Neurotrophic factors (NTFs) regulate the growth, survival, proliferation, migration and differentiation of neurons (71). Therefore, NTFs have been extensively studied in the context of neurodegenerative disorders, including AD (72). In AD, the altered expression and gradual dysregulation of NTFs, such as nerve growth factor (NGF), brain-derived neurotrophic factor (BDNF), glial cell line-derived neurotrophic factor (GDNF) and ciliary neurotrophic factor (CNTF), have been observed in different brain areas (73,74). Numerous experimental studies have indicated the reduction of NTFs in affected brain regions (72,73). These changes in NTFs in AD are critical for neurodegenerative processes. Studies have observed that cognitive decline and the underlying pathologies of AD are associated with neurodegeneration in various regions of the brain, especially cholinergic neurons of the basal forebrain and their projections for the hippocampus and cortex (72,75,76). It has been suggested that the loss of NTFs may be a mechanism involved in the pathogenesis of AD (77). The regulation of NTFs could be a suitable therapeutic target for AD treatment.

As a noninvasive neuromodulatory intervention, TMS or rTMS treatment may potentially regulate the expression of NTFs in the AD brain (Fig. 1), promoting neuronal differentiation and survival (78), and thus, exerting neurorestorative effects. Notably, a number of studies have indicated an increase in endogenous neurotrophic content (BDNF) in the affected brain regions after TMS therapy (2,74). BDNF is a neurotrophin involved in synaptic plasticity changes and improves learning, memory and cognitive functions via the BDNF-tropomyosin receptor kinase B (TrkB) signaling pathway (32,74). Therefore, BDNF serves a critical role in memory formation and synapsis. However, deficits in BDNF signaling are associated with AD (79). Furthermore, the expression levels of BDNF are altered in neurodegenerative disorders, for example the BDNF levels are decreased in AD (80). A study by Choung et al (32) revealed an increase in BDNF expression, as well as neuronal nuclear protein (NeuN) and neuroepithelial stem cell protein (Nestin), after 20 Hz HF-rTMS compared with the non-rTMS group or sham group in the hippocampus and cerebral cortex regions. It was concluded that rTMS exerted neurogenic and neuroprotective effects and promoted neurogenesis (Table I) (32). A similar increase in BDNF has also been observed after rTMS treatment in a number of other studies (36,81). Additionally, rTMS treatment positively regulates the BDNF receptor TrkB. Chen et al (81) observed an increase in TrkB in the AD brain after 5 Hz HF-rTMS. In addition, LF-rTMS also regulates BDNF levels in AD (Table I) (82). A previous study revealed that 1 Hz LF-rTMS upregulates BDNF content in the hippocampal region of the AD brain (82). Tan et al (82) also reported the effects of LF-rTMS on another NTF, NGF, which is essential for growth, development, survival and neuronal population. The expression of NGFs has been found to be altered in AD (Table I). The 1 Hz LF-rTMS treatment upregulates NGF content in AD (Aβ injected mice) group compared to control (saline injected) group (82). Similar results have also been published by Chen et al (83), who applied both 1 and 10 Hz rTMS and observed that both frequencies of rTMS regulated the brain levels of NTFs (BDNF and NGF), and these increased with increased frequency. Furthermore, glial cells, astrocytes and neurons secrete BDNF and NGF, which could be increased following rTMS treatment, therefore rescue memory deficit (82) In contrast to that in AD, various studies have indicated that rTMS application tends to decrease BDNF levels in healthy volunteers (84,85). However, the precise mechanisms of direct evaluation of BDNF levels in humans after TMS treatment remain unclear (86). BDNF levels are associated with TMS treatment, both during and after treatment. Briefly, these findings suggest that BDNF could be an ideal biomarker for TMS treatment for patients with AD.

Oxidative stress serves a key role in the etiology and pathogenesis of AD. The imbalance in cell redox status, ROS production and impaired antioxidant defense lead to oxidative stress (87). These forms of damage serve a pivotal role in cellular dysfunction, potentially harming the neurons in aging and neurodegenerative disorders, including AD. AD research has revealed that oxidative stress and free radical damage are associated with histopathological hallmarks of AD, such as amyloid plaques and neurofibrillary tangles (88,89). ROS are free radical oxygen byproducts containing an unpaired electron in their valence shell, and these are generated as a result of cellular respiration. The excessive buildup of ROS, including oxygen radical superoxide and hydrogen peroxide, in the cells or neurons causes DNA or RNA oxidative damage, leading to cell death and tissue damage (87). Mitochondrial dysfunction generates excessive ROS as the byproduct of the electron transport chain, ameliorating the risk of AD (90,91). Therefore, oxidative stress and mitochondrial dysfunction adversely affect the brain, leading to aging and neurodegenerative disorders, particularly AD. Furthermore, studies have indicated that oxidative stress and BDNF are associated with each other (89,92). In addition, oxidative stress could be considered a promising biomarker of AD prognosis (93). In line with this, TMS treatment noninvasively modulates and balances BDNF and oxidative stress levels, thus exerting beneficial antioxidant effects in patients with AD (Fig. 1) (36). Some studies have reported that rTMS increases BDNF levels and decreases oxidative stress in treatment-resistant depression (94), stroke (95) and experimental autoimmune encephalomyelitis (96). However, there are a limited number of experimental studies in the literature demonstrating the effects of TMS on oxidative stress in AD. Only a recent study by Velioglu et al (36) has analyzed the beneficial effects of rTMS on BDNF and oxidative stress levels in patients with AD. For this purpose, 20 Hz rTMS was applied to the lateral parietal cortex in patients with AD. The levels of BDNF, total antioxidant status, total thiol levels and native thiol levels were increased after 20 Hz rTMS treatment. Furthermore, the total oxidant status, oxidative stress index, oxidant enzyme activity and disulfide levels were decreased following left lateral parietal rTMS (Table I) (36). Oxidative stress could be an effective target for the treatment of neurodegenerative disorders; however, there remains a large research gap in terms of investigating the influence of TMS on oxidative stress, antioxidant defense systems, total oxidant/antioxidant status and antioxidant enzymes. More studies are required to fill this research gap.

The onset of AD also negatively influences the metabolism, levels and functioning of synaptic neurotransmitters. There are important contributions of cholinergic and noncholinergic neurotransmitter systems behind the pathophysiological signaling in AD (97). Neurotransmitters are chemical messengers that are released from a nerve to stimulate other nerves across the synapse. Neurotransmitters, including dopamine, glutamate, aspartate and γ-aminobutyric acid (GABA), serve a key role in cognitive control, learning and memory development (98). Therefore, alterations in the metabolism and expression of neurotransmitters lead to synaptic dysfunction, cognitive impairment, learning disabilities and memory deficits. A number of studies have emphasized that the expression of neurotransmitters and receptors is markedly reduced in patients with AD (97,99). Therefore, targeting neurotransmitters, as well as their receptors, could be a rational approach to overcome AD. NIBS by EMF from TMS has the potential to minimize symptoms and elucidate AD pathology by positively regulating neurotransmitter parameters (e.g. dopamine; Fig. 1).

Dopamine is a monoamine neurotransmitter produced in dopaminergic neurons; it is involved in synaptic plasticity and regulates mood, emotional stability, and cognitive and motor function (100). The dopamine receptors (D₁, D₂, D₃, D₄ and D₅) are G-protein-coupled receptors that are mostly expressed in the limbic system and cortex (101). The dopaminergic system serves a pivotal role in the pathophysiology of AD (102). The loss and decrease in dopamine content and its receptors are frequently reported in patients with AD, causing motor impairment and cognitive decline (99,103,104). TMS increases the levels of dopamine and dopamine receptors in patients with AD. However, a limited number of studies have been conducted regarding dopamine levels after TMS application. Furthermore, in healthy volunteers, dopamine tends to increase following deep TMS therapy (105). In a recent study by Choung et al (32), HF (20 Hz) and LF (1 Hz) rTMS were applied to assess dopamine levels and receptor concentrations after rTMS application. The findings suggested that HF-rTMS and LF-rTMS increased the dopamine levels in the hippocampus. The expression of dopamine receptor 4 (DR4) was increased after 1 Hz LF-rTMS in the hippocampus and cerebral cortex of the AD brain compared with that of the LF and non-rTMS AD groups (32). After TMS therapy, the dopamine levels are also increased in healthy volunteers (105,106). The increases in dopamine levels after TMS could allow monitoring of the progress of the brain stimulation of patients with AD by TMS. The dopamine level also has the potential to be a biomarker for TMS treatment.

The N-methyl-D-aspartate receptor (NMDAR) is a critical molecule that serves a key role in synaptic transmission, synaptic plasticity, hippocampal long-term potentiation (LTP), learning and memory (107). NMDAR is a glutamate receptor that is important for excitatory neurotransmitter transmission, synapsis and memory formation (108). In AD, Aβ plaques trigger excessive calcium (Ca²⁺) influx, which enters into neurons via NMDARs, leading to gradual synaptic dysfunction and neuronal cell death (109). However, NMDAR is downregulated in patients with AD (110). Battaglia et al (111) observed neocortical plasticity impairment in patients with AD and amyloid precursor protein (APP)/presenilin-1 mice, which could cause functional deficits of NMDAR. It has been observed that TMS application can regulate neurotransmitters, including NMDAR expression, effectively affecting cognitive function (112). Low-frequency (1 Hz) rTMS increases NMDAR expression, also increasing NMDAR subunits (NR1, NR2A and NR2B) in the hippocampus, thus facilitating LTP and memory formation (82). Furthermore, an increase in NMDAR and vascular endothelial growth factor (VEGF) expression has been observed in a rat model of vascular dementia (VaD) following 5 Hz rTMS treatment (112) and 1 Hz rTMS (69). The increase in NMDAR-related amino acids has also been observed after LF-rTMS (1 Hz) by Niimi et al (113) in patients after stroke. Furthermore, it has been observed that upregulation of NMDAR contributes to enhanced neurotrophic effects (107). Therefore, treating memory deficits promotes synaptic plasticity, hippocampal plasticity and memory formation. Impaired NMDAR function could alter plasticity in AD. An improved understanding of AD pathophysiology would facilitate the development of a novel treatment that regulates NMDAR function and improves plasticity, learning and memory deficits in patients with AD. Furthermore, an increase in NMDAR expression facilitates neuronal recovery following rTMS.

In neurodegenerative disorders, particularly AD, excessive neuronal loss is considered to be common due to apoptosis, which acts as a major cell death pathway in neurons (114,115). In AD, the levels of apoptosis-related Bcl-2 are downregulated, while those of Bax and cleaved caspase-3 are upregulated (116). TMS noninvasively regulates and balances the apoptotic pathways, thus exerting its beneficial effects on the brains of patients with AD (Fig. 1) (33,82,83). TMS suppresses the apoptotic pathways by inhibiting several members of the Bcl-2 family, particularly Bad, Bax and Bcl-X_L, which enhances apoptosis. rTMS (1 and 10 Hz) treatment in AD mouse models increased apoptosis, as reflected by enhanced Bcl-2 expression and decreased levels of Bax and cleaved caspase-3 (83). Similarly, in a VaD rat model, 1 Hz rTMS was found to increase Bcl-2 expression and suppress Bax expression (69). A study on a middle cerebral artery occlusion rat model revealed that 10 Hz rTMS treatment markedly upregulated Bcl-2 expression and decreased the levels of Bax and TUNEL-positive cells in the ischemic hippocampus (117). Studies have demonstrated that rTMS suppresses the apoptosis and apoptotic pathways, and thus, rTMS may improve cognitive impairment and exert neuroprotective effects on neurons in an affected brain, particularly in AD (78,83,118). rTMS regulates Bcl-2 and Bax expression, which can promote the functional recovery of cognitive impairments and enhance the protective mechanisms of learning and memory with increased synaptic plasticity; this mechanism may be mediated by the BDNF signaling pathway (117). More research is required to study the effects of TMS on apoptosis in AD pathology. However, TMS could be a promising candidate for the clinical treatment of AD.

AD is associated with progressive and irreversible loss of memory, decline in cognitive function, and deterioration of attention, executive function, thinking and behavioral abilities. In AD, language, reasoning, social behavior, verbal and auditory naming, and the ability to carry out simple tasks are also severely impaired due to underlying neurodegenerative processes (119–121). Executive functions, including working memory and selective attention, are typically associated with the dorsolateral prefrontal cortex (DLPFC). Impaired DLPFC neuroplasticity is associated with the physiopathology of AD, severely affecting the executive functions in patients with AD (122,123). Some studies have assessed DLPFC plasticity in patients with AD using paired associative stimulation (PAS), a TMS paradigm, as a measure of DLPFC and potentiation of cortical-evoked activity (124). PAS is the combination of repeated pairing of single pulses of peripheral nerve electrical stimulation with single pulses of TMS of the contralateral cerebral cortex. PAS (TMS with electroencephalography) results in short-term modulation of corticospinal excitability and induces LTP-like plasticity in the different pathological stages of AD (122,124,125). Furthermore, the impaired LTP-like cortical plasticity could be a potential biomarker for the prognosis of AD (126). A recent study revealed that 20 Hz rTMS improved cognition in AD (29). Cortical LTP-like plasticity is associated with cognitive function improvement in patients with AD following rTMS (49). In view of this, TMS positively regulates executive function, cognitive ability and visuospatial learning behavior in DLPFC (127).

Numerous studies have highlighted the fact that TMS can improve cognitive and executive functions, memory and language ability in patients with AD (29,33,66,128). However, to the best of our knowledge, the molecular and metabolic changes following rTMS are still unknown. The effects of LF-rTMS and HF-rTMS on neuronal plasticity and the learning process in memory tasks have been studied extensively. Cappa et al (129) reported that 20 Hz rTMS activates the DLPFC, facilitating object and action naming. Similarly, high-frequency (20 Hz) rTMS applied to the left and right DLPFC improves naming performance not only in mild AD (130), but also in severe AD (131). rTMS may enable the intrinsic ability of the brain to recover damaged function (131). Another study by Cotelli et al (132) suggested that rhythmic HF-rTMS over DLPFC exerts beneficial effects on sentence comprehension and may be used to treat language dysfunction in patients with AD. However, the exact underlying mechanisms involved in rTMS improving naming and speech are still elusive. Ahmed et al (133) demonstrated that (20 Hz) HF-rTMS for five daily sessions over the left and right DLPFC improved cognitive functions in patients with mild to moderate AD. Zhang et al (134) combined HF-rTMS with cognitive training (rTMS-CT), revealing that the ratio of N-acetylaspartate/creatine (NAA/Cr) increased in the left DLPFC of AD patients. Furthermore, the choline (Cho)/Cr and myoinositol (mI)/Cr ratios remained unchanged in the rTMS-CT group compared to sham group (sham rTMS with CT). The study also proposed that rTMS-CT may improve cognitive function in patients with AD who are in a mild to moderate stage (134). On the other hand, low-frequency (1 Hz) rTMS applied over the left DLPFC of patients with AD has been found to facilitate no change in memory performance. However, when applied to the right DLPFC, low-frequency (1 Hz) rTMS improves recognition memory function (135). Additionally, 20 Hz rTMS on the lateral parietal cortex in patients with AD increases visual recognition memory (36). Furthermore, 1 Hz LF-rTMS could potentially rescue spatial learning and memory deficits accompanied by impaired LTP-plasticity in the hippocampal CA1 region in an APP23/PS45 double transgenic mouse model of AD (136). Future studies will also investigate the short- and long-term effects of rTMS on AD and cognitive functions (48). Furthermore, rTMS improves spatial working memory in mouse models of AD (32), visuospatial reasoning, and trained associative memory in patients with AD (137). Accordingly, these studies have concluded that rTMS could be beneficially and therapeutically effective for NIBS, behavioral recovery and cognitive rehabilitation, as well as a well-tolerated therapy for patients with AD. The cortical changes induced by rTMS can improve synapsis and neuronal plasticity (138). In addition, there are only limited experimental studies highlighting the neurobiological changes during cognitive rehabilitation by rTMS (134). We hypothesize that changes in metabolites or other molecular indices could serve as biomarkers following rTMS, allowing for further improvement of the accurate and precise functioning of neurons in AD. Therefore, future studies should focus on the levels of metabolites and NAA/Cr, Cho/Cr and mI/Cr ratios after TMS treatment to further explore the therapeutic effects of rTMS on cognitive rehabilitation in AD.

miRNAs are novel, short (~22 nucleotides), evolutionarily conserved, noncoding RNA molecules that are post-transcriptional regulators of gene expression, cell proliferation, differentiation and apoptosis (139,140). miRNAs serve an important role in regulating the translation and stability of mRNAs, are involved in pathological processes, and inhibit their translation by guiding RNA-induced silencing complex and complement binding or interacting with the 3′-untranslated region of mRNA (141,142). An increasing number of studies have demonstrated that approximately one-half of the miRNAs are in proximity to other miRNAs and regulate the activity of 60% of all protein-coding genes (140,143). A single miRNA regulates almost 400 different mRNAs (144). It has also been reported that miRNAs serve a pivotal role in synaptic formation, development function, plasticity and neuronal processes, such as neural proliferation, differentiation, maturation and migration (145–147). Studies have demonstrated that miRNAs contribute to the development of numerous diseases and neurodegenerative disorders, including AD (141,147). The changes in the levels of miRNAs could also serve as diagnostic biomarkers for AD (148,149). Different miRNAs have been found to be associated with the accumulation of Aβ peptides and tau phosphorylation (141,150), leading to the pathophysiology of AD. Furthermore, miRNAs also regulate oxidative stress and vice versa (142).

TMS might also have the ability to regulate miRNA expression in AD (Fig. 1). In line with this, future studies are required to clarify whether TMS regulates gene expression and miRNAs. However, a few studies have reported the effects of TMS on miRNAs. Liu et al (151) investigated the effects of rTMS on the proliferation of neural stem cells (NSCs) and their association with miRNAs expression in vivo. The 10 Hz rTMS treatment was associated with the upregulation of the miRNA-106b-25 cluster and miR-93, the downregulation of p21 protein and enhanced NSC proliferation (151). Liu et al (152) also investigated the effects of rTMS on the proliferation of neural progenitor cells (NPCs) and the association with miR-106b expression when 10 Hz rTMS was applied to the NPCs cultured from a rat hippocampus. The results revealed that rTMS enhanced NPC proliferation by upregulating miR-106b expression by inhibiting p21 expression (152). Another study by Aydin-Abidin et al (153) examined the effects of low-frequency (1 Hz) rTMS, high-frequency (10 Hz) rTMS and intermittent theta-burst stimulation (iTBS) on the expression of immediate early gene (IEG) proteins c-Fos and zinc finger protein 268 (zif268) in the rat brain. It was observed that LF-rTMS and HF-rTMS increased c-Fos protein expression in the cortical areas. LF-rTMS did not regulate zif268 expression, but HF-rTMS increased zif268 expression in the primary motor and sensory cortices. Additionally, iTBS increased c-Fos expression in limbic cortices only and zif268 levels in all cortical areas (153). One study investigated the effects of a low-frequency pulsed EMF (LF-PEMF) on protein (BACE1) and miRNA expression involved in AD (70). It was revealed that 75 Hz LF-PEMF modulated the expression of miR-107, miR-335-5p and miR26b-5p in an experimental cell model of peripheral blood mononuclear cells from patients with AD. miR-107 regulates β-site APP-cleaving enzyme 1 (BACE1), which serves a role in the amyloidogenic pathway of the APP pathway. An increasing LF-PEMF exposure time reduced miRNAs expression and BACE1 level (Table I) (70). Recently, Perez et al (154) reported that repeated EMF stimulation reduces Aβ40 and Aβ42 peptides in primary human brain cultures. In a similar vein, another study reported that low-frequency (1 Hz) rTMS progressively downregulated APP and its C-terminal fragments (CTFs) in the AD mouse brain. The decrease in β-secretase generated C99 and C89 fragments, and BACE1 could be observed following 1 Hz rTMS application in transgenic mice (136). Accordingly, it was also demonstrated that rTMS may suppress β-secretase cleavage of APP proteins, contributing toward the decrease in Aβ neuropathology, such as neuritic plaque formations, APP processing and BACE1 expression, which may contribute to the amelioration of cognitive functioning and synaptic plasticity (136). Therefore, TMS exerts anti-AD effects by targeting Aβ peptides, modulating gene expression in the AD brain and reducing AD-related neuropathology in patients with AD.