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Review

Nanotechnology-based drug delivery systems for the treatment of Alzheimer’s disease

Bruno Fonseca-SantosDepartment of Drugs and Medicines, School of Pharmaceutical Sciences, São Paulo State University (UNESP), Araraquara, São Paulo, Brazil

Maria Palmira Daflon GremiãoDepartment of Drugs and Medicines, School of Pharmaceutical Sciences, São Paulo State University (UNESP), Araraquara, São Paulo, Brazil

Marlus ChorilliDepartment of Drugs and Medicines, School of Pharmaceutical Sciences, São Paulo State University (UNESP), Araraquara, São Paulo, BrazilCorrespondence[email protected]

Abstract

Alzheimer’s disease is a neurological disorder that results in cognitive and behavioral impairment. Conventional treatment strategies, such as acetylcholinesterase inhibitor drugs, often fail due to their poor solubility, lower bioavailability, and ineffective ability to cross the blood–brain barrier. Nanotechnological treatment methods, which involve the design, characterization, production, and application of nanoscale drug delivery systems, have been employed to optimize therapeutics. These nanotechnologies include polymeric nanoparticles, solid lipid nanoparticles, nanostructured lipid carriers, microemulsion, nanoemulsion, and liquid crystals. Each of these are promising tools for the delivery of therapeutic devices to the brain via various routes of administration, particularly the intranasal route. The objective of this study is to present a systematic review of nanotechnology-based drug delivery systems for the treatment of Alzheimer’s disease.

Keywords:

Introduction

Alzheimer’s disease (AD) is an acquired disorder of cognitive and behavioral impairment that is an incurable disease with a long and progressive course.^Citation1 In AD, plaques develop in the hippocampus,^Citation2 a structure deep in the brain that helps to encode memories, and in other areas of the cerebral cortex that are used in thinking and decision making.

In the US, an estimated 5.2 million people of all ages have AD. This disease is the sixth leading cause of death in the US overall and the fifth leading cause of death for those aged 65 years and older. Deaths from Alzheimer’s increased by 68% between 2000 and 2010, while deaths from human immunodeficiency virus (HIV), stroke, and heart disease decreased by 42%, 23%, and 16%, respectively. By 2050, the number of people aged 65 years and older with AD may nearly triple from 5 million to a projected 13.8 million unless medical breakthroughs are made to prevent, retard, or stop the disease progression.^Citation3

There are several limitations associated with present therapy, and the intranasal strategy seems to be a promising route for delivery of drugs to brain.^Citation4 Currently approved drugs for treating the cognitive impairments in AD are based on neurotransmitter or enzyme modulation.^Citation4 Acetylcholinesterase (AChE) inhibitors are associated with gastrointestinal adverse effects like nausea and vomiting that most commonly lead to discontinuation of treatment.^{Citation5,Citation6} Tacrine has a short half-life and needs four administrations per day.^Citation7 In addition, patients who used the drug required periodic blood monitoring due to hepatotoxicity.^Citation8 Also, galantamine and rivastigmine exhibit a half-life of 7 and 2 hours, respectively. The use of memantine can cause adverse effects as dizziness, confusion, constipation, and vomiting.^Citation9 A summary of pharmacokinetic parameters of drugs used in AD are shown in .

Table 1 Summary of the pharmacokinetic parameters of the cholinesterase inhibitors and memantine

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Therapy failure frequently occurs due to the unfavorable pharmacokinetics and pharmacodynamics of drugs.^Citation12 Pharmacotherapy failure is the result of inadequate physical chemistry of drugs (such as hydrophobicity), unfavorable absorption by biological membranes, unfavorable pharmacokinetic parameters (such as intense and plasma metabolism), instability of drugs (oxidation, hydrolysis, or photolysis), and toxicity to tissues (hepatotoxicity, neurotoxicity, or kidney toxicity).^Citation12^–^Citation14 The use of drugs in nano-platforms or nanodevices results in the enhancement of their pharmacokinetics and pharmacodynamics, as well as they can to exhibit minimal toxicity.^{Citation15,Citation16} On the one hand, an essential aspect in nanomedicine development is the controlled release of drugs into disease sites.^{Citation12,Citation14,Citation17,Citation18}

The effectiveness of a treatment can be increased by incorporating nanotechnology-based drug delivery systems.^{Citation19,Citation20} Some of these new platforms, which aim to improve the bioavailability, pharmacokinetics, and pharmacodynamics of drugs while reducing their side effects, are shown in .

Table 2 Summary of nanotechnology-based systems applied in the treatment of Alzheimer’s disease

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AD pathophysiology

AD is histopathologically characterized by a massive synaptic loss and neuronal death observed in the brain regions responsible for cognitive functions, including the cerebral cortex, hippocampus, entorhinal cortex, and ventral striatum.^Citation55 In the brain parenchyma of patients with AD, fibrillar amyloid deposits located on the walls of blood vessels are associated with a variety of different types of senile plaques, the accumulation of abnormal tau protein filaments, and the subsequent formation of neurofibrillary tangles, neuronal and synaptic loss, glial cell activation, and inflammation.^Citation55 Two hypotheses have been proposed for the etiology and pathophysiology of AD: the first hypothesis pertains to amyloidal cascade neurodegeneration, whereas the second pertains to the dysfunction of the cholinergic system: tau aggregation, metal-mediated toxicity, and inflammation.

According to the amyloidal cascade neurodegeneration hypothesis, AD begins with the proteolytic cleavage of the amyloid precursor protein (APP) and results in the production, aggregation, and deposition of β-amyloid (Aβ) and amyloid plaques ().^{Citation56,Citation57} The deposition of Aβ is increased in patients with AD when there are mutations in APP and presenilin (PS).^{Citation56,Citation58} An increase in metal-mediated neurotoxicity is also associated with the deposition of Aβ.^Citation59 When the concentration of Aβ is high, insoluble amyloid fibers are formed in the brain. These fibers may be complexed with zinc and copper, thereby aggravating the neuronal toxicity.^Citation60 Copper has shown the ability to increase Aβ aggregation, and an in vitro study showed that the Aβ–copper complexation resulted in the formation of neurotoxic hydrogen peroxide.^Citation61 Furthermore, metals such as copper, iron, and zinc have been found in the amyloid deposits in the brains of AD patients.^Citation62 The use of metal chelators in the postmortem tissues of AD patients could dissolve these amyloid plaques.^Citation63 An in vivo study with an animal model of AD also showed that chelating agents could solubilize amyloid plaques.^Citation64

Figure 1 Formation of amyloid plaques (A) and neurofibrillary tangles (B) in the neurons in Alzheimer’s disease.

Abbreviations: Aβ, β-amyloid; APP, amyloid precursor protein.

According to the cholinergic hypothesis, the dysfunction of the cholinergic system is sufficient to produce a memory deficit in animal models that is similar to AD.^Citation65 Rossor et al and Henke and Lang reported that the brains of patients with AD showed the degeneration of cholinergic neurons and a reduction in cholinergic markers, whereas the activities of choline acetyltransferase (ChAT) and AChE were reduced in the cerebral cortexes of patients with AD.^{Citation66,Citation67} A study reported by Soininen et al showed that AD patients carrying the apolipoprotein E (APOE) ε4 allele have a more severe cholinergic deficit than the AD patients without the APOE ε4 allele.^Citation68

Phospholipase A2 (PA2) is the enzyme responsible for the synthesis of chemical mediators of inflammation and is also responsible for the conversion of phosphatidylcholine to choline.^{Citation69,Citation70} However, PA2 has been reported to decrease in the frontal and parietal cortexes of AD patients,^Citation71 resulting in decreased levels of choline. Because choline is converted to acetylcholine by ChAT and AChE, its deficit contributes to cholinergic deficiency and AD progression.^Citation70

The main function of tau protein is to promote the association of tubulin monomers in order to form microtubules, which modulate the functional and structural organization of neurons.^Citation72 In AD, tau protein is abnormally phosphorylated and thus the microtubules disaggregate, accumulating in the cell body and forming intracellular filaments that lead to the disorganization of the neuron cytoskeleton.^{Citation73,Citation74} This results in the blocking of the intracellular trafficking of neurotrophic proteins and other functional proteins, resulting in the loss or decline in dendritic or axonal transport in neurons ().

In AD, the reactive astrocytes are increased,^{Citation75,Citation76} and there is a high expression of PA2. Astrocytes are able to release proinflammatory molecules, such as interleukins (ILs), prostaglandins, leukotrienes, thromboxanes, coagulation factors, complement factors, and proteases.^Citation77^–^Citation80 The activated microglia cells have also been shown to be abundant in the brains of patients with AD.^{Citation76,Citation79} These cells produce a variety of neurotoxic compounds, including superoxide radicals, glutamate, and nitric oxide.^Citation81 The exposure of microglia cells to Aβ results in the release of proinflammatory factors, including interleukin-1 (IL-1), interleukin-6 (IL-6), interleukin-8 (IL-8), and tumor necrosis factor-α (TNF-α).^Citation82

A number of complex mechanisms are involved in the genesis and progression of AD. Recent advances in the understanding of the molecular control of these various pathways will allow for a more accurate diagnosis and assessment of AD prognosis and may lead to more novel approaches to finding new molecular targets for AD treatment and prevention.

Diagnosis and treatment of AD

AD is a clinical diagnosis;^Citation83^–^Citation86 however, the differential diagnosis of AD is based on the diagnosis of depression, which occurs in approximately 30%–50% of patients with AD. Depression in patients committed with AD are more often features motivational disturbances, such as fatigue, psychomotor slowing, and apathy, whereas depression in geriatric patients without cognitive impairment tends to feature mood symptoms, such as depressed mood, anxiety, suicidality, and disturbances in sleep and appetite.^Citation87 Commonly used instruments for assessing depression were designed for use in other patient populations and may be less reliable in patients with AD.^Citation87 Olin et al have proposed the inclusion and exclusion of provisional affective and behavioral diagnostic criteria in identifying AD in patients with depression.^Citation88

Ancillary imaging studies, such as computed tomography (CT) or magnetic resonance imaging (MRI) and, in selected cases, single-photon emission CT (SPECT) or positron emission tomography (PET), can also be used in the diagnosis of AD.^Citation89 Brain MRI or CT scanning has indicated the use of structural neuroimaging to detect lesions that may result in cognitive impairment. In patients with AD, brain MRIs or CT scans can show diffuse cortical and cerebral atrophy, but these findings are not diagnostic of AD.^Citation89

Images obtained from CT scans can show the changes in the rate of atrophy progression,^Citation90 longitudinal changes in brain size,^Citation91 and enlargement of the third and lateral ventricles.^Citation92 This approach can be useful in diagnosing AD. MRI measurements of the cerebral structures (hippocampus, amygdala, lateral ventricles, third ventricle, and basal forebrain) yield a prediction rate of 77% for the conversion of questionable AD to AD.^{Citation93,Citation94} PET scanning is helpful for understanding the pathogenesis of AD, making the correct diagnosis, and monitoring the AD progression and response to drug treatment.^Citation95 PET scanning involves the introduction of a radioactive tracer into the human body, usually via intravenous injection. PET measures glucose-dependent physiological processes in brain by using 2-[¹⁸F]fluoro-2-deoxy-D-glucose (FDG).^{Citation96,Citation97} Patients with AD have a temporoparietal glucose hypometabolism, which correlates with the severity of dementia and can be evaluated using FDG PET.^{Citation96,Citation98,Citation99} In 2012, florbetapir F18 was approved by the US Food and Drug Administration (FDA) as a diagnostic imaging agent. It is indicated for PET brain imaging of Aβ neuritic plaques in adults under evaluation for AD or other conditions related to cognitive decline.^Citation100^–^Citation103 In 2013, the FDA approved flutemetamol F18. Like florbetapir F18, this drug attaches to Aβ in the brain and produces a PET image that can be used to assess the presence of Aβ, as evidenced in a clinical Phase II trial.^Citation104

Laboratory tests can be used to exclude other possible causes for dementia^Citation89 such as cerebrovascular disease, cobalamin deficiency, syphilis, or thyroid disease.^Citation105^–^Citation107 Cerebrospinal fluid (CSF) analysis can be useful in identifying dementia caused by other factors, including infections in the central nervous system (CNS) such as neurosyphilis, neuroborreliosis, and cryptococcosis.^Citation108 The CSF levels of tau and phosphorylated tau are often elevated in AD, whereas amyloid levels are usually low. The reason for this is not known, but perhaps amyloid levels are low because the amyloid is deposited in the brain rather than the CSF.^Citation86 Other diagnosis tools include genotyping mutations in the genes for APOE, APP, and PS. A recent study has reported that plasma levels of APOE ε4 are associated with the risk of dementia independent of the APOE genotype.^Citation109 These genotype tests provide assessments to patients with AD and provide the key elements used in genetic counseling for the disease.^Citation110

The use of nanotechnology as a diagnostic tool depends on the detection of amyloid peptides (Aβ), which are used as targets in the development of biological markers for the diagnosis of AD.

Polymeric nanoparticles (NPs) have been prepared and encapsulated with radio-labeled ¹²⁵I-clioquinol (5-chloro-7-iodo-8-hydroxyquinoline [CQ]), a drug with amyloid affinity, to improve its transport to the brain and amyloid plaque retention of ¹²⁵I-CQ. Radio-iodinated CQ NPs have been demonstrated to be promising delivery vehicles for in vivo SPECT or for use as a PET amyloid imaging agent.^Citation111

The use of thioflavin-T entrapped in polymeric NPs has been described for use as a probe to detect Aβ in senile plaques.^Citation112 The photoconversion of fluorescent thioflavin-T as a model drug was achieved in tissues fixed 3 days after injection, and thioflavin-T delivered from nanospheres was predominantly found in neurons and microglia. These data suggest that drugs delivered by NPs might target Aβ in the brain.^Citation112

The current pharmacological approach to AD treatment is based on vascular prevention and symptomatic therapy with cholinesterase inhibitors and N-methyl-D-aspartate (NMDA) antagonists.^Citation113 Cholinesterase inhibitors are included in drugs such as donepezil, rivastigmine, galantamine,^Citation113 and tacrine.^Citation114 These drugs act by inhibiting the action of AChE and optimizing the levels of acetylcholine available for postsynaptic stimulation.^Citation115

Memantine is an NMDA antagonist that acts as a noncompetitive glutamate receptor antagonist.^{Citation116,Citation117} Glutamate-related excitotoxicity resulting from an excessive activation of neuronal amino acid receptors^Citation118 is involved in the pathophysiology of AD.^Citation119 Memantine acts on the glutamatergic system by blocking NMDA receptors and this blocking effects on glutamate activity reduction on brain cells and blocking the activity of the neurotransmitter.^{Citation120,Citation121} At normal levels, glutamate is conducive to memory and learning, but if levels are too high, glutamate appears to overstimulate nerve cells, killing them through excitotoxicity.^Citation122 The interaction of memantine with NMDA receptors plays a major role in the symptomatic improvement that the drug produces in AD. Moreover, there is no evidence as yet that the ability of memantine to protect against NMDA receptor-mediated excitotoxicity has a disease-modifying effect in AD, although this has been suggested in animal models.^Citation123

Winslow et al have reported conflicting evidence about the benefits of selegiline, testosterone, and ginkgo (Ginkgo biloba) for the treatment of AD, and no evidence supports the beneficial effects of vitamin E, estrogen, or nonsteroidal anti-inflammatory drug therapies.^Citation114 Nevertheless, the inflammatory pathways in AD^{Citation124,Citation125} and treatment with anti-inflammatory molecules has the potential to delay, prevent, or treat AD.^{Citation125,Citation126}

Nanotechnology-based drug delivery systems

Treatment options are limited mainly due to the inability of drugs to cross the blood–brain barrier (BBB)^Citation127^–^Citation129 or their poor solubilities by oral route.^{Citation130,Citation131} Many strategies have been developed to overcome the BBB, such as drug delivery systems, liposomes, polymeric and solid lipid NPs (SLNs), solid lipid carriers, liquid crystals (LCs), microemulsions (MEs), and hydrogels.^Citation127^–^{Citation129,Citation132}^–^Citation134 The physicochemical characteristics of drugs, such as its hydrophilicity or lipophilicity, ionization, high molecular weight, poor bioavailability, extensive metabolization, and adverse effects, can result in its failure as a pharmacotherapeutic.^{Citation127,Citation135} These limitations can be overcome by the use of intranasal administration, which offers an alternative, noninvasive means of drug delivery to the brain because drugs delivered this way can bypass the BBB and directly transport drugs to the CNS.^{Citation136,Citation137}

Polymeric NPs

NPs are defined as particulate dispersions or solid particles with sizes ranging from 1 to 1,000 nm.^Citation138 The structural organization of a nanosystem is based on its composition: the presence of compartments within nanocapsules^Citation139 leads to oily or aqueous cores surrounded by thin polymer membranes,^Citation140 whereas nanospheres provide a matrix-based organization of the polymeric chains ().^Citation139

Figure 2 Schematic differences between nanocapsule, nanostructured lipid carrier, polymeric nanoparticle, and solid lipid nanoparticle drug delivery systems.

NPs have been prepared using several methods, including polymer polymerization,^{Citation141,Citation142} ionic gelation or coacervation,^{Citation143,Citation144} emulsion solvent evaporation,^Citation145^–^Citation148 spontaneous emulsification or solvent diffusion,^{Citation149,Citation150} nanoprecipitation,^{Citation151,Citation152} spray drying,^{Citation29,Citation153} supercritical fluid technology,^Citation154 and particle replication in non-wetting templates (PRINT).^Citation155^–^Citation157

Drug delivery across the BBB to the brain may provide a significant advantage over currently used strategies without damaging the BBB.^{Citation158,Citation159} The transport mechanism of NPs across the BBB can be explained by the increased retention of the NPs in the brain blood capillaries in combination with the adsorption of the NPs to the capillary walls. These events lead to a higher concentration gradient, which increases the transport across the endothelial cell layer and thus enhances the delivery to the brain.^Citation160 Transport can also be facilitated through the inhibition of the efflux system^Citation160 by using polysorbate 80 as the coating agent.^{Citation161,Citation162} NPs may induce local toxic effects on the brain vasculature, leading to a limited permeabilization of the brain endothelial cells.^Citation160 The use of a surfactant to solubilize the lipids of the endothelial cell membrane can enhance drug permeability across the BBB. The NPs could permeate the BBB through the tight junctions, which are open between the endothelial cells of the brain blood vessels.^{Citation158,Citation160,Citation163} Endocytosis by the endothelial cells followed by the release of the drugs within these cells facilitates delivery to the brain.^{Citation164,Citation165} Transcytosis can also facilitate transport through the endothelial cell layer.^Citation166^–^Citation168 Finally, a combination of the effects described above can be used ().^{Citation158,Citation160,Citation163} NPs can also be administered nasally to promote absorption^Citation169 and delivery to the brain.^{Citation160,Citation170,Citation171} Other technological strategies include coating NPs with polyethylene glycol (PEG),^Citation172 polymers, or antibodies to improve nasal absorption.^Citation173 Surface modification of the NPs with mucoadhesive polymers can increase the retention time of NPs delivered via the nasal route.^Citation174

Figure 3 Schematic representation of types of liposomes and enlarged view of the layers of phospholipids.

Abbreviations: GUV, giant unilamellar vesicle; LUV, large unilamellar vesicle; MLV, multilamellar vesicle; SUV, small unilamellar vesicle.

Wilson et al^Citation21 developed polysorbate 80-coated poly(n-butyl cyanoacrylate) NPs loaded with tacrine, which were prepared by emulsion polymerization. The concentrations of tacrine in the lungs and kidneys were not significant when compared to both groups. The authors suggested a mechanism for delivery of the coated polysorbate 80 NPs to the brain via the interaction between the polysorbate 80 coating and the endothelial cells of the brain microvessels.^Citation21 In another study, Wilson et al^Citation22 developed poly(n-butyl cyanoacrylate) NPs coated with polysorbate 80 for the targeted delivery of rivastigmine to the brain in order to treat AD. Animal studies were performed by injecting the NPs into mice. The concentration of tacrine in the brain was approximately 170 ng/mL when the coated NPs were used, and this result was significant (P<0.001) relative to the use of uncoated NPs or the free drug. The authors suggest that the mechanism for delivering the coated polysorbate 80 NPs to the brain is the interaction between the polysorbate 80 coating and the endothelial cells of the brain microvessels.^Citation22 This specific role of the polysorbate 80 coating in targeting NPs to the brain was proposed and studied by Sun et al.^Citation175

Zhang et al^Citation23 developed a dual-functional NP drug delivery system based on a PEGylated poly(lactic acid) polymer containing two targeting peptides, TGN and QSH, conjugated to the surfaces of the NPs. TGN specifically targets ligands at the BBB, while QSH has good affinity for Aβ_1–42, which is the main component of amyloid plaques. In this study, the optimal maleimide/peptide molar ratio was 3 for both TGN and QSH on the surface of the NPs. These NPs were delivered to amyloid plaques with enhanced and precisely targeted delivery in the brains of AD model mice.^Citation23

The use of intranasal NPs to deliver basic fibroblast growth factor (bFGF) to the brain for the treatment of AD was also studied by Zhang et al.^Citation24 In this study, bFGF was entrapped in NPs conjugated with PEG and polylactide-polyglycolide (PLGA) and Solanum tuberosum lectin (STL), which selectively binds to N-acetylglucosamine on the nasal epithelial membrane to facilitate brain delivery. The NPs were prepared using the emulsion solvent evaporation method. The intranasal administration of the STL-modified NPs (STL-bFGF-NPs) resulted in a 1.7–5.17-fold greater distribution of the formulation in the brain than the intravenous administration of the NPs. The distribution of the formulation using intranasally administered STL-bFGF-NPs was also 0.61–2.21-fold greater than an intranasally administered drug solution and 0.19–1.07-fold greater than intranasally administered unmodified NPs. The activity of ChAT in mice showed a significant increase (P<0.05) in the group treated with NPs via the intranasal route compared to the AD control group. These findings indicated that ChAT activity in the hippocampus of AD rats treated with bFGF-loaded STL-conjugated NPs was higher than in the rats treated with unconjugated NPs. The STL-conjugated NPs could effectively facilitate the direct transport of bFGF into the rat brain with reduced peripheral adverse effects following intranasal administration.^Citation24 Based on these requirements, PEG–PLGA copolymer NPs that feature a PEG-rich surface around the PLGA core are ideal for intranasal administration because the PEG-rich surface has been demonstrated to prevent the NP aggregation typically observed when the uncoated PLGA NPs come into contact with the nasal mucosa.^Citation176

Poly[(hexadecyl cyanoacrylate)-co-methoxypoly (ethylene glycol) cyanoacrylate] NPs were formulated by Brambilla et al.^{Citation25,Citation26} The authors investigated the effects of these NPs in slowing down or disrupting the aggregation process in vitro through kinetic studies performed with the Aβ_1–42 peptide or corresponding oligomers by capillary electrophoresis. The capillary electrophoresis experiments showed that these NPs could link the Aβ_1–42 peptide both under its monomeric and soluble oligomeric forms. These NPs were also shown to influence Aβ_1–42 peptide aggregation, which was confirmed by thioflavin-T assays.

Joshi et al^Citation27 used a modified nanoprecipitation method and an emulsion polymerization method to prepare rivastigmine-loaded PLGA and PBCA NPs, respectively. The administration of rivastigmine formulations in saline-treated animals did not result in any noticeable improvement in learning and memory capacities, whereas the administration of different rivastigmine-loaded NPs in scopolamine-treated mice antagonized the scopolamine-induced amnesia, as evidenced by a significant decrease (P<0.05) in escape latency.

Fazil et al^Citation28 prepared chitosan NPs using an ionic gelation method to enhance the bioavailability and uptake of rivastigmine to the brain via intranasal delivery. Using confocal laser scanning fluorescence microscopy, their findings showed that the concentration of rivastigmine in the brain following intranasal administration was found to be significantly higher at all times compared to the administration of a rivastigmine solution via the intravenous or intranasal route.^Citation28

Amorim et al used the spray-drying technique to develop idebenone-loaded chitosan and N-carboxymethylchitosan NPs.^Citation29 Although the authors did not study the use of these NPs in the treatment of AD, the beneficial effects of idebenone for the treatment of AD^{Citation177,Citation178} and its role as an antioxidant in AD progression^{Citation55,Citation58,Citation179}^–^Citation181 have been well documented in clinical trials. The incorporation of idebenone in chitosan or N-carboxymethylchitosan NPs was shown to preserve the antioxidant efficiency, especially at higher polymer-to-drug ratios. The NPs showed a tenfold increase in drug stability compared to the free drug. These results showed a severe reactivity of free idebenone that was similar to the positive control, indicating a significant potential for corrosion or irritation. On the other hand, the incorporation of idebenone in polymeric NPs showed a decrease in drug reactivity.^Citation29 Because chitosan and N-carboxymethylchitosan exhibit mucoadhesive properties,^Citation182^–^Citation187 these results revealed that NPs are potential carriers for the nasal delivery of hydrophobic and irritating drugs such as idebenone due to the high first-pass metabolism of idebenone^Citation188 after oral administration.

Solid lipid carriers

SLNs are typically spherical, with average diameters between 10 and 1,000 nm when dispersed in water. SLNs possess a solid lipid core matrix that can solubilize lipophilic molecules.^Citation189 The lipid core, typically consisting of triglycerides (eg, tristearin), diglycerides (eg, glyceryl behenate), monoglycerides (eg, glycerol monostearate), fatty acids (eg, stearic acid), steroids (eg, cholesterol), or waxes (eg, cetyl palmitate),^Citation190 is stabilized by surfactants, though the combination of emulsifiers might be more efficient at preventing particle agglomeration.^Citation190 Though SLNs are formed by a matrix lipid, a new generation of NPs can be produced using a blend of solid lipids with a liquid lipid, termed nanostructured lipid carriers (NLCs),^{Citation189,Citation191} in order to minimize the drug expulsion associated to SLNs ().

SLNs or NLCs are prepared from lipids, an emulsifier, and water or solvent by using different methods such as high pressure homogenization,^{Citation192,Citation193} an ultrasonication/high-shear technique,^Citation194^–^Citation198 the solvent evaporation method,^{Citation199,Citation200} the solvent emulsification-diffusion method,^Citation201^–^Citation204 the supercritical fluid method,^{Citation205,Citation206} the ME-based method,^Citation207^–^Citation209 the spray-drying method,^Citation210^–^Citation212 the double emulsion method,^Citation213 or the precipitation technique.^Citation214

The BBB can be overcome through the use of SLNs or nanocarriers lipids for the delivery of drugs to the brain, as these formulations can penetrate the BBB^Citation194 or be used intranasally to bypass the BBB. The use of cationic lipids can be a strategy to improve mucoadhesion in the nasal cavity by promoting electrostatic interactions with mucus^Citation215 in addition to mediating the adsorptive-mediated transcytosis cationic NPs across the BBB.^Citation216 Coating NPs with surfactants can be an alternative strategy for delivery across the BBB. The transport of surfactant-coated NPs across the BBB may occur through endocytosis mediated by the endothelial cells of the brain capillaries.^Citation217^–^Citation219

Piperine SLNs with a polysorbate 80 coating were prepared by the emulsification-solvent diffusion technique.^Citation30 These NPs were experimentally assessed in ibotenic acid-induced AD in mice. The results showed an increase in AChE activity and improvement in cognition, which were superior to the result shown for donepezil. Histopathology studies also revealed a reduction in plaques and tangles.^Citation30

Sood et al^Citation31 developed curcumin/donepezil-loaded NCLs for delivery to the brain via the intranasal route. The results demonstrated a higher concentration of drugs in the brain via intranasal delivery compared to intravenous administration. A mouse model showed improved memory and learning compared to the group treated with the free drug. Nevertheless, the levels of acetylcholine were improved and oxidation damage was reduced in the groups treated with NLCs.^Citation31

Zhuang et al^Citation32 formulated vinpocetine-loaded NCLs using a high-pressure homogenization method for improved oral bioavailability. Pharmacokinetic studies showed a twofold increase, threefold increase, and 0.35-fold decrease in the maximum concentration, maximum time, and elimination constant in plasma, respectively, relative to a suspension of vinpocetine. The authors concluded that the NCLs showed a relative drug bioavailability of 322% in rats after oral administration compared with the administration of free drug in suspension, further demonstrating that these NCLs can be used to load drugs with poor water solubility. AD-based clinical trial has shown that vinpocetine is a drug with potential use in the treatment of cognitive impairment and memory.^Citation220 However, a 2003 Cochrane Review determined that the results were inconclusive.^Citation221

NCLs with oil-based cores loaded with resveratrol were developed by Frozza et al in order to improve cerebral bioavailability.^Citation33 The results showed 2.5-fold, 6.6-fold, and 3.4-fold greater drug concentrations in the brain, liver, and kidneys, respectively, of mice treated with the NCLs relative to those treated with free resveratrol.^Citation33 Additional important data showed that mice treated with an intrac-erebral infusion of Aβ_1–42 had memory deficits that were reduced only by the treatment with drug-loaded NCLs with oil-based cores.^Citation33 Recently, a study using resveratrol confirmed the accumulation of this drug in vivo and the neuroprotective action of a kinase against Aβ plaques.^Citation222 This study demonstrates the emerging therapeutic potential of resveratrol in AD.

Bondi et al^Citation223 developed ferulic acid-loaded SLNs using the ME technique as a potential treatment for AD. In this study, unloaded SLNs showed no cytotoxicity against human neuroblastoma, but they showed the ability to penetrate into these cells. Cells treated with ferulic acid-loaded SLNs showed a greater reduction in the production of radical oxygen species than cells treated with the free drug.^Citation223 These findings demonstrate that drug-loaded SLNs possess a higher protective activity than the free drug against oxidative stress induced in neurons, suggesting that these SLNs are potentially excellent carriers for transporting cholinergic agent drugs into the cells.

Patel et al proposed a study to comparatively evaluate the in vitro and in vivo behaviors of huperzine A-loaded lipid-based nanocarriers.^Citation35 Huperzine A is a well-tolerated drug that has been shown in a clinical study to effectively reverse or attenuate cognitive deficits.^Citation224 Huperzine A was loaded on SLNs and NLCs, which were prepared using the ME technique before the nanocarriers were dispersed on a gel. Ex vivo permeation studies were carried out, and the results showed that NLCs had increased permeability through the abdominal rat skin relative to SLNs. A primary irritation test in rabbit model indicated the safety of applying the drug-loaded nanocarrier-based gel to skin. The in vivo efficacies of the nanocarrier-based formulations were also tested in a scopolamine-induced amnesia model. A significant improvement in cognitive function was observed in mice treated with the nanocarrier-based formulations compared with the control group. A decrease in cognitive function was observed upon oral delivery of a drug suspension compared with the transdermally administered nanocarrier. These findings showed a reduced transfer latency over the period of 3 days, which indicated the sustained and controlled release of the drug from the developed nanocarriers when administered via the transdermal route.^Citation223

Studies have demonstrated that curcumin decreases the in vitro and in vivo Aβ formation from APP and also inhibits the aggregation of Aβ into pleated sheets.^Citation225^–^Citation228 Curcumin has been incorporated into SLNs and NCLs for other therapeutic purposes.^Citation229^–^Citation234 Kakkar et al evaluated curcumin-loaded SLNs for brain delivery in rats via the oral route.^Citation36 The results showed that drug-loaded SLNs increased the activity of AChE compared to the free drug, and the concentration of curcumin was increased by twofold in the brain compared to the free drug when both treatments were orally administered. Although a cerebral ischemic reperfusion injury animal model was used in the study, these SLNs can be used for drug release in the brain for the treatment of AD.^Citation36 SLNs and NCLs that are chosen as drug carriers and administered in vivo can be transported to the CNS^{Citation34,Citation165,Citation194,Citation235}^–^Citation238 and may be useful in the treatment of AD.

Liposomes

Liposomes are vesicles consisting of one or more phospholipid bilayers concentrically oriented around an aqueous compartment^Citation239 that serve as carriers of lipophilic or hydrophilic drugs.^{Citation240,Citation241} Various processes can be used to prepare liposomes, such as hydration of a thin lipid film^Citation242^–^Citation244 followed by agitation,^Citation245^–^Citation248 sonication,^Citation249^–^Citation254 extrusion,^{Citation251,Citation255}^–^Citation258 high-pressure homogenization,^Citation259^–^Citation262 or reverse-phase evaporation.^Citation263^–^Citation266

Liposomes may contain a single lipid bilayer or multiple bilayers around the inner aqueous compartment and are therefore classified as unilamellar and multilamellar, respectively.^Citation267 Liposomes are classified by their lamellar size as small unilamellar vesicles with diameters of 20–100 nm, large unilamellar vesicles with diameters exceeding 100 nm, giant unilamellar vesicles with diameters up to 1 µm, oligolamellar vesicles with diameters of 0.1–1 µm, and multilamellar vesicles with diameters up to 500 nm ().^Citation268

Figure 4 Main pathways for nanosystems to cross the blood–brain barrier to target to brain.

Abbreviations: CNS, central nervous system; NCLs, nanostructured lipid carriers; NPs, nanoparticles.

In the literature, liposomes are classified as niosomes, transfersomes, ethosomes, and phytosomes. Niosomes are formed by self-assembly of nonionic surfactants in an aqueous dispersion and they are flexible and more stable than liposomes, which reduces the flux of drugs in comparison to conventional liposomes.^Citation269 Transfersomes are deformable vesicles composed of phospholipids^Citation270 that are usually administered via the transdermal route.^Citation271 Ethosomes are either conventional liposomes or are transfersomes containing up to 10% ethanol, which can promote the solubilization of hydrophilic drugs.^Citation272 Phytosomes are produced by binding individual components of herbal extracts to phosphatidylcholine.^Citation273

Yang et al formulated rivastigmine liposomes and cell-penetrating peptide (CPP)-modified liposomes to improve the distribution of rivastigmine in the brain, enhance the pharmacodynamics via intranasal administration, and minimize side effects.^Citation37 The results showed that the concentrations of rivastigmine across the BBB were significantly different after 8 hours, reaching higher concentration values when CPP liposomes and liposomes were used compared to the free drug. The biodistribution of rivastigmine in the cerebellum was not found when free drug was administered intranasally or intravenously. The average rivastigmine concentration in CNS cerebral tissues was higher following intranasal administration of modified liposomes compared with liposomes, and the average rivastigmine concentration was significantly higher for the modified liposomes in the hippocampus, cortex, and olfactory region at 15 minutes to 60 minutes. The authors suggest that rivastigmine-loaded liposomes, especially-modified liposomes, improve the brain delivery and enhance pharmacodynamics with respect to BBB penetration and the nasal olfactory pathway into the brain after intranasal administration.^Citation37

In a study designed by Kumaraswamy et al, liposomes were obtained using the thin-film hydration technique.^Citation39 Thermal studies showed that the beta-sheet blocker was located in the hydrophobic core, where it acted to lower the surface tension. This property made these liposomes a suitable therapeutic agent for the prevention of amyloid aggregation by binding with Aβ in the brain.^Citation39

Many techniques are used to target liposomes across the BBB. These strategic techniques include the conjugation of drugs and monoclonal antibodies against endogenous receptors in the BBB^{Citation173,Citation274,Citation275} or liposomes or other nanodevices coated with polysorbate 80, cationic macromolecules, peptides, or antibodies against BBB receptors or Aβ peptides^{Citation173,Citation276}^–^Citation279 to cross the BBB and to be targeted to the brain.

Liposomes functionalized with an anti-transferrin receptor antibody can cross the BBB. The functionalization of liposomes gave higher values of uptake and permeability across the barrier model in comparison to non-decorated liposomes.^Citation280 Liposomes were functionalized with a modified cell-penetrating TAT peptide, which increased the permeability of curcumin-loaded liposomes across a BBB model.^Citation40

Mono- and dual-decorated liposomes were prepared by immobilization of anti-transferrin monoclonal antibody (MAb) against transferrin receptor in BBB and a peptide analog of apolipoprotein (PAA) to target low-density lipoprotein receptor in BBB. The major results showed liposome uptake and transport across the human microvascular endothelial cells (hCMEC/D3) used as a model barrier was significantly affected by decoration with PAA or MAb, and that the double immobilization with ligands in the liposomes exerted an additive effect in the BBB targeting. The mechanism of targeting was confirmed to be vesicle transcytosis. In vivo study was carried out in mice, and the results showed that MAb and dual ligands (MAb and PAA) increased brain targeting compared to nontargeted liposomes. The authors appointed a contradiction between in vitro and in vivo results. PAA was found to target BBB and increase the in vitro targeting potential of MAb-decorated liposomes, but not in vivo, because in vitro studies were carried out in the presence of serum proteins in the middle of cell culture, revealing their important role in targeted-nanoformulation performance.^Citation41

Another published study explored the use of MAb in liposomes loaded with curcumin analog. This study compared the ability of both curcumin analog- and curcumin-loaded liposomes and showed a high affinity for senile plaques on postmortem brain tissue of AD patients. The ability of both liposomes to delay Aβ_1–42 peptide aggregation was confirmed. However, the decoration of the curcumin-derivative liposomes with the MAb improved significantly the intake by the BBB cellular model. These results prove the potential of such multifunctional liposomes for application in AD treatment and diagnosis.^Citation42

Curcumin-conjugated liposomes were developed and the results showed significant amounts of labeled Aβ deposits in postmortem brain tissue of AD patients. In vivo injection in the hippocampus and in the neocortex of mice showed that curcumin-conjugated nanoliposomes were able to specifically stain the Aβ deposits.^Citation43 Thus, these liposome formulations can be applied in diagnosis and targeted drug delivery in AD.

Curcumin derivative maintaining the planarity was developed to obtain conjugated liposomes. Surface plasmon resonance experiments indicated that the liposomes exposing the curcumin derivative had extremely high affinity for Aβ1–42 fibrils, likely because of the occurrence of multivalent interactions, whereas those exposing non-planar curcumin did not bind to Aβ_1–42.^Citation44

Ligand-functionalized nanoliposomes for targeted delivery of galantamine have also been designed. The major result revealed by confocal microscopy was that the ligand-functionalized nanoliposomes facilitated galantamine uptake into PC12 neuronal cells.^Citation45 Nevertheless, in vivo uptake studies should be should be performed as well as testing in animal models of AD to demonstrate the effectiveness of the nanosystem.

Liposomes were prepared by the lipid hydration method to sustain the effect of rivastigmine in the brain. Rivastigmine-loaded liposomes and rivastigmine solution were administered via the subcutaneous route in an aluminum chloride-induced Alzheimer’s model. Both formulations improved the deterioration of spatial memory induced by aluminum chloride, with liposomes having a superior effect. Though the rivastigmine solution significantly attenuated AChE activity, rivastigmine-loaded liposomes succeeded in normalizing AChE.^Citation38

The delivery of liposomes to the brain can be attained via the intranasal route to overcome the BBB,^{Citation169,Citation281,Citation282} and liposomes can cross the BBB by transport lipid-mediated free diffusion or lipid-mediated endocytosis.^Citation283 Rivastigmine-loaded liposomes were prepared using the lipid hydration method for delivery into the brain via the intranasal route. Intranasally delivered liposomes were compared to the orally delivered free drug group. The results showed that maximum concentration was tenfold higher in plasma and the half-time was significantly different for the intranasally delivered liposome group compared to the intranasally delivered free drug group or the orally delivered free drug group.^Citation46 Rivastigmine-loaded liposomes were administered orally and intraperitoneally in an AD animal model, and the results showed the highest AChE inhibition with the use of rivastigmine–sodium taurocholate liposomes.^Citation47

The transport of rivastigmine-containing liposomes across Caco-2 cells has also been studied. The highest cumulative amount of rivastigmine to pass through the Caco-2 cell cultures was found for the rivastigmine–sodium taurocholate solution compared to the rivastigmine–sodium taurocholate liposome. Rivastigmine liposomes and molecular solutions were also administered to animals and the AChE activity calculated using blood and brain tissue samples, and the highest value of AChE inhibition was observed for the rivastigmine and sodium taurocholate liposomes.^Citation48

Folic acid niosomes were prepared using different non-ionic surfactants and cholesterol via the lipid hydration technique, and ex vivo perfusion studies were performed using a rat model. The drug was found to be absorbed through the nasal cavity at the end of 6 hours.^Citation49 Folic acid has been associated with an improvement in the response of cholinesterase inhibitors in people with AD.^Citation284

Freeze-dried niosomes loaded with G. biloba extract were developed with improved oral bioavailability. The in vivo distribution of GbE niosomes in the rat showed that the flavonoid glycoside biomarker content in the brain was significantly higher for the niosome group than for the G. biloba extract tablet group.^Citation51 Change in pharmacokinetic behavior, in vivo distribution, and higher accumulation in the brain with the use of the plant drug extract or AChE inhibitor drugs indicate the pharmacotherapeutic uses of niosomes in diseases affecting the brain. Phytosomes containing G. biloba were administered to rats via the oral route. Compared to a sodium nitrite treatment, these phytosomes were able to increase the activities of antioxidant enzymes in all the brain regions.^Citation50 However, many of the early trials used unsatisfactory methods, were small, and publication bias cannot be excluded. The evidence that G. biloba has predictable and clinically significant benefit for people with dementia or cognitive impairment is inconsistent and unreliable.^Citation285

Surfactant-based systems

Surfactant-based drug delivery systems are different drug delivery systems in which surfactant molecules are self-aggregated, usually in the presence of water, to form structures with variable parameters depending on the concentration of the surfactant, the presence of salts, or the temperature. These aggregates become more organized even when oils or other components such as other surfactants are added to the surfactant–water system.^Citation286 Thus, MEs, nanoemulsions (NEs), and lyotropic LC mesophases with different geometries can be generated.^{Citation286,Citation287}

MEs are usually thermodynamically stable isotropic liquids formed by mixing oil, water, and surfactants together. NEs, by contrast, are conventional emulsions that contain very small particles. The droplet sizes of MEs are between 10 and 140 nm,^Citation288 which results in optically transparent and thermodynamically stable systems.^{Citation289,Citation290} NEs are up to 140 nm in diameter and are not transparent and less thermodynamically stable than MEs ().^Citation290 The two systems are very different because NEs are formed by mechanical shearing and ME phases are formed by self-assembly.^Citation291

Figure 5 Photograph of microemulsion and nanoemulsion.

Note: Enlarged areas show schematics of the size of droplets formed.

Other parameters can distinguish MEs from NEs: MEs are more stable in long-term storage than NEs; MEs can be agitated, cooled, or heated and then returned to their original conditions, whereas NEs cannot return to their original conditions; MEs have a homogeneous droplet size while NEs have a range of heterogeneously sized droplets; and MEs may or may not contain spherical droplets due to the lower interfacial tension while NEs consist of spherical droplets due to the large Laplace pressure acting upon them.^Citation290

MEs are formed from spontaneous mixtures of oils, water, and surfactants,^{Citation292,Citation293} though it is often necessary to apply stirring or heating^{Citation292,Citation294} to facilitate the formation of MEs due to kinetic energy barriers that must be overcome or mass transport limitations that inhibit their spontaneous formation.^Citation290 NEs are formed using the input of some external energy provided by high-pressure homogenizers,^Citation295^–^Citation297 microfluidizers,^Citation298 and sonication methods^Citation299 to convert the mixture into a colloidal dispersion or phase inversion. Spontaneous emulsification methods^Citation296 can then be used to form NEs.

NEs containing curcumin were developed for intranasal delivery, and the results from behavioral experiments showed improved memory and learning in the group treated with curcumin-loaded NEs compared with the group treated with the pure drug.^Citation300 MEs were developed for transdermal delivery in order to manage AD, and mice given MEs containing huperzine A showed improved cognitive functions compared to mice given the drug in suspension via the oral route.^Citation35 An ME-based patch for the transdermal delivery of huperzine A and ligustrazine phosphate was developed, and the results showed that, unlike the monotherapy, the combined therapy had a synergistic effect against amnesia induced in mice by 9 days after administration.^Citation301

The intranasal administration of β-asarone-loaded MEs resulted in a ratio of AUC_brain/AUC_plasma that was significantly higher compared to intravenous administration.^Citation52 Another study was developed, in which an anticholinesterase alkaloidal extract from Tabernaemontana divaricata was loaded into MEs. The results showed a good stability of the MEs and an AChE activity of more than 80% by 180 days. Moreover, the skin permeation and retention of the formulation increased within 24 hours after transdermal delivery of the extract.^Citation53

Tacrine-loaded MEs showed a rapid absorption and nose-to-brain transmission that was twofold higher than that of an intranasally administered drug solution. A larger amount of tacrine was transported into the brains of scopolamine-induced amnesic mice after the intranasal administration of tacrine-loaded MEs. These mice also showed the fastest recovery of memory loss.^Citation54

LCs consist of matter in a state with properties between those of conventional liquids and those of solid crystals.^Citation302 In other words, LCs have the structural behavior and rigidity of a solid combined with the mobility, disorder, and fluidity of an isotropic liquid.^Citation303 Lyotropic mesophases can be considered to be micelles with ordered molecular arrangements characterized by alternating hydrophobic and hydrophilic regions.^Citation304 By increasing the concentration of surfactants, lamellar, hexagonal, and cubic liquid-crystalline forms can be generated ().^Citation305

Figure 6 Schematic representation of lamellar, hexagonal, and cubic liquid crystal mesophases formed by surfactant molecules’ self-assembly.

The lamellar phase is formed from bilayers separated by layers of surfactants and solvents, which forms a one- or two-dimensional network.^Citation306 In the hexagonal phase, the aggregates are formed by the arrangement of long cylinders that form two- or three-dimensional structures.^Citation307 Lyotropic cubic phases have more complicated structures consisting of a curved, bicontinuous lipid bilayer that extends in three dimensions to generate two interpene trating, but non-contacting, aqueous nanochannels.^{Citation308,Citation309}

Self-assembly systems display phase transformations and notable in situ thickening after administration. These systems are also of interest in relation to drug delivery to the body cavities.^Citation305 The intranasal administration of LCs can be interesting due to the dilution of LCs in nasal fluid, which promotes the phase transition to a hexagonal or cubic LC that can prolong the residence time of the formulation in contact with the mucosa.^Citation310 In the case of LC phases, the mechanism of mucoadhesion most likely involves the rheological properties of the system, which are similar to those of in situ gelling vehicles.^Citation311 Due to their high viscosity, hexagonal and cubic phases have been suggested as mucoadhesives. However, the viscosity of cubic phases can hinder their nasal administration. To circumvent this handling problem, precursor formulations of liquid-crystalline mesophases have been proposed.^Citation312 Numerous studies have shown that MEs and lamellar phase can be used as a precursor of the hexagonal or cubic phases^{Citation310,Citation311,Citation313}^–^Citation317 after the stimuli in situ.

LC systems significantly increased the transdermal delivery of the T. divaricata extract at 24 hours. When loaded into an LC system, an alkaloidal extract from the T. divaricata stem may act as an alternative percutaneous formulation for enhancing the acetylcholine level in patients with AD.^Citation53

The nasal administration of LCs in the treatment and management of AD is a tool that has been unexplored by researchers. LCs have been shown to be an optimal system for intranasal administration; in situ gelation occurs by dilution by nasal fluid and results in increased residence time in the nasal cavity and targeting of drugs to the brain.

Remarks and challenges

Approximately 15 million people worldwide are currently afflicted by AD.^Citation3 This number is expected to increase fourfold by 2050.^Citation3 Nanotechnology offers the potential for designing drug delivery systems with many properties. In the context of treating AD, these types of nanosystems could efficiently carry and deliver drugs and other neuroprotective molecules to the brain.^{Citation4,Citation318,Citation319} The intranasal route plays a role in overcoming the BBB and targeting the drugs directly to the brain.^{Citation282,Citation319}^–^Citation325 However, the oral, dermal, and intra venous routes can be used to administration of nanodevices to target to the brain passing by BBB^{Citation276,Citation326}^–^Citation329 to enhanced bioavailability, pharmacodynamic properties, and decreased adverse effects of these drugs to maximize pharmacotherapy in patients with AD.

Though the registry of patents for nanotechnology-based products is currently increasing,^{Citation323,Citation330,Citation331} clinical trials are needed to evaluate their clinical efficacy and potential toxicological effects to human health.^Citation332 In the near future, neurologists and patients will benefit from suitable nanotechnology-based drug delivery systems that could lead to improved therapeutic outcomes with reduced costs. Although there are no clinical studies on the use of nanotechnology to treat AD, nanotechnology is also predicted to alter health care in neurology, providing novel methods for identifying AD^Citation19 and customizing a patient’s therapeutic profile.

Author contributions

BFS made substantial contributions in conceiving this review, searching the bibliographical data, conducting the analysis, and critically revising it for important intellectual content. MPDG and MC conducted the analysis and revised it critically for important intellectual content. All authors gave final approval of the version to be published.

Acknowledgments

The authors are grateful to the São Paulo Research Foundation (FAPESP) (São Paulo, Brazil, Coordination for the Improvement of Higher Education Personnel (CAPES) (Brasília, Brazil) for research fellowships and Programa de Apoio ao Desenvolvimento Científico (PADC-FCF-UNESP) for financial support.

Disclosure

The authors report no conflicts of interest in this work.

References