Abstract
Vinpocetine (VPN) is an ethyl apovincaminate that has anti-inflammatory and antioxidant effects by inhibiting the expression of nuclear factor kappa B (NF-κB) and phosphodiesterase enzyme 1 (PDE-1). VPN is used in the management of stroke, dementia, and other neurodegenerative brain diseases. VPN may be effective in treating Parkinson’s disease (PD). Therefore, this review aimed to clarify the mechanistic role of VPN in the management of PD. VPN has protective and restorative effects against neuronal injury by reducing neuroinflammation, and improvement of synaptic plasticity and cerebral blood flow. VPN protects dopaminergic neurons by reducing oxidative stress, lipid peroxidation, glutamate neurotoxicity, and regulation of Ca+ 2 overloads. VPN can alleviate PD neuropathology through its anti-inflammatory, antioxidant, antiapoptotic and neurogenic effects. VPN through inhibition of PDE1 improves cyclic adenosine monophosphate (cAMP)/cyclic guanosine monophosphate (cGMP) signaling in the dopaminergic neurons of the substantia nigra (SN). VPN improves PD neuropathology through PDE1 inhibition with a subsequent increase of the cAMP/cGMP signaling pathway. Therefore, increasing cAMP leads to antioxidant effects, while augmentation of cGMP by VPN leads to anti-inflammatory effects which reduced neurotoxicity and development of motor severity in PD. In conclusion, this review indicated that VPN could be effective in the management of PD.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Vinpocetine (VPN) is an ethyl apovincaminate (Fig. 1) derived from vinca alkaloid vincamine extracted from Vocanga Africana seeds and Vinca minor leaves (Al-Kuraishy et al. 2020).
VPN was first used in 1978 to treat dementia, stroke, and memory disorders (Patyar et al. 2011). It has been extensively used to manage dementia and stroke in European and Asian countries. In addition to its usage as a nootropic and dietary supplement; however, it was not approved for therapeutic use in the USA (Al-Kuraishy et al. 2019).
The mechanism of VPN is related to the inhibition of sodium channels, reduction of calcium influx, and antioxidant effects (Al-kuraishy and Al-Gareeb 2020). VPN is regarded as a potent inhibitor of phosphodiesterase enzyme 1 (PDE-1) (Patyar et al. 2011). Besides, VPN has an anti-inflammatory effect by inhibiting the expression of nuclear factor kappa B (NF-κB) via stabilization of IκB, an inhibitor of NF-κB. VPN increases dihydroxyphenylacetic acid (DOPAC), a metabolic product of dopamine that suggests VPN’s role in the metabolism of dopamine (Zhang et al. 2018). Moreover, VPN has anti-platelet activity, thereby improving brain blood flow and brain metabolism (Medina 2010).
VPN is considered a safe drug, though it is contraindicated in pregnancy (Medina 2010). Prolonged use of VPN is associated with the development of some side effects, including hypotension, tachycardia, dizziness, dry mouth, nausea, heartburn, and flushing (Al-Kuraishy et al. 2020). VPN has a specific pharmacokinetic profile; the effective therapeutic dosage of VPN is 5–10 mg (Medina 2010). VPN half-life is 1–2 h; it is highly absorbed from the intestine with 56.6% bioavailability, peak plasma level is reached after one hour of oral administration, highly distributed, crosses the blood-brain barrier (BBB), metabolized by the liver and excreted by urine (Bönöczk et al. 2000; Medina 2010; Patyar et al. 2011).
VPN is effective in managing neurodegenerative brain diseases, including Parkinson’s disease (PD) (Ping et al. 2019). Thus, this review aims to clarify the mechanistic role of VPN in PD.
Parkinson’s disease
PD is the second most common neurodegenerative brain disease, following Alzheimer’s disease (AD) (Alrouji et al. 2023; Poewe et al. 2017). PD was first recognized in 1817 by Doctor James Parkinson, who described shaking palsy (Savica et al. 2010). PD is developed due to dopaminergic neuron loss in the substantia nigra (SN) with subsequent significant dopamine deficiency in the caudate nucleus and putamen (Savica et al. 2010). These pathological changes lead to motor dysfunctions, including rigidity, resting tremors, bradykinesia and walking difficulty (Savica et al. 2010). In PD, many non-motor disorders include apathy, depression, anxiety, autonomic disorders, dementia, neuropsychiatric disorders, cognitive dysfunction, and sleep disturbances (Thenganatt and Jankovic 2014). The incidence of PD in the general population is 0.3% and reaches 4% above the age of 80 years (Savica et al. 2016). The mean age of PD onset is around 60 years; however, new-onset PD may develop in the younger age group of 20–50 years (Patyar et al. 2011). The annual incidence of PD is 8–18 per 100,000 (Savica et al. 2016). Males are more affected than females by PD, with a ratio of 3:2 (Savica et al. 2016). In 2040, the number of PD patients will extend to 14 million people at risk for the development of the Parkinson’s pandemic (Savica et al. 2016). PD may be genetic due to mutations of 9 autosomal recessive and 11 autosomal dominant, and non-genetic due to exposure to pesticides, carbon disulfide and manganese (Sardi et al. 2018). The neuropathological characteristic of PD is the deposition of Lewy bodies from aggregated α-synuclein (Fig. 2) (Stefanis 2012).
The deposition of α-synuclein is not limited to the SN but throughout the entire brain, such as the autonomic nervous system (ANS) (Stefanis 2012). Deposition of α-synuclein is progressive for many years before the development of a symptomatic period (Stefanis 2012). Deposition of α-synuclein is started initially in the ANS, mostly in the dorsal motor nucleus of glossopharyngeal and vagus nerves and then spreads to the other brain areas in stage I of PD neuropathology (Sharabi et al. 2021). Stage II α-synucleinopathy is propagated by spreading to brain stem areas, including medulla oblongata, locus coeruleus and pontine tegmentum. In stage III α-synucleinopathy, the SN is affected. During stage IV α-synucleinopathy, there is profound degeneration of dopaminergic neurons in the SN and pathology of Lewy bodies extended to the temporal cortex. In the last V and VI stages, Lewy bodies are highly deposited in the neocortex leading to the development of cognitive dysfunction (Niwa et al. 2011). These verdicts proposed that PD neuropathology is progressive and not limited to SN degeneration. Notably, in the prodromal phase, non-motor symptoms, including anosmia, constipation, sleep disorders, and depression, develop before dopaminergic degeneration in the SN. Following the development of motor symptoms due to dopaminergic degeneration in the SN, cognitive dysfunctions are propagated due to the involvement of the temporal cortex (Wakabayashi 2020).
Novel treatment for the management of PD is required. The management of PD should be broader than symptomatic improvement, as treatment of non-motor symptoms remains challenging and not traditional. However, early detection of PD neuropathology before the development of excitotoxicity and apoptosis may prevent symptomatic PD. Though, most PD in animal model studies reflects the acute status of dopaminergic neuron degeneration regardless of PD neuropathology stages (Biswas and Bagchi 2023). Recently, it has been shown that nicotine, caffeine and some natural products like polyphenols in green tea prevent mutation in the parkin protein, which is involved in the pathogenesis of PD (Biswas and Bagchi 2023). Interfering with aggregation of α-synuclein like nicotine and caffeine could prevent PD (Biswas and Bagchi 2023). Furthermore, inosine, a urate precursor, may prevent dopaminergic neuron degeneration in the SN (Bluett et al. 2021). In addition, many preclinical studies have proposed immunotherapy against α-synuclein by either active or passive immunizations (Poewe et al. 2021). Of interest, modulators of α-synuclein aggregations have been suggested to be effective in the prevention of PD (Al-kuraishy et al. 2023; Wang et al. 2021). VPN could be of interest in managing PD because of its anti-inflammatory and antioxidant activities.
Neuroprotective effects of VPN
VPN has protective and restorative effects against neuronal injury by reducing neuroinflammation and synaptic plasticity and improving cerebral blood flow in acute ischemic stroke (Bönöczk et al. 2000). VPN has been reported to be effective against stroke, chronic cerebral insufficiency, and cerebral atherosclerosis (Cai et al. 2013). VPN attenuates endothelial dysfunction and lipid accumulation by inhibiting macrophage activity and oxidation of low-density lipoprotein (LDL) (Cai et al. 2013). VPN also effectively manages epilepsy and dementia through the modulation of synaptic plasticity and neurotransmission (Meador et al. 2021). A recent randomized clinical trial by Garza-Morales et al. (2019) showed that VPN effectively treated focal epilepsy. An experimental study confirmed that VPN effectively alleviated cerebral ischemic reperfusion (I/R) injury and associated neuroinflammation by inhibiting microglia activation (Wang et al. 2014). A pilot single-blind clinical trial illustrated that VPN improved clinical outcomes in patients with acute ischemic stroke (Feigin et al. 2001).
Moreover, VPN improves regional brain blood flow via redistribution of cerebral blood flow (CBF) in patients with chronic cerebral ischemia (Szilágyi et al. 2005). A double-blind imaging study involving 13 patients with chronic ischemia revealed that VPN increased regional and global cerebral blood flow (Szilágyi et al. 2005). Thus, VPN had a neuroprotective effect via redistribution of cerebral blood flow. VPN regulates blood viscosity and increases CBF modulation of erythrocyte deformability and vasodilation in patients with acute ischemic stroke (Panda et al. 2022). A systematic review and meta-analysis involving four clinical trials of 236 patients on VPN and placebo showed that VPN was effective in patients with acute ischemic stroke without reduction of case fatality (Panda et al. 2022). VPN regulates the neuroplastic process by controlling glial activity and glucose uptake (Xu et al. 2021). Moreover, VPN improves cognitive function in patients with AD and epilepsy (Valikovics et al. 2012).
Furthermore, VPN reduces the expression of NF-κB and the release of pro-inflammatory cytokines after I/R, thereby preventing the development of brain edema (Wang et al. 2014). In vitro study observed that VPN had a protective activity on cortical neurons by preserving mitochondrial function via regulation of mitochondrial membrane potential (MMP) (Tárnok et al. 2008). VPN has been reported to interfere with various signaling cascades during brain ischemic events, including activation of voltage-gated Na+ channel, adenosine triphosphate (ATP) depletion, glutamate excitotoxicity and Ca+ 2 dysregulation (Hadjiev 2003). VPN has potent antioxidant and anti-inflammatory effects that attenuate BBB dysfunction during brain ischemic events (Hadjiev 2003). These findings suggest VPN’s universal role in managing different neurological disorders (Fig. 3).
Role of VPN in PD
Numerous studies confirmed the protective effects of VPN against the development of PD. For example, an experimental study by Zaitone et al. (2012) showed that VPN attenuated rotenone-induced PD in rats. VPN protects dopaminergic neurons by reducing oxidative stress, lipid peroxidation, glutamate neurotoxicity and regulation of Ca+ 2 overload (Zaitone et al. 2012). Likewise, pre-treatment with VPN reduced the rotenone-induced locomotor deficit, motor incoordination, and cognition deficits in rats (Ishola et al. 2023). In addition, rotenone-induced a significant increase in the level of interleukin (IL)-6, tumor necrosis factor-alpha (TNF-α), oxidative stress markers, cholinergic signaling, guts dysfunction and hematologic dysfunctions which were attenuated by VPN administration. Immunostainings showed that rotenone-induced dopamine neuron loss, microglia reactivity, astrocytes activation, toll-like receptor4 (TLR4) and α-synuclein expressions were attenuated by VPN administration (Ishola et al. 2023). VPN also attenuates paraquat-induced PD in mice by improving antioxidant defense mechanisms and inhibiting neuroinflammation (Ishola et al. 2018). These preclinical findings indicated that VPN can alleviate PD neuropathology through its anti-inflammatory, antioxidant, antiapoptotic and neurogenic effects (Abu-Elfotuh et al. 2022).
A recent clinical study involving 89 PD patients compared to 42 healthy controls observed that VPN was influential in managing cognitive impairment in PD patients (Ping et al. 2019). The cognitive enhancing effect of VPN is related to its potent anti-inflammatory effects. Circulating levels of TLR and pro-inflammatory cytokines were reduced in PD patients following treatment with VPN (Ping et al. 2019). The anti-inflammatory role of VPN in the treatment of PD. VPN regulates TLR2/3/4 mRNA and protein expression; moreover, it modulates downstream signaling proteins and cytokines. However, there is no stable or clear cause-effect relationship between its anti-inflammatory action and cognitive enhancement. Thus, VPN is a good candidate for future therapy in PD patients (Ping et al. 2019).
These observations indicated that VPN has a neuroprotective effect against the development and progression of PD neuropathology.
Mechanistic role of VPN in PD
Neuroinflammation
Neuroinflammation transcription factors and are involved in the pathogenesis and progression of PD (Tiwari and Pal 2022). Neuroinflammation has been recognized as a cornerstone in the progression of neurodegenerative diseases and especially in the chronic loss of nigral dopaminergic neurons in PD. Noteworthy, the generation of reactive oxygen species (ROS) induces inflammation through the activation of NF-кB activation which in turn led to enhanced production of downstream proinflammatory mediators (Hirsch et al. 2012). Lipopolysaccharide (LPS) activation adjacent to the dopaminergic neurons in the SN increases neuronal loss and degeneration (Tiwari and Pal 2022). Postmortem analysis of brain tissues and cerebrospinal fluid of PD patients demonstrated that NF-κB, mechanistic target of rapamycin (mTOR), Ying-Yang1 (YY1) and fibroblast growth factor 20 (FGF20) were over-expressed and associated with the dopaminergic neuronal loss (Tiwari and Pal 2022). Both pro-inflammatory cytokines and chemokines are linked with dopaminergic degeneration in the SN with the propagation of PD (Hirsch et al. 2012; Tiwari and Pal 2022). VNP had a protective effect against pilocarpine-induced seizures by inhibiting the mTOR pathway in rats (El-Sayed et al. 2021). Therefore, VNP is a valuable candidate for epilepsy therapy via its modulation of the mechanisms underlying epileptogenesis with emphasis on its modulatory effect on the mTOR signaling pathway (El-Sayed et al. 2021). VPN has been observed to inhibit neuroinflammation in preclinical and clinical studies (Zhou et al. 2020). VPN in hypoxic mice inhibits inflammatory molecules including IL-6 and TNF-α which are involved in the development of neuroinflammation, indicating that VPN as a unique anti-inflammatory agent may be beneficial for the treatment of neuroinflammatory diseases (Zhao et al. 2011). In vitro study demonstrated that VPN inhibits microglia activation induced by LPS (Zhou et al. 2020). In vitro study demonstrated that VPN inhibits the production of nitirc oxide (NO) and inflammatory factors such as IL-1β, IL-6 and TNF-α in BV-2 microglia, in which cells were treated with LPS by suppressing the expression of translocator protein (TSPO). As well, VPN blocks the expression of Akt, Junk, p38, NF-κB and activator protein-1 (AP-1) in LPS-stimulated microglia, indicating that VPN has an anti-inflammatory effect by partly targeting NF-κB/AP-1 (Zhao et al. 2011). VPN attenuates the release of pro-inflammatory cytokines and the development of neuroinflammation via the activation of adenosine monophosphate protein kinase (AMPK) (Zhou et al. 2020). AMPK is a crucial regulator of immunity and inflammation by inhibiting TLR4 and NF-κB (Zhou et al. 2020). Moreover, the nucleotide-binding oligomerization domain-, leucine-rich repeat and pyrin domain-containing 3 (NLRP3) inflammasome is an inflammatory complex existing in microglia (Batiha et al. 2022). Its activation promotes the secretion of the inflammatory cytokine interleukin-1β/18 (IL-1β/18) and induces pyroptosis, a type of cell death that possesses the potential for inflammation, to rupture microglia to further release IL-1β (Wang et al. 2019). NLRP3 inflammasomes play a crucial role in PD via caspase 1 activation, primarily induced by mitochondrial damage. NLRP3 binds to apoptosis-associated speck-like protein and forms inflammasomes in the brain. Inflammasomes act as a platform for caspase 1 to induce IL1β maturation, leading to neuronal pyroptosis (Sarkar et al. 2017). Moreover, α-synuclein also activates NLRP3 inflammasomes. Mutations to PRKN (encoding Parkin) are the most common cause of autosomal recessive familial and sporadic early-onset PD. Evidence has confirmed a relationship between Parkin and NLRP3 inflammasomes (Fan et al. 2020). It has been shown that VPN has ability to inhibit the expression of NLRP3 inflammasomes in mice with age-related macular degeneration (Liu et al. 2014). As well, VPN alleviates ischemic stroke by regulating levels of NLRP3 inflammasome, and proinflammatory cytokines in mice, offering an alternative medication for ischemic stroke associated with inflammation (Han et al. 2021).
These findings pointed up that VPN attenuates neuroinflammation-induced PD by inhibiting the expression of inflammatory signaling NF-κB/ NLRP3 inflammasome and the release of pro-inflammatory cytokines. These verdicts confirmed that VPN can attenuate neuroinflammation which is involved in the pathogenesis of PD.
Oxidative stress
Mitochondrial dysfunction, the release of ROS and the development of oxidative stress are involved in the pathogenesis of PD (Henchcliffe and Beal 2008). Oxidative stress is believed to play a critical role in dopaminergic neurotoxicity (Blesa et al. 2015). In PD, mitochondrial dysfunction is the primary source of ROS linked with dopaminergic neurotoxicity (Blesa et al. 2015). Dysfunction of different pathways due to genetic variations increases the risk of oxidative stress due to mitochondrial dysfunction (Blesa et al. 2015). Oxidative stress promotes aggregation of α-synuclein with a reduction of intracellular ATP production and development of dopaminergic neuron degeneration (Fig. 4). Of note, α-synuclein overexpression promotes the formation of α-synuclein-immunopositive inclusion-like structures and mitochondrial alterations accompanied by increased levels of free radicals (Han et al. 2021). These alterations are ameliorated by pretreatment with antioxidants such as vitamin E (Hsu et al. 2000). Taken together these results suggest that abnormal accumulation of α-synuclein could lead to mitochondrial alterations that may result in oxidative stress and, eventually, cell death. A systematic review and meta-analysis revealed that PD is accompanied by increased oxidative stress (Wei et al. 2018). Different studies revealed that VPN has antioxidant effects (Deshmukh et al. 2009; Santos et al. 2000). VPN can act as an antioxidant and prevent the formation of ROS and lipid peroxidation in rat brain synaptosomes (Santos et al. 2000). The antioxidant effect of VPN might contribute to the protective role exerted by reducing neuronal damage in pathological situations (Santos et al. 2000). Chronic treatment with VPN also reduced significantly the increase in acetylcholinesterase activity and lactate dehydrogenase levels indicating the restorative capacity of VPN concerning cholinergic functions and preventing the neuronal damage (Deshmukh et al. 2009). The observed beneficial effects of VPN on spatial memory may be due to its ability to favorably modulate cholinergic functions, prevent neuronal cell damage and possibly through its antioxidant mechanism (Deshmukh et al. 2009). VPN inhibits oxidative stress by scavenging free radicals, prevention of Glutathione (GSH) depletion, reducing superoxide anion and nitric oxide production, and lipid peroxidation (Ruiz-Miyazawa et al. 2015). Moreover, VPN prevents paraquat-induced motor deficits, memory impairment, oxidative stress, and neuroinflammation through the enhancement of the antioxidant defense system and the inhibition of neuroinflammatory cytokine (Ishola et al. 2018). Furthermore, VPN attenuates demyelination in the brain rats by inhibiting oxidative stress and lipid peroxidation (Ruiz-Miyazawa et al. 2015). These findings pointed out that VPN by its antioxidant effect can mitigate PD neuropathology.
PDEs
PDEs are highly expressed in the striatum and SN and regulate dopamine signaling through cAMP/cGMP signaling (Nthenge-Ngumbau and Mohanakumar 2018). Several PDE families are highly expressed in the striatum including PDE1–4, PDE7, PDE9 and PDE10. There are growing evidence to suggest that these enzymes play a critical role in modulating cAMP-mediated dopamine signaling at the postsynaptic region. Therefore, it is clear that PDEs, given the broad range of subtypes and their varied tissue- and region-specific distributions, will be able to provide a range of possibilities as drug targets. There is no phosphodiesterase inhibitor currently approved for use against PD. The development of small molecule inhibitors against cyclic nucleotide PDE is a particularly hot area of investigation, and a lot of research and development is geared in this direction with major players in the pharmaceutical industry investing heavily in developing such potential drug entities (Nthenge-Ngumbau and Mohanakumar 2018). A recent experimental study confirmed that PDE7 is linked with the development of neurodegeneration and neuroinflammation (Morales-Garcia et al. 2020). Therefore, PDE inhibitors, through their neuroprotective effects, could be a new therapeutic strategy for treating PD. Garcia et al. (2014) observed that PDEA10 inhibitors might effectively manage PD and other brain neurodegenerative diseases. Interestingly, synthetic quinazoline derivatives produce a neuroprotective effect against the progression of PD through the inhibition of PDE1 (Laddha and Bhatnagar 2009). VPN improves PD neuropathology through PDE1 inhibition with a subsequent increase of the cAMP/cGMP signaling pathway. Therefore, increasing cAMP leads to antioxidant effects. In contrast, augmentation of cGMP by VPN leads to the development of motor severity in PD (Niccolini et al. 2015). Of note, striatal, and pallidal loss of PDE10A expression, which is associated with Parkinson’s duration and severity of motor symptoms and complications? PDE10A is an enzyme that could be targeted with novel pharmacotherapy, and this may help improve dopaminergic signaling and striatal output and therefore alleviates symptoms and complications of PD (Niccolini et al. 2015). Though, The severity of excessive daytime sleepiness in PD was associated with elevated PDE4 expression (Wilson et al. 2020). Therefore, VPN through inhibition of PDE1 improves cAMP/cGMP signaling in the dopaminergic neurons in the SN. However, none of the PDE inhibitors is approved for managing PD (Fig. 5).
Glycogen synthase kinase 3β
Glycogen synthase kinase-3 (GSK-3) is a pleiotropic serine/threonine protein kinase found in almost all eukaryotes. It is structurally highly conserved and has been identified as a multifaceted enzyme affecting a wide range of biological functions, including gene expression and cellular processes. There are two closely related isoforms of GSK-3; GSK-3α and GSK-3β. The latter appears to play crucial roles in regulating the pathogenesis of diverse diseases, including neurodegenerative diseases including PD (Li et al. 2014). It has been shown that dysregulation of GSK-3β is associated with the pathogenesis of PD and by increasing accumulation of tau protein and production of α-synuclein (Li et al. 2014). GSK-3β has an antioxidant effect by inhibiting the generation of ROS. However, mutant GSK-3β triggers the degeneration of dopaminergic neurons in the SN causing PD (Li et al. 2014). Numerous apoptotic conditions can be facilitated by the GSK-3β signaling pathways. Studies have shown that GSK-3β inhibition protects the dopaminergic neurons from various stress-induced injuries, indicating the involvement of GSK-3β in PD pathogenesis (Li et al. 2014; Wang et al. 2007). However, the underlying mechanisms of the protective effect of GSK-3β inhibition on dopaminergic neurons in PD are not completely understood (Li et al. 2014; Wang et al. 2007). Multiple pathological events have been recognized to be responsible for the loss of dopaminergic neurons in PD, including mitochondrial dysfunction, oxidative stress, protein aggregation, and neuroinflammation (Wang et al. 2007). GSK-3β is a critical intermediate of MPTP neurotoxicity, and inhibition of GSK-3β may provide a novel strategy to treat PD (Wang et al. 2007). Thus, inhibition of dysregulated GSK-3β could be effective in reducing PD severity (Wang et al. 2007). Inhibition of GSK-3β attenuates the development of MPTP-induced PD in mice (Wang et al. 2007). VPN inhibits aluminum-induced cognitive impairment in rats by inhibiting the expression of GSK-3β (Ali et al. 2019). In addition, VPN mitigates ketamine-induced behavioral abnormalities by inhibiting GSK-3β (Ahmed et al. 2018). Therefore, VPN could effectively treat PD by inhibiting the expression of neuronal GSK-3β.
Brain-derived neurotrophic factor
Brain-derived neurotrophic factor (BDNF) is a small dimeric protein, structurally related to nerve growth factor, which is abundantly and widely expressed in the adult mammalian brain (Murer et al. 2001). BDNF has been found to promote survival of all major neuronal types affected in PD, like hippocampal and neocortical neurons, cholinergic septal and basal forebrain neurons, and nigral dopaminergic neurons (Murer et al. 2001). BDNF is a potent inhibitor of apoptosis-mediated cell death and neurotoxin-induced degeneration of dopaminergic neurons. There is a growing body of evidence implicating BDNF in the pathogenesis of PD, suggesting it may eventually be used in the development of neuroprotective therapies for PD (Scalzo et al. 2010). A case-control study on 47 PD patients and 23 control subjects showed that serum BDNF serum level was significantly decreased in PD patients when compared with controls (Scalzo et al. 2010). Though, BDNF serum level was higher in the late stage of PD patients (Scalzo et al. 2010). Therefore, lower BDNF levels in the early stages of the disease may be associated with pathogenic mechanisms of PD, and an increase of BDNF levels with the progression of the disease may be a compensatory mechanism in more advanced stages of PD. A systematic review and meta-analysis revealed that PD patients had reduced serum BDNF levels compared to healthy controls, regardless of the presence of co-morbid depression. PD is at least equally effective in reducing serum BDNF levels as depression (Rahmani et al. 2019). Motor progression predicts serum BDNF downregulation in PD. Acute exercise improves motor function and depressive symptoms in PD probably via BDNF upregulation. The paradoxical rise in serum BDNF in advance of PD is probably compensatory in nature (Rahmani et al. 2019). Therefore, activating of BDNF signaling pathway in the early stage of PD may attenuate the progression of PD neuropathology. It has been reported that VPN can reverse the synaptic ultrastructure by regulating BDNF-related PSD-95 to alleviate schizophrenia-like deficits induced by ketamine in rats (Xu et al. 2019). The underlying mechanism is that VPN could increase cAMP and cGMP levels, thereby increasing the activity of cAMP and cGMP-dependent protein kinase A (PKA) and protein kinase G (PKG), which could promote the activation of many genes, such as BDNF (Swart et al. 2017). As well, VPN improves behavioral changes in autism spectrum disorder in rats by improvement of BDNF signaling (Luhach et al. 2022). Therefore, VPN through the improvement of BDNF signaling may attenuate PD neuropathology.
Taken together, VPN may improve PD by anti-inflammatory and antioxidant effects with modulation of various signaling pathways including NF-κB, NLRP3 inflammasomes, GSK-3β and BDNF.
Conclusion
VPN has anti-inflammatory and antioxidant effects by inhibiting the expression of NF-κB and PDE-1. VPN is used in the management of dementia and stroke. VPN has protective and restorative effects against neuronal injury by reducing neuroinflammation and synaptic plasticity and improving cerebral blood flow. VPN protects dopaminergic neurons by reducing oxidative stress, lipid peroxidation, glutamate neurotoxicity, and regulation of Ca+ 2 overloads. Likewise, VPN can alleviate PD neuropathology through its anti-inflammatory, antioxidant, antiapoptotic and regulation of inflammatory signaling pathways. Moreover, VPN could effectively treat PD by inhibiting the expression of neuronal GSK-3β. VPN also attenuates neuroinflammation-induced PD by inhibiting the expression of inflammatory signaling NF-κB and the release of pro-inflammatory cytokines. VPN through inhibition of PDE1 improves cAMP/cGMP signaling in the dopaminergic neurons in the SN. This review indicated that VPN could be effective in the management of PD. However, preclinical and prospective studies are warranted to confirm the possible beneficial role of VPN in PD.
Data availability
Not applicable.
Code availability
Not applicable.
References
Abu-Elfotuh K, Hamdan AME, Abbas AN, Alahmre ATS, Elewa MA, Masoud RAE, Ali AA, Othman M, Kamal MM, Hassan FAM (2022) Evaluating the neuroprotective activities of vinpocetine, punicalagin, niacin and vitamin E against behavioural and motor disabilities of manganese-induced Parkinson’s disease in Sprague Dawley rats. Biomed Pharmacother 153:113330
Ahmed HI, Abdel-Sattar SA, Zaky HS (2018) Vinpocetine halts ketamine-induced schizophrenia-like deficits in rats: impact on BDNF and GSK-3β/β-catenin pathway. Naunyn-Schmiedeberg’s Arch Pharmacol 391:1327–1338
Al-kuraishy HM, Al-Gareeb AI (2020) Vinpocetine and ischemic stroke. Ischemic stroke 27
Al-Kuraishy HM, Al-Gareeb AI, Al-Nami MS (2019) Vinpocetine improves oxidative stress and pro-inflammatory mediators in acute kidney injury. Int J Prev Med 10:142. https://doi.org/10.4103/ijpvm.IJPVM_5_19
Al-kuraishy HM, Al-Gareeb AI, Alexiou A, Papadakis M, Alsayegh AA, Almohmadi NH, Saad HM, Batiha GE-S (2023) Pros and cons for statins use and risk of Parkinson’s disease: an updated perspective. Pharmacol Res Perspect 11:e01063
Al-Kuraishy HM, Al-Gareeb AI, Naji MT, Al-Mamorry F (2020) Role of vinpocetine in ischemic stroke and poststroke outcomes: a critical review. Brain Circulation 6:1
Ali AA, Ahmed HI, Khaleel SA, Abu-Elfotuh K (2019) Vinpocetine mitigates aluminum-induced cognitive impairment in socially isolated rats. Physiol Behav 208:112571
Alrouji M, Al-Kuraishy HM, Al-Gareeb AI, Saad HM, Batiha GE-S (2023) A story of the potential effect of non-steroidal anti-inflammatory drugs (NSAIDs) in Parkinson’s disease: beneficial or detrimental effects. Inflammopharmacology 31: 673–688. https://doi.org/10.1007/s10787-023-01192-2
Batiha GE, Al-Gareeb AI, Rotimi D, Adeyemi OS, Al-Kuraishy HM (2022) Common NLRP3 inflammasome inhibitors and Covid-19: divide and conquer. Sci African 18:e01407
Biswas S, Bagchi A (2023) Study of the effects of nicotine and caffeine for the treatment of Parkinson’s disease. Appl Biochem Biotechnol 195:639–654
Blesa J, Trigo-Damas I, Quiroga-Varela A, Jackson-Lewis VR (2015) Oxidative stress and Parkinson’s disease. Front Neuroanat 9:91
Bluett B, Togasaki DM, Mihaila D, Evatt M, Rezak M, Jain S, Schwarzschild MA, Ascherio A, Casaceli C, Curhan GC (2021) Effect of urate-elevating inosine on early Parkinson disease progression: the SURE-PD3 randomized clinical trial. JAMA 326:926–939
Bönöczk P, Gulyás B, Adam-Vizi V, Nemes A, Kárpáti E, Kiss B, Kapás M, Szántay C, Koncz I, Zelles T (2000) Role of sodium channel inhibition in neuroprotection: effect of vinpocetine. Brain Res Bull 53:245–254
Cai Y, Li J-D, Yan C (2013) Vinpocetine attenuates lipid accumulation and atherosclerosis formation. Biochem Biophys Res Commun 434:439–443
Deshmukh R, Sharma V, Mehan S, Sharma N, Bedi K (2009) Amelioration of intracerebroventricular streptozotocin induced cognitive dysfunction and oxidative stress by vinpocetine—a PDE1 inhibitor. Eur J Pharmacol 620:49–56
El-Sayed SS, El-Yamany MF, Salem HA, El-Sahar AE (2021) New insights into the effects of vinpocetine against neurobehavioral comorbidities in a rat model of temporal lobe epilepsy via the downregulation of the hippocampal PI3K/mTOR signalling pathway. J Pharm Pharmacol 73:626–640
Fan Z, Pan Y-T, Zhang Z-Y, Yang H, Yu S-Y, Zheng Y, Ma J-H, Wang X-M (2020) Systemic activation of NLRP3 inflammasome and plasma α-synuclein levels are correlated with motor severity and progression in Parkinson’s disease. J Neuroinflammation 17:1–10
Feigin V, Doronin B, Popova T, Gribatcheva E, Tchervov D (2001) Vinpocetine treatment in acute ischaemic stroke: a pilot single-blind randomized clinical trial. Eur J Neurol 8:81–85
Garcia A, Redondo M, Martinez A, Gil C (2014) Phosphodiesterase 10 inhibitors: new disease modifying drugs for Parkinson’s disease? Curr Med Chem 21:1171–1187
Garza-Morales S, Briceño-González E, Ceja-Moreno H, Ruiz-Sandoval JL, Góngora-Rivera F, Rodríguez-Leyva I, Alonso-Rivera CG (2019) Extended-release vinpocetine: a possible adjuvant treatment for focal onset epileptic seizures. Bol Med Hosp Infant Mex 76:215–224
Hadjiev D (2003) Asymptomatic ischemic cerebrovascular disorders and neuroprotection with vinpocetine. Ideggyogyaszati Sz 56:166–172
Han D, Wang J, Wen L, Sun M, Liu H, Gao Y (2021) Vinpocetine attenuates ischemic stroke through inhibiting NLRP3 inflammasome expression in mice. J Cardiovasc Pharmacol 77:208
Henchcliffe C, Beal MF (2008) Mitochondrial biology and oxidative stress in Parkinson disease pathogenesis. Nat Clin Pract Neurol 4:600–609
Hirsch EC, Vyas S, Hunot S (2012) Neuroinflammation in Parkinson’s disease. Parkinsonism Relat Disord 18:S210–S212
Hsu LJ, Sagara Y, Arroyo A, Rockenstein E, Sisk A, Mallory M, Wong J, Takenouchi T, Hashimoto M, Masliah E (2000) α-Synuclein promotes mitochondrial deficit and oxidative stress. Am J Pathol 157:401–410
Ishola IO, Akinyede A, Adeluwa T, Micah C (2018) Novel action of vinpocetine in the prevention of paraquat-induced parkinsonism in mice: involvement of oxidative stress and neuroinflammation. Metab Brain Dis 33:1493–1500
Ishola I, Awogbindin I, Olubodun-Obadun T, Olajiga A, Adeyemi O (2023) Vinpocetine prevents rotenone-induced Parkinson disease motor and non-motor symptoms through attenuation of oxidative stress, neuroinflammation and α-synuclein expressions in rats. Neurotoxicology 96:37–52
Laddha SS, Bhatnagar SP (2009) A new therapeutic approach in Parkinson’s disease: some novel quinazoline derivatives as dual selective phosphodiesterase 1 inhibitors and anti-inflammatory agents. Biorg Med Chem 17:6796–6802
Li DW, Liu ZQ, Chen W, Yao M, Li GR (2014) Association of glycogen synthase kinase–3β with Parkinson’s disease. Mol Med Report 9:2043–2050
Liu RT, Wang A, To E, Gao J, Cao S, Cui JZ, Matsubara JA (2014) Vinpocetine inhibits amyloid-beta induced activation of NF-κB, NLRP3 inflammasome and cytokine production in retinal pigment epithelial cells. Exp Eye Res 127:49–58
Luhach K, Kulkarni G, Singh V, Sharma B (2022) Vinpocetine ameliorates developmental hyperserotonemia induced behavioral and biochemical changes: role of neuronal function, inflammation, and oxidative stress. Acta Neurobiol Exp (Wars) 82:35–51
Meador KJ, Leeman-Markowski B, Medina AE, Illamola SM, Seliger J, Novak G, Lin C, Ivanisevic M, Razavi B, Marino S (2021) Vinpocetine, cognition, and epilepsy. Epilepsy Behav 119:107988
Medina AE (2010) Vinpocetine as a potent antiinflammatory agent. Proc Natl Acad Sci 107:9921–9922
Morales-Garcia JA, Alonso-Gil S, Santos Á, Perez-Castillo A (2020) Phosphodiesterase 7 regulation in cellular and rodent models of Parkinson’s disease. Mol Neurobiol 57:806–822
Murer MG, Yan Q, Raisman-Vozari R (2001) Brain-derived neurotrophic factor in the control human brain, and in Alzheimer’s disease and Parkinson’s disease. Prog Neurobiol 63:71–124
Niccolini F, Foltynie T, Reis Marques T, Muhlert N, Tziortzi AC, Searle GE, Natesan S, Kapur S, Rabiner EA, Gunn RN (2015) Loss of phosphodiesterase 10A expression is associated with progression and severity in Parkinson’s disease. Brain 138:3003–3015
Niwa F, Kuriyama N, Nakagawa M, Imanishi J (2011) Circadian rhythm of rest activity and autonomic nervous system activity at different stages in Parkinson’s disease. Auton Neurosci 165:195–200
Nthenge-Ngumbau DN, Mohanakumar KP (2018) Can cyclic nucleotide phosphodiesterase inhibitors be drugs for Parkinson’s disease? Mol Neurobiol 55:822–834
Panda PK, Ramachandran A, Panda P, Sharawat IK (2022) Safety and efficacy of vinpocetine as a neuroprotective agent in acute ischemic stroke: a systematic review and meta-analysis. Neurocrit Care 37:314–325
Patyar S, Prakash A, Modi M, Medhi B (2011) Role of vinpocetine in cerebrovascular diseases. Pharmacol Rep 63:618–628
Ping Z, Xiaomu W, Xufang X, Liang S (2019) Vinpocetine regulates levels of circulating TLRs in Parkinson’s disease patients. Neurol Sci 40:113–120
Poewe W, Seppi K, Tanner CM, Halliday GM, Brundin P, Volkmann J, Schrag A-E, Lang AE (2017) Parkinson disease. Nat Rev Dis Primers 3:1–21
Poewe W, Volc D, Seppi K, Medori R, Lührs P, Kutzelnigg A, Djamshidian A, Thun-Hohenstein C, Meissner WG, Rascol O (2021) Safety and tolerability of active immunotherapy targeting α-synuclein with PD03A in patients with early Parkinson’s disease: a randomized, placebo-controlled, phase 1 study. J Parkinsons Dis 11:1079–1089
Rahmani F, Saghazadeh A, Rahmani M, Teixeira AL, Rezaei N, Aghamollaii V, Ardebili HE (2019) Plasma levels of brain-derived neurotrophic factor in patients with Parkinson disease: a systematic review and meta-analysis. Brain Res 1704:127–136
Ruiz-Miyazawa KW, Pinho-Ribeiro FA, Zarpelon AC, Staurengo-Ferrari L, Silva RL, Alves-Filho JC, Cunha TM, Cunha FQ, Casagrande R, Verri WA Jr (2015) Vinpocetine reduces lipopolysaccharide-induced inflammatory pain and neutrophil recruitment in mice by targeting oxidative stress, cytokines and NF-κB. Chem Biol Interact 237:9–17
Santos MS, Duarte AI, Moreira PI, Oliveira CR (2000) Synaptosomal response to oxidative stress: effect of vinpocetine. Free Radic Res 32:57–66
Sardi SP, Cedarbaum JM, Brundin P (2018) Targeted therapies for Parkinson’s disease: from genetics to the clinic. Mov Disord 33:684–696
Sarkar S, Malovic E, Harishchandra DS, Ghaisas S, Panicker N, Charli A, Palanisamy BN, Rokad D, Jin H, Anantharam V (2017) Mitochondrial impairment in microglia amplifies NLRP3 inflammasome proinflammatory signaling in cell culture and animal models of Parkinson’s disease. npj Parkinson’s Dis 3:30
Savica R, Grossardt BR, Bower JH, Ahlskog JE, Rocca WA (2016) Time trends in the incidence of Parkinson disease. JAMA Neurol 73:981–989
Savica R, Rocca WA, Ahlskog JE (2010) When does Parkinson disease start? Arch Neurol 67:798–801
Scalzo P, Kümmer A, Bretas TL, Cardoso F, Teixeira AL (2010) Serum levels of brain-derived neurotrophic factor correlate with motor impairment in Parkinson’s disease. J Neurol 257:540–545
Sharabi Y, Vatine GD, Ashkenazi A (2021) Parkinson’s disease outside the brain: targeting the autonomic nervous system. Lancet Neurol 20:868–876
Stefanis L (2012) α-Synuclein in Parkinson’s disease. Cold Spring Harb Perspect Med 2:a009399
Swart PC, Currin CB, Russell VA, Dimatelis JJ (2017) Early ethanol exposure and vinpocetine treatment alter learning-and memory‐related proteins in the rat hippocampus and prefrontal cortex. J Neurosci Res 95:1204–1215
Szilágyi G, Nagy Z, Balkay L, Boros I, Emri M, Lehel S, Márián T, Molnár T, Szakáll S, Trón L (2005) Effects of vinpocetine on the redistribution of cerebral blood flow and glucose metabolism in chronic ischemic stroke patients: a PET study. J Neurol Sci 229:275–284
Tárnok K, Kiss E, Luiten P, Nyakas C, Tihanyi K, Schlett K, Eisel U (2008) Effects of Vinpocetine on mitochondrial function and neuroprotection in primary cortical neurons. Neurochem Int 53:289–295
Thenganatt MA, Jankovic J (2014) Parkinson disease subtypes. JAMA Neurol 71:499–504
Tiwari PC, Pal R (2022) The potential role of neuroinflammation and transcription factors in Parkinson disease. Dialogues Clin Neurosci 19:71–80
Valikovics A, Csányi A, Németh L (2012) Study of the effects of vinpocetin on cognitive functions. Ideggyogyaszati Sz 65:115–120
Wakabayashi K (2020) Where and how alpha-synuclein pathology spreads in Parkinson’s disease. Neuropathology 40:415–425
Wang C, Yang T, Liang M, Xie J, Song N (2021) Astrocyte dysfunction in Parkinson’s disease: from the perspectives of transmitted α-synuclein and genetic modulation. Transl Neurodegener 10:1–17
Wang W, Yang Y, Ying C, Li W, Ruan H, Zhu X, You Y, Han Y, Chen R, Wang Y (2007) Inhibition of glycogen synthase kinase-3β protects dopaminergic neurons from MPTP toxicity. Neuropharmacology 52:1678–1684
Wang S, Yuan Y-H, Chen N-H, Wang H-B (2019) The mechanisms of NLRP3 inflammasome/pyroptosis activation and their role in parkinson’s disease. Int Immunopharmacol 67:458–464
Wang H, Zhang K, Zhao L, Tang J, Gao L, Wei Z (2014) Anti-inflammatory effects of vinpocetine on the functional expression of nuclear factor-kappa B and tumor necrosis factor-alpha in a rat model of cerebral ischemia–reperfusion injury. Neurosci Lett 566:247–251
Wei Z, Li X, Li X, Liu Q, Cheng Y (2018) Oxidative stress in Parkinson’s disease: a systematic review and meta-analysis. Front Mol Neurosci 11:236
Wilson H, Pagano G, Niccolini F, Muhlert N, Mehta MA, Searle G, Gunn RN, Rabiner EA, Foltynie T, Politis M (2020) The role of phosphodiesterase 4 in excessive daytime sleepiness in Parkinson’s disease. Parkinsonism Relat Disord 77:163–169
Xu Y, Deng C, Zheng Y, Liu N, Fu B (2019) Applying vinpocetine to reverse synaptic ultrastructure by regulating BDNF-related PSD-95 in alleviating schizophrenia-like deficits in rat. Compr Psychiatry 94:152122
Xu H, Wang E, Chen F, Xiao J, Wang M (2021) Neuroprotective phytochemicals in experimental ischemic stroke: mechanisms and potential clinical applications. Oxid Med Cell Longev 2021:1–45
Zaitone SA, Abo-Elmatty DM, Elshazly SM (2012) Piracetam and vinpocetine ameliorate rotenone-induced parkinsonism in rats. Indian J Pharmacol 44:774
Zhang Y-s, Li J-d, Yan C (2018) An update on vinpocetine: new discoveries and clinical implications. Eur J Pharmacol 819:30–34
Zhao Y-Y, Yu J-Z, Li Q-Y, Ma C-G, Lu C-Z, Xiao B-G (2011) TSPO-specific ligand vinpocetine exerts a neuroprotective effect by suppressing microglial inflammation. Neuron Glia Biol 7:187–197
Zhou Q, Guo D, Li X, Wang Y, Ye X, Xue S, Wang X (2020) Anti-inflammatory effects of vinpocetine in LPS-stimulated microglia via activation of AMPK. An Acad Bras Cienc 92(4)
Funding
Open Access funding enabled and organized by Projekt DEAL. This work was supported by the University of Witten-Herdecke Germany.
Author information
Authors and Affiliations
Contributions
HMA-K conceptualized the manuscript, wrote, edited and reviewed the main text and approved the final edition of the manuscript. A.A., M.P., O.E., H.M.S. and GE-SB prepared the figures, wrote, corrected, amended and approved the final edition of the manuscript.
Corresponding author
Ethics declarations
Ethical approval
Not applicable.
Consent to participate
Not applicable.
Consent for publication
The authors declare no conflict of interest.
Conflict of interest
Not applicable.
Additional information
Publisher’s note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Al-kuraishy, H.M., Alexiou, A., Papadakis, M. et al. New insights on the potential effect of vinpocetine in Parkinson’s disease: one of the neglected warden and baffling topics. Metab Brain Dis 38, 1831–1840 (2023). https://doi.org/10.1007/s11011-023-01254-y
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11011-023-01254-y