Gut Microbiome as a Source of Probiotic Drugs for Parkinson’s Disease

PD is a slowly progressing chronic neurodegenerative disorder that affects 1–4% of individuals over the age of 60. It occurs in both sporadic and hereditary forms, with contributing factors including genetic mutations and environmental exposures. PD is classified into primary (idiopathic), secondary (symptomatic), and neurodegenerative PD subtypes [16,17]. A hallmark of PD is the degeneration of neurons in the substantia nigra pars compacta (SN) and the accumulation of α-synuclein–containing protein aggregates (Lewy bodies). Damage to the nigrostriatal pathway leads to dopamine depletion in the striatum, which underlies the characteristic motor symptoms of the disease, such as hypokinesia, rigidity, and resting tremor. Involvement of additional neuronal pathways contributes to cognitive and autonomic dysfunctions [18,19].

Peripheral nervous system involvement has also been reported, including α-synuclein accumulation in the enteric nervous plexuses and salivary glands, which is associated with gastrointestinal dysmotility and impaired salivation [20]. Both exogenous (environmental) and endogenous (genetic) factors are implicated in PD pathogenesis. Endogenous factors include Mendelian-inherited genetic mutations. Monogenic forms of PD are linked to six of the 28 chromosomal regions associated with the disease. However, incomplete penetrance, variable expression, and phenocopies complicate assessment of whether PD is exclusively genetic or influenced by environmental modifiers [21].

Environmental exposure, particularly to pesticides and industrial chemicals, is associated with increased PD risk. Chronic exposure to rotenone, paraquat, and solvents such as trichloroethylene and perchloroethylene in humans has been shown to promote Lewy body formation, α-synuclein misfolding, and mitochondrial dysfunction, ultimately triggering oxidative stress and apoptosis. Irreversible parkinsonism can also be induced by neurotoxins such as 6-hydroxydopamine (6-OHDA) and 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), which are metabolized into toxic compounds that accumulate in dopaminergic neurons and lead to their degeneration. Traumatic brain injury is another contributing factor, as it can damage the basal ganglia and their connections, disrupt the blood–brain barrier, and initiate prolonged neuroinflammation, mitochondrial dysfunction, excessive glutamate release, and α-synuclein aggregation in the brain. Together, these mechanisms may contribute to the development of secondary parkinsonism [17,22].

Parkinson's disease manifests through motor disturbances such as hypokinesia, muscle rigidity, resting tremor, and postural instability. The characteristic "petitioner's posture" in PD is associated with increased tone in the flexor musculature [23,24]. Disease progression involves not only the dopaminergic system but also the cholinergic, serotonergic, and noradrenergic systems of the brain. Damage to these systems contributes to the development of non-motor symptoms (NMS), which persist throughout the disease course.

NMS are classified as autonomic, sensory, sleep-related, and neuropsychiatric. Autonomic dysfunction can affect nearly all functional systems of the body. Among the most common are gastrointestinal disturbances, which often appear in the early stages of PD—sometimes even before motor symptoms. These include impaired intestinal motility, dysphagia (difficulty swallowing), and gastroparesis (delayed gastric emptying), which hinder the absorption of medications, particularly levodopa, thereby reducing therapeutic efficacy. Patients may also experience heartburn, reflux, and other digestive problems caused by altered gastric and sphincter motility [20,25].

Olfactory dysfunction (hyposmia) is another frequent early marker of PD [26]. The disease also disrupts the regulation of sleep and wakefulness, leading to insomnia, excessive daytime sleepiness, and impaired motor control during REM sleep [27]. Cognitive impairments and dementia typically emerge in later stages, manifesting as reduced attention, memory deficits, and impaired visuospatial orientation. Common psychiatric disturbances include depression, apathy, hallucinations, and impulse control disorders, the latter often induced by pharmacological therapy [28]. Some NMS may also arise directly as side effects of treatment.

Despite their key role in PD, NMS remain underdiagnosed and insufficiently studied.

Catecholamines, including dopamine, are synthesized from L-tyrosine through the action of tyrosine hydroxylase (TH), the rate-limiting enzyme in dopamine biosynthesis. In patients with PD, TH activity is significantly reduced in the nigrostriatal system, as well as in other brain regions, reflecting the systemic nature of neurodegeneration [29,30]. Dopamine metabolism generates reactive oxygen species (ROS) and quinones, which further exacerbate mitochondrial dysfunction and promote aggregation of α-synuclein—a protein central to PD pathogenesis [31,32].

Morphologically, PD is characterized by Lewy bodies—intracellular aggregates of abnormal, insoluble α-synuclein—found in both central and peripheral nervous system structures. Their widespread presence, particularly in advanced stages, confirms the progressive nature of the disease. The extent of dopaminergic cell loss correlates with Lewy body burden [33,34].

A hallmark of PD is oxidative stress, driven by mitochondrial dysfunction and ROS accumulation. Dopaminergic neurons are especially vulnerable due to their high oxygen metabolism, low antioxidant capacity, and elevated iron content. Increasing evidence highlights oxidative stress as a major driver of dopaminergic neurodegeneration across all forms of PD [35,36].

Iron plays a central role in free radical–producing oxidative reactions. Under physiological conditions, the SN is among the brain regions with the highest iron content. Abnormally elevated iron levels in the SN have been demonstrated in both genetic and idiopathic PD, linking the disease to disrupted iron metabolism [37]. With aging, glutathione levels and other antioxidant defense components decline, rendering neurons less capable of mounting stress responses [38].

Chronic neuroinflammation is another key factor in PD pathogenesis. Damaged neurons release α-synuclein, which activates astrocytes and microglia. These glial cells, in turn, produce proinflammatory cytokines, chemokines, and ROS, further amplifying tissue injury and neurodegeneration [39,40,41].

Taken together, these findings support the view of PD as a multifactorial disorder driven by diverse pathogenic processes at the cellular level. The human microbiota—particularly the gut microbiota—also contributes to PD onset and progression. Alterations in gut microbial composition may influence disease mechanisms, exacerbate inflammation, and aggravate symptoms. Moreover, the microbiota is increasingly studied as a potential source of therapeutic agents or adjuvants in PD treatment. These aspects will be discussed in the following sections of this review.

Postmortem analysis of PD-affected human brain tissue provides insights primarily into the terminal stages of the disease and is unsuitable for investigating early neurodegenerative events. Therefore, experimental model systems are essential for studying different aspects of PD. Commonly used models include rodents (rats and mice), non-human primates, and model organisms such as Caenorhabditis elegans, Drosophila melanogaster, and zebrafish. Among these, rodents are the most widely used and accessible. To reproduce disease symptoms, researchers employ both genetic models (e.g., knockout mice for genes such as α-synuclein, Parkin, UCH-L1, PINK1, DJ1, LRRK2, or overexpression of mutant human α-synuclein) and neurotoxic models [42]. Exogenous neurotoxins remain the most frequently applied approach [43].

The first PD animal model was established through intracerebral injection of 6-OHDA in rats [44]. 6-OHDA is a structural analog of catecholamines (dopamine and norepinephrine) that selectively destroys dopaminergic neurons by generating ROS. Since it cannot cross the blood–brain barrier (BBB), stereotactic surgery is required to deliver it directly into the SN [45,46]. A more widely used model involves MPTP, which readily crosses the BBB and therefore does not require surgical administration. MPTP is metabolized into the toxic compound MPP⁺, which damages dopaminergic neurons and replicates both motor and non-motor symptoms of PD [47]. MPTP administration in monkeys is considered the gold standard, though similar studies are also conducted in rodents [48].

Agricultural pesticides such as paraquat and rotenone also target the dopaminergic system. Paraquat, a nitrogen-based herbicide widely used to control broadleaf weeds, is structurally similar to MPP⁺, the toxic MPTP metabolite. Rotenone, used to eliminate invasive fish in lakes and reservoirs, is a potent dopaminergic neurotoxin with high lipophilicity that allows it to cross the BBB and enter cells. However, its application is limited by systemic toxicity. Both paraquat and rotenone disrupt mitochondrial function, increase ROS production, and lead to dopaminergic neuron loss and motor deficits [49,50,51].

Symbiotic bacteria from the human gut microbiota are widely used to alleviate symptoms and treat various human diseases [88]. A substantial number of studies have explored the potential use of these bacteria as adjuvants in PD therapy. A search in PubMed NCBI using the query "probiotics Parkinson Parkinson's" returns more than 300 publications from 2020 to April 2025. Most experimental studies have been conducted in animal models, primarily rodents. The findings of many of these studies have been summarized in reviews [89,90,91,92,93,94]. This article focuses primarily on experimental studies conducted between 2024 and April 2025, as well as earlier investigations employing alternative animal models. Regarding clinical studies on probiotic interventions in PD patients, we aimed to include all available reports. Relevant articles were identified through searches in Google Scholar and PubMed using the keywords "probiotic(s) Parkinson's (Parkinson)," "Bifidobacterium Parkinson's (Parkinson)," and "Lactobacillus Parkinson's (Parkinson)." Studies were then selected according to two criteria of interest: (i) probiotic use in animal models of PD, and (ii) probiotic interventions in clinical trials. The overarching goal was to evaluate the mechanisms of bacterial action and assess their potential for clinical application.

Table 1 provides a list and a brief summary of studies from 2024–2025 using bacterial preparations in animal models of PD. Various bacterial species were tested: Lactocaseibacillus (Lactobacillus) rhamnosus, Lactiplantibacillus (Lactobacillus) plantarum, Limosilactobacillus (Lactobacillus) fermentum, Limosilactobacillus (Lactobacillus) reuteri, Lactobacillus delbrueckii, Lactobacillus acidophilus, Ligilactobacillus (Lactobacillus) murinus, Bifidobacterium animalis subsp. lactis, B. bifidum, Bifidobacterium longum, Bifidobacterium breve, Lactococcus lactis, Escherichia coli, Streptococcus thermophilus, Bacillus subtilis, Bacillus coagulans, Clostridium butyricum, and A. muciniphila. Many of these bacteria have been well-characterized in other models (e.g., L. rhamnosus GG, L. plantarum PS128, A. muciniphila Akk11). Both individual strains and multi-component mixtures, as well as pharmaceutical formulations (e.g., VSL#3^®, a probiotic used for IBS treatment), were tested.

The biological effects of probiotic strains are generally species- and strain-specific. This is clearly demonstrated in cell culture experiments. For example, 48 bifidobacterial strains were tested on an LPS-induced BV-2 murine microglial cell line (a neuroinflammation model) for NO signaling, Nrf2/HO-1/NQO1 pathway gene expression, and cytokine production. Only one strain, B. longum subsp. longum C7, showed promising protective properties [107]. Testing many strains in animal models is more complex, but strain specificity was also observed in such models [109]. In some cases, probiotic effects were found to be species-specific rather than strain-specific [99]. Genetically engineered strains were also used in some studies [110,111]

The administered bacterial doses ranged from 10⁸ to 10¹⁰ CFU, and it was observed that higher doses yielded stronger effects [96,104]. The duration of experiments varied from 2 to 8 weeks. Prolonged administration was considered most effective [112].

Some studies combined bacterial preparations with medications or dietary supplements. L. rhamnosus increased the bioavailability of curcumin [96]. Vinpocetine (a synthetic alkaloid believed to improve cerebral circulation) showed effects similar to the bacterial preparation [97]. Liraglutide (a GLP-1R agonist that protects dopaminergic neurons by reducing inflammation) exhibited neuroprotective and anti-inflammatory effects and regulated gut microbiota dysbiosis, like L. plantarum, but did not affect intestinal transit, unlike the bacterial preparation [101]. The effects of B. longum on several markers were comparable to L-DOPA, and it outperformed L-DOPA in reducing inflammation [107]. When a bacterial mixture was co-administered with L-DOPA–benserazide, the neuroprotective effects of the bacteria did not interfere with L-DOPA therapy; in fact, the pharmacological efficacy of L-DOPA was maintained and, in some cases, improved [103]. Thus, in all studies, bacterial treatments either mirrored or enhanced the effects of conventional drugs.

In addition to variations in bacterial formulations, experimental designs also differed. Some studies used an acute model with a single high dose of a neurotoxin [95,98], while others employed a chronic model with repeated low doses [96,97,103]. Bacterial preparations were administered before the neurotoxin [101,102,105,107], after the neurotoxin [95,100,104], or simultaneously [96,97,98,103]. The experimental design most closely resembling human disease progression was employed by [100], in which 6-OHDA was injected into the SN, followed by a one-month latency period until PD symptoms emerged. Only then were bacterial therapies initiated. Animals used were generally 8–10-week-old mice, though [103] used 1-year-old mice, making the model more representative of the human disease. Most studies used male animals, with female subjects rarely included [104]. When both sexes were used, sex-specific differences in probiotic effects were observed. For instance, L. plantarum improved memory and reduced TNF-α levels in female mice, but these benefits were not seen in males [113].

All the reviewed studies clearly demonstrate the undeniable effect of bacterial preparations in alleviating PD symptoms. However, it is not possible to compare the efficacy of individual preparations due to differences across studies in all of the listed parameters.

Neurotoxins such as MPTP, paraquat, rotenone, and 6-OHDA were used as PD inducers and administered intraperitoneally, subcutaneously, or intranigrally. Neurotoxins are widely used to produce PD in animal models, triggering oxidative stress, neuronal loss, and neuroinflammation. The main signs of PD induced by these toxins are motor deficits caused by the almost complete loss of dopaminergic cells in the SN. Almost all studies conducted behavioral tests and noted that bacteria significantly improved motor deficits: motor performance and balance, movement coordination, and strength [96,97,100,101,102,103,104,105,108]. The positive effect of bacterial preparations was also noted in behavioral tests for cognitive deficits, various aspects of learning, memory, anxiety-like behaviors, and exploratory activity [103,104,107]. Almost all animal model studies of PD indicate that various bacterial preparations can positively affect dopaminergic neuron preservation and prevent neuronal damage in the SN [95,97,98,99,100,101,102,103,104,105,106,107]. An increase in brain dopamine [95,96,97,102,107] and acetylcholinesterase [96,97] levels has also been noted—two major neuromodulators regulating basal ganglia activity.

The root cause of altered dopaminergic neuron activity in PD is the agglomeration of misfolded protein aggregates known as α-synuclein in the brain and the gut. Bacterial preparations are capable of reducing the expression of the α-synuclein gene in the intestine [100], α-synuclein and tau proteins in the striatum [97] and SN [101], and the level of α-synuclein phosphorylation in the SN [108].

Neuroinflammation plays a critical role in PD progression and is mediated and facilitated by various pro-inflammatory cytokines. A growing body of evidence suggests that gut inflammation is the initiator of neuroinflammation. Neurotoxins used to model PD induce not only neuroinflammation but also gut and systemic inflammation. Bacterial preparations reduce inflammatory processes: the expression of pro-inflammatory cytokines decreases while anti-inflammatory cytokines increase in the brain [95,97,98,101,103,104,105,107]. The expression of the C-reactive protein is also reduced [104]. Glial activation decreases [98,101,105,107], and inhibition of the microglial NLRP3 inflammasome is observed [98]. Bacterial preparations restore levels of anti-inflammatory mediators GDNF and BDNF [95,107]. A reduction in inflammation due to bacterial preparations is also evidenced by changes in inflammatory markers in the brain: decreased levels of MDA [96,97,104], nitric oxide synthase [104], ROS [102], and increased antioxidant capacity via SOD, catalase, and GSH expression [96,97,104]. The anti-inflammatory effect of bacterial preparations is observed at both systemic and intestinal levels. They reduce the expression of pro-inflammatory cytokines and increase the expression of anti-inflammatory cytokines in the intestine and colon [95,98,107], the serum [95,103], and the liver [95], and inhibit the intestinal NLRP3 inflammasome [95]. Bacterial interventions improve BBB integrity [101,105,107].

The gut–brain axis plays a crucial role in the development of neurological and neurodegenerative disorders, including PD [1]. Gut-related symptoms are commonly observed in PD. Alterations in the composition of the gut microbiota and intestinal barrier permeability may contribute to the development of PD, at least in some subsets of the disease [67]. Neurotoxins used in animal models of PD, along with other physiological changes, significantly alter the composition and properties of the gut microbiota. The impact on microbiota was investigated in only five of the studies listed in Table 1. The results vary considerably. An improvement in microbiota richness and diversity was observed [101,107]. Both neurotoxin exposure alone and combined with probiotic administration led to changes in microbiota composition compared to control, but these changes did not compensate for each other. Changes induced by probiotics compared to neurotoxins at the phylum level differed between studies: a reduction in Firmicutes [101], an increased Firmicutes/Bacteroidetes ratio [102], and a reduction in Bacteroidetes [105]. At the family level, the following changes were noted: reductions in Prevotellaceae and Desulfovibrio [101]; Alloprevotella, Prevotellaceae Ga6a1 group (associated with anxiety-like behavior in rats), and Lachnospiraceae [103]; Muribaculaceae, Bacteroides, and Prevotellaceae [105]; and increases in Oscillibacter, Lactobacillus, Butyricicoccus (a butyrate producer) [102], Akkermansia, Roseburia, and Dubosiella [105]. While specific microbiota alterations varied, the overall effect was a reduction in pathogenic and pro-inflammatory taxa and the restoration of potentially beneficial bacteria.

The positive effects of bacterial preparations were also evident in the correlation between the relative abundance of specific fecal bacteria and certain traits: Bifidobacterium in feces showed a significant positive correlation with fecal levels of acetic and propionic acids; the relative abundance of the Eubacterium ruminantium group was significantly positively correlated with BDNF and GDNF expression in the striatum and TH-positive cells in the SN; and there was a negative correlation between fecal Eubacterium ruminantium group abundance and IL-6 and TNF-α expression in the striatum [107]. Analyzing bacterial metabolites may be an even more informative indicator. Bacterial intervention significantly increased the levels of beneficial bacterial metabolites. In feces of animals from the bacterial intervention group, compared to the PD group, levels of indole-3-acrylic acid, docosatrienoic acid, and indole-3-butyric acid increased, while levels of N-acetylhistamine, indole-3-acetic acid, and speridine decreased. A significant increase in SCFAs was also observed [107]. The increase in SCFAs in feces following bacterial intervention was confirmed in other studies as well [104,105].

Bacterial intervention also improves gastrointestinal motility [101,102,103,104,105], intestinal barrier integrity [102,104,107], and small intestine histology [103].

Bacterial strains such as B. animalis subsp. lactis NJ241 and L. plantarum SG5 enhance GLP-1 expression in the colon and increase serum GLP-1 levels, as well as GLP-1 receptor (GLP-1R) and PGC-1α expression in the SN of mice. GLP-1 (glucagon-like peptide-1) can promote insulin secretion, regulate gastrointestinal motility, and exert protective effects on the nervous system. The neuroprotective effects of bacterial preparations were attenuated when a GLP-1R antagonist was applied. These data indicate that the action of probiotics is at least partially mediated through the GLP-1/PGC-1α signaling pathway [101,105]. Additionally, genetically engineered bacterial strains delivering GLP-1 have also demonstrated neuroprotective effects in PD animal models [110,111].

Bacterial preparations are administered orally and primarily act on the gut microbiota, altering its composition, reducing the pathogenic component, and changing the spectrum of produced metabolites. The microbiota bacteria synthesize or facilitate the synthesis of metabolites in the host organism, such as neurotransmitters (dopamine, norepinephrine, serotonin, GABA, glutamate, and histamine), exopopolysaccharides, vitamins, antimicrobial peptides, secondary bile acids, and hydrogen sulfide [67]. Bacteria also produce SCFAs through microbial fermentation of dietary fiber in the colon, which are crucial for gastrointestinal and immune health [70]. In the studies reviewed, only some authors linked the activity of bacterial preparations to the production of specific products, specifically suggesting the synthesis of vitamins (riboflavin and folic acid) [103] and exopolysaccharides [102].

In a study of the L. fermentum U-21 strain, which exhibits anti-Parkinsonian activity [108], a 76 kDa protein was found in the cell-free supernatant and extracellular vesicles (EVs) of the strain, which was absent in the supernatant of the L. fermentum 279 strain that lacks such properties. This protein was identified as ClpL, the ATP-binding subunit of the Clp ATP-dependent protease. ClpL belongs to the HSP100 heat shock protein family and interacts with the DnaKJ/GrpE chaperone complex involved in the disaggregation of denatured proteins. In vivo in E. coli cells and in vitro, the ClpL protein demonstrated the ability to refold luciferase proteins. The cell-free culture fluid of the strain also had disaggregating activity [114]. Disaggregases are indeed being considered as potential drug candidates for the treatment of neurodegenerative diseases [115]. It is possible that the antioxidant and anti-Parkinsonian effects of the L. fermentum U-21 strain are partly due to the ClpL protein and its ability to refold protein aggregates.

The possibility of intranasal use of bacterial preparations based on commensal bacteria has also been demonstrated. Compared to the gut microbiota, bacteria of the nasal microbiota—especially those in the olfactory mucosa—are geographically closer to the brain and potentially have a tighter connection with the CNS via metabolite exchange. This offers additional advantages for the treatment of neurodegenerative diseases [116,117]. Recombinant commensal bacteria, particularly lactobacilli, can be used as intranasal drug delivery vehicles, highlighting their potential for brain-targeted therapies [118].

The nematode C. elegans is also used as a model to study the properties of functionally active bacteria [119]. Models of PD have been developed in C. elegans. In the study by Goya et al. [120], it was shown that diverse B. subtilis strains inhibit and clear human α-synuclein aggregation in transgenic C. elegans worms. The bacterium acts through metabolites and biofilm formation to activate protective host pathways, including DAF-16/FOXO and sphingolipid metabolism. In a more detailed study by Francisco and Grau [99], it was shown that B. subtilis strains used as gut commensals in C. elegans prevented the aggregation of GFP-tagged human α-synuclein in worms. To exert this effect, the strains needed to maintain biofilm formation proficiency and the QS peptide CSF. Biofilm-forming B. subtilis also protects against age-related and 6-OHDA-induced dopaminergic neurodegeneration, improves dopamine-dependent behaviors, and extends the lifespan of worms. The protection of C. elegans from 6-OHDA-induced dopaminergic neuron damage occurred not via insulin/IGF-1 signaling, as in the case of α-synuclein aggregation inhibition in the previous study, but through activation of PMK-1/SKN-1 signaling, which are major regulators of genes involved in detoxification and antioxidant defense. In the studies mentioned, the beneficial properties exhibited by Bacillus strains were not strain-specific but were shared by several strains capable of forming biofilms. It is likely that the ability to produce nitric oxide is also important for the probiotic effects of Bacillus. Previously, it was shown that the increased lifespan and stress resistance of C. elegans caused by B. subtilis were due to nitric oxide synthesized by the bacteria via NO synthase [121]. Lactobacilli are poorly suited to serve as gut commensals in C. elegans, but some strains have been found to increase the nematode's lifespan after exposure to a neurotoxin [122].

All the reviewed studies clearly demonstrate that certain bacterial strains are capable of alleviating or even completely eliminating PD symptoms induced by neurotoxins, acting similarly to pharmaceutical drugs. The application of probiotic bacterial strains in PD therapy represents a highly promising direction. However, several important limitations must be considered. Probiotics are live microorganisms and, in rare cases, may trigger pathological inflammatory processes. This restricts their use in critically ill or immunocompromised patients, as well as in individuals with vascular catheters. Since most PD patients are elderly and often present with multiple comorbidities, these safety concerns are particularly relevant. Certain strains of Lactobacillus and Bifidobacterium produce both L- and D-lactate. The latter can accumulate in the intestine and cause D-lactic acidosis. In rare instances, probiotic intake has been linked to symptoms of D-lactic acidosis, such as brain fog or somnolence. Discontinuation of probiotics, in combination with antibiotic therapy, typically resolves acidosis and alleviates neurological symptoms [123,124]. Careful strain-specific characterization of candidate probiotic preparations is therefore essential. In addition, the development of postbiotics and paraprobiotics offers an important complementary strategy. Postbiotics (also called metabiotics) are metabolic products secreted by probiotics and their complex mixtures, while paraprobiotics are inactivated microbial cells of probiotics or their cellular components [125,126]. There are some data on the use of paraprobiotics in PD models. Heat-killed L. murinus improved 6-OHDA-induced motor impairments and prevented the loss of dopaminergic neurons in the SN, while live L. murinus showed no protective effect. The heat-killed bacteria also reduced NLRP3 inflammasome activation in microglia and the secretion of proinflammatory factors, thereby inhibiting neuroinflammation [127]. Certain bacterial cell components, such as SCFAs, spermine, spermidine, indole, and exopolysaccharides have neuroprotective effects in animal models [128]. EVs are of particular interest as postbiotics.

EVs are nanosized particles released from prokaryotic and eukaryotic cells, enclosed in a lipid bilayer. The cargo of bacterial EVs includes proteins, neurotransmitters, lipids, polysaccharides, phages, DNA, RNA, and microRNAs. Bacterial EVs perform a wide range of functions: exporting misfolded proteins and peptidoglycan fragments from cells; binding and transporting cytosolic metabolites, phages, antibiotics, and bioactive peptides; and transferring DNA. EVs mediate interactions between microbiome bacteria and host cells [129]. Bacterial EVs are absorbed by intestinal epithelial cells and nerve endings, enter the bloodstream, and cross the blood–brain barrier. EVs of Gram-negative pathogenic bacteria can shuttle bacterial toxins and virulence factors throughout the body, triggering inflammatory responses. There is evidence that these EVs may contribute to PD by initiating local, systemic, and neuroinflammation [130]. EVs from probiotic bacteria possess biological activity and are being considered as potential postbiotics [131,132]. Bacterial EVs can serve as vectors for the targeted delivery of specific metabolites and proteins to target cells. There is evidence that EVs from probiotic bacteria suppress neuroinflammation, reduce neuronal damage, and influence serotonin signaling [133]. In a model of Aβ phagocytosis in BV2 microglia, EVs from B. coagulans lilac-01 and E. coli DH5α significantly increased Aβ uptake in a dose-dependent manner [134]. EVs from L. rhamnosus ATCC 7469 reduced lipopolysaccharide-induced neuroinflammation in mice [135]. Lactobacillus-derived EVs have attracted significant attention due to their diverse physiological functions [136]. Biologically active proteins and metabolites have been identified in EVs from the strain L. fermentum U-21 [108], which may account for its biological activity [137,138]. In a study by Sheikh et al., 2025 [100], it was shown for the first time that EVs from the probiotic L. acidophilus PTCC 1643 reduce movement disorders and increase serotonin (5-HT) and TH levels in the SN in a 6-OHDA rat model of PD.

EVs are considered promising therapeutic agents because, unlike live bacteria, they carry a complex of bioactive proteins and metabolites and can be used as vectors for drug delivery.

Animal models of PD have made it possible to identify bacterial strains and compositions with neuroprotective and anti-inflammatory effects, protecting animals from neurotoxins. These studies represent only the first stage in the search for probiotics aimed at alleviating PD symptoms. Due to the characteristics of PD (its long-term progression and unclear origin), there are no animal models that fully replicate the human disease.

Nevertheless, the success in identifying antiparkinsonian effects of bacterial preparations has led to their use in clinical trials. Results from these studies are summarized in Table 2.

The reviewed studies used various bacterial species: S. thermophilus, Enterococcus faecium, B. coagulans, and various Lactobacillus strains (L. rhamnosus, L. acidophilus, L. plantarum, L. paracasei, L. casei, L. delbrueckii, L. reuteri, and L. fermentum), as well as Bifidobacteria (B. breve, B. animalis, B. infantis, B. bifidum, and B. longum). It is not merely the species but the specific strain of bacteria that determines their effects on human health. In some studies, unfortunately, the strains were not specified. However, most studies did report the strain identity. Many of the strains used had already proven effective in previous studies unrelated to PD, such as L. paracasei strain Shirota [139,148], B. animalis subsp. lactis BS01, B. longum 03, B. adolescentis BA02 [152], L. plantarum PS128 [145,155], and B. animalis subsp. lactis Probio-M8 [147]. Commercial probiotic formulations were also used, such as Hexbio^® (B-Crobes Laboratory, Malaysia) [143], Symprove (Symprove Ltd.) [144], Enterolactis Duo L. paracasei DG (DSM 34154) [151], Comflor^® (Fara Daroo Fanavar Mehr Co) [150], BioZen D [153], and Livia^® (Pharma Zad, Egypt) [154]. Prebiotics such as inulin, fructooligosaccharides, and vitamins D and B-group were also used. It is worth noting that the L. paracasei (Shirota) strain was successfully tested in two studies, and L. plantarum PS128 showed positive results both in clinical trials and animal experiments. The typical duration of probiotic administration was 3 months, with high daily doses (10⁹–10¹⁰ CFU).

The conducted studies were predominantly randomized, double-blind, placebo-controlled clinical trials (RCTs). The number of participants ranged from 25 to 128, with average participant age between 56 and 76 years. All studies included both men and women. The probiotic treatments lasted between 4 and 12 weeks, most commonly 12 weeks. Probiotics were administered in the form of fermented milk, capsules, or powder sachets. In all studies, probiotics were used alongside standard medications (levodopa, dopamine agonists, and MAO-B inhibitors).

The functional bacteria were generally well tolerated by patients, with rare and mild adverse effects. For instance, Ibrahim et al. [43] reported two cases of abdominal symptoms and two of dizziness; Tan et al. [146] mentioned one case of lethargy after probiotic treatment.

All studies reported improvements in PD patients' health parameters, though the nature of these improvements varied. Regarding patient condition and behavior, general improvement in quality of life [145,149,153] prolonged ON periods, and reduced OFF periods [145] were noted.

Constipation is a predominant NMS of PD, often appearing years before motor symptoms. Its pathophysiology involves multiple factors: PD-related GI dysfunction, side effects of antiparkinsonian medications, sedentary lifestyle, reduced intestinal motility, and impaired anal sphincter function. Probiotics have proven effective in treating constipation in non-PD adult patients [156]. In PD-related probiotic studies, the following improvements were observed: improved stool frequency [140,143,146,147,148,150,151], improved whole gut transit time [145], and improved stool consistency [139,147,148,150,151]. These findings are supported by reduced laxative use [140]. However, some studies did not show statistically significant improvements in constipation symptoms [141,152].

An analysis of data from a single patient with recently diagnosed PD, who began a diet enriched with plant-based foods and dietary fiber, along with probiotic supplementation six months after diagnosis, showed a rapid disappearance of constipation symptoms. It is possible that the use of probiotics is most effective in the early stages of the disease [157].

Probiotic intake also decreases gastrointestinal problems such as bloating and abdominal pain [139,141,151,152,153]. The effects of probiotics on the gastrointestinal tract in PD patients may be multifaceted, including general improvements in well-being and possibly influencing the formation of synuclein aggregates. Furthermore, by promoting intestinal transit, probiotics may enhance the absorption of PD therapy, thereby increasing its clinical effectiveness.

Many studies have also noted improvements in other NMS. These include enhanced cognitive function [147,151,152], reductions in alexithymia and dysautonomia [151], improved sleep quality [147], and improvements in mental health parameters such as depression, anxiety, and panic disorder [147,148,149,151,153]. The effects of different probiotic strains on depression and anxiety symptoms have been studied previously [158,159].

Some studies report improvements in motor function, UPDRS-III scores, and akinesia [145,147,152]. However, other studies did not find improvements in motor symptoms with probiotic use [143,150,151].

Biochemical studies have also been conducted. Investigations among PD patients demonstrated a reduced endogenous antioxidant system [35]. In the studies reviewed, probiotic intake increased total antioxidant capacity (TAC) [149,153], reduced oxidative stress index [149], and improved markers of oxidative stress in serum—lowering levels of malondialdehyde [149,153,154] and myeloperoxidase [145]. In the study by Borzabadi et al. [142], however, no change in GSH levels was observed with probiotic intake.

Neuroinflammation is one of the key factors in PD pathogenesis, along with alpha-synuclein accumulation, synaptic dysfunction, and dopaminergic neuronal loss. Aggregated alpha-synuclein binds to Toll-like receptors and activates microglia, initiating the production and secretion of pro-inflammatory cytokines [160]. Regulating inflammatory markers may reduce central inflammation and help restore nervous system functions. Probiotic intake may reduce gene expression levels of inflammatory markers [161]. Studies have reported downregulation of pro-inflammatory cytokines (IL-1β, IL-8, IFN-γ, TNF-α) in peripheral blood mononuclear cells [142] and serum [152,153,154], as well as upregulation of the anti-inflammatory cytokine IL-10 in serum [153].

Probiotics may also affect glycemic status and insulin sensitivity. In animal studies, insulin resistance increased after probiotic use [162]. In clinical trials, probiotics reduced blood glucose levels [163]. Among the studies reviewed, only one investigated this aspect. These reported upregulation of peroxisome proliferator-activated receptor gamma in peripheral blood mononuclear cells [142]. This receptor, which acts as a transcription factor, is involved in fatty acid storage and glucose metabolism [164].

Other serum markers also changed—there was an increase in acetic acid and dopamine and a decrease in glutamine and tryptophan [147]. Yang et al. noted an increase in serum tyrosine and a decrease in fecal tyrosine [148]. Probiotics may improve impaired digestion and absorption of L-tyrosine in the upper digestive tract, increasing its level in the serum. A statistically significant increase in the butyrate/acetate ratio in fecal samples was also observed after synbiotic intake [151].

The primary action of probiotics is on the gut microbiota, and understanding how it changes in response to probiotics is essential. Unfortunately, only four of the reviewed studies examined microbiota composition. These studies reported that probiotic supplementation did not cause drastic changes in gut microbiota diversity or structure [147,148], though it did alter the microbiota composition. These changes likely occur rapidly: in an in vitro gut model using PD patient microbiota, changes in microbial composition and an increase in SCFAs and lactate production were observed within 48 h of probiotic addition [144]. The specific changes varied across studies: suppression of L. fermentum and potentially pathogenic taxa (Klebsiella) and increases in beneficial taxa (Ruminococcaceae, Lachnospira, Butyricimonas) [147]; increased Lacticaseibacillus [148]; and increases in Oscillospiraceae, particularly F. prausnitzii, a major butyrate producer, along with an increase in the butyrate/acetate ratio in fecal samples [151]. In the same in vitro model, probiotic dosing improved colonic media tight junction integrity. The probiotic itself did not directly affect tight junctions—rather, the effect was mediated by the altered microbiota and increased SCFA levels [144].

A number of studies have conducted systematic reviews and meta-analyses of existing research on the effects of probiotics in patients with PD. These analyses include various publications, and the conclusions drawn by authors are not always consistent. Overall, such studies confirm the effectiveness of probiotics in improving PD-related symptoms such as constipation [156,165,166,167,168], UPDRS-III motor scores [166,169], and depression [169]. These studies also highlight that the efficacy of probiotics appears to be greater when administered in capsule form compared to fermented milk [156,169].

Although early clinical trials investigating bacterial preparations in PD patients have yielded encouraging results, further research is essential. It should be noted that the number of available clinical studies remains limited; most involve small patient cohorts and report heterogeneous outcomes. Large-scale trials with well-defined, homogeneous patient groups are urgently needed. Early intervention and long-term administration of bacterial products may prove especially beneficial in slowing disease progression and alleviating symptoms. In particular, detailed investigation of bacterial formulations and the development of live biotherapeutic products (LBPs) based on them is necessary. This includes identifying suitable PD models, exploring novel probiotics and postbiotics—especially bacterial vesicles—and searching for early PD biomarkers [170,171,172].

Table 3 provides examples of bacterial preparations aimed at treating neurodegenerative diseases, including PD.

An important but underexplored microbial intervention for PD is fecal microbiota transplantation (FMT). FMT involves the transfer of fecal material from a healthy donor into the gastrointestinal tract of a patient via colonoscopy, gastroscopy through a nasojejunal tube, or oral capsules containing the microbiota. Unlike probiotics, FMT delivers a complex microbial community rather than a single strain. FMT has proven highly effective in treating recurrent Clostridium difficile infections [177] and is occasionally used in other conditions linked to gut dysbiosis. In rodent models of PD, FMT was shown to correct dysbiosis, reduce inflammation in the gut and brain, and alleviate disease symptoms [178,179]. To date, four randomized controlled trials have been published examining the effects of FMT in PD patients [180,181,182,183]. The study methodologies and outcomes varied, but in general, mild-to-moderate adverse events were transient and gastrointestinal in nature. Modest but statistically significant improvements were observed in gut motility/constipation, motor and NMS, and overall PD severity scores [67,184]. However, such studies are extremely difficult to standardize. Outcomes depend heavily on the microbiota profiles of both patients and donors, the method and formulation of FMT administration, and the quantity of transplanted material. Additionally, the potential risk of serious infections associated with FMT should not be underestimated.