:e53547.
Stover KR, Campbell MA, Van Winssen CM, Brown RE. Early detection of cognitive deficits in the 3xTg-AD mouse model of Alzheimer’s disease. Behav Brain Res. 2015;289:29–38.
Chiasseu M, Cueva Vargas JL, Destroismaisons L, Vande Velde C, Leclerc N, Di Polo A. Tau accumulation, altered phosphorylation, and missorting promote neurodegeneration in glaucoma. J Neurosci. 2016;25:5785–98.
Dilsiz N, Sahaboglu A, Yildiz MZ, Reichenbach A. Protective effects of various antioxidants during ischemia-reperfusion in the rat retina. Graefes Arch Clin Exp Ophthalmol. 2006;244:627–33.
Agapova OA, Ricard CS, Salvador-Silva M, Hernandez MR. Expression of matrix metalloproteinases and tissue inhibitors of metalloproteinases in human optic nerve head astrocytes. Glia. 2001;33:205–16.
Williams PA, Thirgood RA, Oliphant H, Frizzati A, Littlewood E, Votruba M, et al. Retinal ganglion cell dendritic degeneration in a mouse model of Alzheimer’s disease. Neurobiol Aging. 2013;34:1799–806.
Fischer AJ, Dierks BD, Reh TA. Exogenous growth factors induce the production of ganglion cells at the retinal margin. Development. 2002;129:2283–91.
Choi J, Ko J, Racz B, Burette A, Lee JR, Kim S, et al. Regulation of dendritic spine morphogenesis by insulin receptor substrate 53, a downstream effector of Rac1 and Cdc42 small GTPases. J Neurosci. 2005;25:869–79.
Steen E, Terry BM, Rivera EJ, Cannon JL, Neely TR, Tavares R, et al. Impaired insulin and insulin-like growth factor expression and signaling mechanisms in Alzheimer’s disease—is this type 3 diabetes? J Alzheimers Dis. 2005;7:63–80.
Moroo I, Yamada T, Makino H, Tooyama I, McGeer PL, McGeer EG, et al. Loss of insulin receptor immunoreactivity from the substantia nigra pars compacta neurons in Parkinson’s disease. Acta Neuropathol. 1994;87:343–8.
Zhao L, Teter B, Morihara T, Lim GP, Ambegaokar SS, Ubeda OJ, et al. Insulindegrading enzyme as a downstream target of insulin receptor signalling cascade: implications for Alzheimer’s disease intervention. J Neurosci. 2004;24:11120–6.
Farris W, Mansourian S, Chang Y, Lindsley L, Eckman EA, Frosch MP, et al. Insulin-degrading enzyme regulates the levels of insulin, amyloid betaprotein, and the beta-amyloid precursor protein intracellular domain in vivo. Proc Natl Acad Sci USA. 2003;100:4162–7.
Qian W, Shi J, Yin X, Iqbal K, Grundke-Iqbal I, Gong CX, et al. PP2A regulates tau phosphorylation directly and also indirectly via activating GSK-3beta. J Alzheimers Dis. 2010;19:1221–9.
Rodrigues M, Waldbillig RJ, Rajagopalan S, Hackett J, LeRoith D, Chader GJ. Retinal insulin receptors: localization using a polyclonal anti-insulin receptor antibody. Brain Res. 1988;443:389–94.
de la Monte SM, Wands JR. Alzheimer’s disease is type 3 diabetes-evidence reviewed. J Diabetes Sci Technol. 2008;2:1101–13.
Oh SW, Lee S, Park, Kim DJ. Elevated intraocular pressure is associated with insulin resistance and metabolic syndrome. Diabetes Metab Res Rev. 2005;21:434–40.
Hepburn DA, Fisher BM, Thomson I, Barrie T, Frier BM. Autonomic mechanisms underlying intraocular pressure changes during insulininduced hypoglycaemia in normal human subjects: effects of pharmacological blockade. Clin Sci. 1991;80:333–8.
Berdahl JP, Allingham RR, Johnson DH. Cerebrospinal fluid pressure is decreased in primary open-angle glaucoma. Ophthalmology. 2008;115:763–8.
Edwards ME, Wang SS, Good TA. Role of viscoelastic properties of differentiated SH-SY5Y human neuroblastoma cells in cyclic shear stress injury. Biotechnol Prog. 2001;17:760–7.
Singh K, Shrivastava A. Intraocular pressure fluctuations: how much do they matter? Curr Opin Ophthalmol. 2009;20:84–7.
Bengtsson B, Leske MC, Hyman L, Heijl A. Early manifest glaucoma trial group. Fluctuation of intraocular pressure and glaucoma progression in the early manifest glaucoma trial. Ophthalmology. 2007;114:205–9.
Flammer J, Orgül S, Costa VP, Orzalesi N, Krieglstein GK, Serra LM, et al. The impact of ocular blood flow in glaucoma. Prog Retin Eye Res. 2002;21:359–93.
Ren R, Jonas JB, Tian G, Zhen Y, Ma K, Li S, et al. Cerebrospinal fluid pressure in glaucoma: a prospective study. Ophthalmology. 2010;117:259–66.
Chang TC, Singh K. Glaucomatous disease in patients with normal pressure hydrocephalus. J Glaucoma. 2009;18:243–6.
Wostyn P, Audenaert K, De Deyn PP. Alzheimer’s disease-related changes in diseases characterized by elevation of intracranial or intraocular pressure. Clin Neurol Neurosurg. 2008;110:101–9.
Silverberg G, Mayo M, Saul T, Fellmann J, McGuire D. Elevated cerebrospinal fluid pressure in patients with Alzheimer’s disease. Cerebrospinal Fluid Res. 2006;3:7.
Wostyn P, Audenaert K, De Deyn PP. Alzheimer’s disease and glaucoma: is there a causal relationship? Br J Ophthalmol. 2009;93:1557–9.
Killer HE, Jaggi GP, Flammer J, Miller NR. Is open-angle glaucoma caused by impaired cerebrospinal fluid circulation: around the optic nerve? Clin Exp Ophthalmol. 2008;36:308–11.
Venkataraman ST, Flanagan JG, Hudson C. Vascular reactivity of optic nerve head and retinal blood vessels in glaucoma-a review. Microcirculation. 2011;17:568–81.
Moore D, Harris A, Wudunn D, Kheradiya N, Siesky B. Dysfunctional regulation of ocular blood flow: a risk factor for glaucoma? Clin Ophthalmol. 2008;2:849–61.
Flammer J. The vascular concept in glaucoma. Surv Ophthalmol. 1994;38:S3–6.
Michelson G, Langhans MJ, Harazny J, Dichtl A. Visual field defect and perfusion of the juxtapapillary retina and the neuroretinal rim area in primary open-angle glaucoma. Graefes Arch Clin Exp Ophthalmol. 1998a;236:80–5.
Michelson G, Welzenbach J, Pal I, Harazny J. Automatic full field analysis of perfusion images gained by scanning laser Doppler flowmetry. Br J Ophthalmol. 1998b;82:1294–1300.
Harju M, Vesti E. Blood flow of the optic nerve head and peripapillary retina in exfoliation syndrome with unilateral glaucoma or ocular hypertension. Graefes Arch Clin Exp Ophthalmol. 2001;239:271–7.
Yin ZQ, Vaegan, Millar TJ, Beaumont P, Sarks S. Widespread choroidal insufficiency in primary open-angle glaucoma. J Glaucoma. 1997;6:23–32.
Drance S, Anderson DR, Schulzer M. Risk factors for progression of visual field abnormalities in normal-tension glaucoma. Am J Ophthalmol. 2001;131:699–708.
Flammer J, Kaiser H, Haufschild T. Susac syndrome: a vasospastic disorder? Eur J Ophthalmol. 2001a;11:175–9.
Flammer J, Pache M, Resink T. Vasospasm, its role in the pathogenesis of diseases with particular reference to the eye. Prog Retin Eye Res. 2001b;20:319–49.
Pluta R. The role of apolipoprotein E in the deposition of β-amyloid peptide during ischemia–reperfusion brain injury. A model of early Alzheimer’s disease. Ann NY Acad Sci. 2000a;903:324–34.
Pluta R, Jabłoński M, Czuczwar SJ. Postischemic dementia with Alzheimer phenotype: selectively vulnerable versus resistant areas of the brain and neurodegeneration versus β-amyloid peptide. Folia Neuropathol. 2012b;50:101–9.
Pluta R, Kida E, Lossinsky AS, Golabek AA, Mossakowski MJ, Wisniewski HM. Complete cerebral ischemia with short-term survival in rats induced by cardiac arrest: I. Extracellular accumulation of Alzheimer’s β-amyloid protein precursor in the brain. Brain Res. 1994b;649:323–8.
Ishimaru H, Ishikawa K, Haga S, Shoji M, Ohe Y, Haga C, et al. Accumulation of apolipoprotein E and β-amyloid-like protein in a trace of the hippocampal CA1 pyramidal cell layer after ischaemic delayed neuronal death. NeuroReport. 1996a;7:3063–7.
Armstrong RA. Plaques and tangles and the pathogenesis of Alzheimer’s disease. Folia Neuropathol. 2006;44:1–11.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
The authors declare that they have no conflict of interest.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Sen, S., Saxena, R., Tripathi, M. et al. Neurodegeneration in Alzheimer’s disease and glaucoma: overlaps and missing links. Eye 34, 1546–1553 (2020). https://doi.org/10.1038/s41433-020-0836-x
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1038/s41433-020-0836-x
