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The intestinal microbiota as an ally in the treatment of Alzheimer’s disease

Published online by Cambridge University Press:  19 June 2023

Sabrina Sehn Hilgert
Affiliation:
Centro Universitário Barão de Mauá, Ribeirão Preto, Brazil
Daniel Penteado Martins Dias*
Affiliation:
Centro Universitário Barão de Mauá, Ribeirão Preto, Brazil
*
Corresponding author: Daniel Penteado Martins Dias; Email: danielpenteado@gmail.com

Abstract

The evolution of the understanding of the intestinal microbiota and its influence on our organism leverages it as a potential protagonist in therapies aimed at diseases that affect not only the intestine but also neural pathways and the central nervous system itself. This study, developed from a thorough systematic review, sought to demonstrate the influence of the intervention on the intestinal microbiota in subjects with Alzheimer’s disease. Clinical trials using different classes of probiotics have depicted noteworthy remission of symptoms, whose measurement was performed based on screenings and scores applied before, during, and after the period of probiotics use, allowing the observation of changes in functionality and symptomatology of patients. On the other hand, faecal microbiota transplantation requires further validation through clinical trials, even though it has already been reported in case studies as promising from the symptomatology point of view. The current compilation of studies made it possible to demonstrate the potential influence of the intestinal microbiota on Alzheimer’s pathology. However, new clinical studies with a larger number of participants are needed to obtain further clarification on pathophysiological correlations.

Type
Review
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of The Nutrition Society

Introduction

Research involving the gastrointestinal tract, and its systemic influences, have been developed for a long time. Still, in the 17th century, Antoni van Leeuwenhoek wrote about “animalcules” – bacteria – that he identified in his oral cavity with the help of his homemade microscopes, identifying differences between them and some bacteria that he observed in the faeces (Leeuwenhoek, Reference Leeuwenhoek1683). The 19th century was marked by publications that boosted the foundations of perceptions of the interaction between microorganisms and the host, mainly addressing the role of the germ in disease, and the importance of microorganisms in physiology. The publication “A flora and fauna within living animals,” detailing anatomy, reproductive cycle, and specific aspects of “entozoa,” “ectozoa,” and “entophyte” of humans, was essential to induce research aimed at what would come to be defined as the microbiota (Leidy, Reference Kim, Kim, Choi, Kim, Park, Lee, Kim, Kim, Choi, Hyun, Lee, Choi, Lee, Bae and Mook-Jung2012). Pasteur and collaborators, in 1879, described vibrios and their negative repercussions when present in wounds, supporting the “germ theory,” but also suggested that some microorganisms could be significant in human physiological processes, not only in pathologies (Pariente, Reference Pariente2019).

However, with the publication of the Henle–Koch postulates and the successful use of them to identify the relationship between a bacillus and tuberculosis (Koch, Reference Koch1882), researchers at the time began to focus on the search for causative agents of pathology, which led to the “first golden age of microbiology.” Studying the beneficial relationship between microorganisms and humans remained in the background during this period, progressing more slowly until 1916. In that year, there was a correlation between the presence of specific bacterial strains and the inhibition of Salmonella replication, already known to be related to dysentery (Nissle, Reference Nissle1916). When he successfully isolated Escherichia coli from a soldier who had not succumbed to dysentery, Nissle began to cultivate it on agar and filled gelatine capsules with the cultures patenting the creation for the pharmaceutical industry at the time (Sonneborn, Reference Sonnenborn2016). However, the first recognised use of the intestinal microbiota as a treatment method occurred in proving faecal transplantation effectiveness in treating patients with recurrent Clostridium difficile infection in 1958 (Eiseman et al., Reference Eiseman, Silen, Bascom and Kauvar1958).

Research in this line of treatment has become increasingly frequent, especially with the increased antibiotic resistance in recent decades (Sonnenborn, Reference Sonnenborn2016). The intensification of these researches, combined with new technologies, allowed the analysis of the influence of the intestinal microbiota beyond the barriers of the gastrointestinal tract, as well as the demonstration of the systemic influence on these microorganisms. Still in the 1970s, the ability of stress to alter the intestinal microbiota was demonstrated, considering it the causal factor of the observed differences (Tannock and Smith, Reference Tannock and Smith1972). In the clinical setting, the effect of stress on these microorganisms has already been demonstrated through the analysis of faecal content before and after the participation of volunteers in adverse situations with potential stressors (flight training and astronaut diet), evidencing the variation in the composition of the microbiota (Holdeman et al., Reference Holdeman, Good and Moore1976).

Although the first study to demonstrate that hormones produced in the central nervous system (CNS) are also found in the gastrointestinal tract was carried out in the 1930s (Euler and Gaddum, Reference Euler and Gaddum1931), the term brain–gut axis took several decades to emerge. One of the first studies to use the term identified negative feedback on the major release of cholecystokinin (CCK) from the increase in the plasma concentration of this hormone, with the gastrointestinal tract as a possible modulator since the substance does not cross the blood–brain barrier (Banks, Reference Banks1980). Moreover, in this way, the existence of the afferent pathway of the brain–gut axis was evidenced.

The proof of the existence of the efferent pathway occurred years later. In the year 2000, there was a flood that contaminated drinking water in a city in Canada, infecting part of the population with microorganisms, such as Campylobacter jejuni. This population was evaluated, and 8 years later, 2,451 individuals completed the reassessment, out of a total of 4,561 who became infected, and approximately half of the re-evaluated participants (1,166 individuals) were diagnosed with irritable bowel syndrome, having as independent risk factors anxiety and depression (Marshall et al., Reference Marshall, Thabane, Garg, Clark, Moayyedi and Collins2010). Another research, looking for treatment alternatives for hepatic encephalopathy, demonstrated that the oral administration of a low-spectrum antibiotic with the main action on enterobacteria could reverse hepatic encephalopathy more efficiently than the intravenous route. It was seen remission of behavioural symptoms, as well as normalisation of laboratory tests, improvement of mental status, and intellectual abnormalities in patients with decompensated liver disease (Schiano, Reference Schiano2010).

Seeking greater insight into the subject, an experimental study conducted by Neufeld et al. Reference Neufeld, Kang, Bienenstock and Foster(2011) compared brain development and behavioural expression between germ-free (GF) mice (i.e., animals that do not have contact or colonisation by normal microbiota) and rats raised in an environment free of specific pathogens (SPF; i.e., animals colonised by the normal microbiota and isolated from contact with disease-causing microorganisms). The results showed divergences, demonstrating that the SPF population showed behaviour similar to anxiety, which did not occur in GF animals. In addition, there were differences in the central expression of genes, culminating in modifications in the amygdala, hippocampus, and dentate gyrus, areas involved with behaviour and composers of the intrinsic signalling pathway of the CNS responsible for triggering feelings such as fear, anxiety, and the fight or flight response. When subjected to the SPF-rearing environment, the GF population did not present anxiety-like behaviour, only their offspring, which were reared in the same environment as the SPF. These analyses were able to demonstrate that the differences in the CNS level in the SPF rats were related to the composition of their intestinal microbiota (Neufeld et al., Reference Neufeld, Kang, Bienenstock and Foster2011). Heijtz et al. (Reference Heijtz, Wang, Anuar, Qian, Bjorkholm, Samuelsson, Hibberd, Forssberg and Pettersson2011) obtained similar results, showing that the GF animals explored the environment they were exposed to more inadvertently and extensively when compared to the SPF group, which showed greater caution in the unknown environment. A new population of GF rats was obtained and inoculated with the same microbiota as the SPF group shortly after birth, forming the group of conventionalised adults (CON). Their behaviour was similar to the SPF population after undergoing the same tests. Research indicates that GF mice showed lower activation of genes related to fear and anxiety in cortical regions such as the hippocampus, cingulate cortex, and amygdala (Heijtz et al., Reference Heijtz, Wang, Anuar, Qian, Bjorkholm, Samuelsson, Hibberd, Forssberg and Pettersson2011).

In the clinical field, a double-blind trial with 55 properly randomised participants used probiotics (BP) and placebo (PL) for 30 days, seeking to compare levels of anxiety and depression between the groups through questionnaires. After the treatment period (30 days), only the PB group showed an improvement in the psychological distress score, as well as in the self-blame score and higher score in problem-solving in addition to a decrease in the mean urinary cortisol level. The comparison was performed with results obtained in tests before the period of administration of PB or PL. The probiotics used included the genera Lactobacillus and Bifidobacterium (Messaoudi et al., Reference Messaoudi, Lalonde, Violle, Javelot, Desor, Nejdi, Bisson, Rougeot, Pichelin, Cazaubiel and Cazaubiel2011).

The identification and subsequent understanding of the neural axis responsible for this neurotransmission took place through the observation that vagotomised rats do not present behavioural or neurochemical differences after the use of probiotics, pointing out the vagus nerve as an important communication route between the intestinal microbiota and the CNS (Bravo et al., Reference Bravo, Forsythe, Chew, Escaravage, Savignac, Dinan, Bienenstock and Cryan2011). Although the vagus nerve is the main extrinsic neural pathway from the CNS to the intestine, other communication pathways have already been demonstrated. It is a bidirectional connection in which the CNS can interact with the intestine, and the intestine with the CNS (Wang and Wang, Reference Wang and Wang2016), through the vagus nerve itself, spinal nerves, other divisions of the autonomic nervous system, endocrine and immune pathways (cytokines), in addition to other pathways that are still under investigation (Margolis et al., Reference Margolis, Cryan and Mayer2021). Brain imaging has already demonstrated this reciprocal activation, in which intestinal stimuli simultaneously activate crucial brain regions involved in emotion regulation (Mayer, Reference Mayer2011).

In addition, under clinical aspects, symptoms of gastrointestinal disorders have been associated with psychological disorders and psychiatric diagnoses. More than that, significant diseases such as Parkinson’s can cause dysfunction in the gastrointestinal tract even before neurological symptoms are evident (Bove and Travagli, Reference Bove and Travagli2019). In this context, the intestinal microbiota also began to be investigated, especially after the publication of the aforementioned study on the use of oral antibiotics for the treatment of hepatic encephalopathy. Among the pathways of influence of the microbiota on the CNS, it has been shown that 90% of the body’s serotonin is produced by intestinal cells through signalling by compounds metabolised by bacteria, culminating in the activation of central nervous areas through the conduction of the stimulus by the vagus nerve afferent (Reigstad et al., Reference Reigstad, Salmonson, Rainey, Szurszewski, Linden, Sonnenburg, Farrugia and Kashyap2015; Yano et al., Reference Yano, Yu, Donaldson, Shastri, Ann, Ma, Nagler, Ismagilov, Mazmanian and Hsiao2015). The intestinal microbiota is also responsible for helping to maintain the intestinal mucus layer, so changes in the microbiota induced by inadequate diet cause compromise of the mucus layer, allowing access to pathogens to dendritic cells. Due to this exposure, immune mediators are released into the systemic circulation, which can cause immune activation in different locations, including the CNS (André et al., Reference André, Laugerette and Féart2019). This activation correlates with neurodegenerative disease pathophysiology (Margolis et al., Reference Margolis, Cryan and Mayer2021).

With this in mind, researchers have developed experimental designs involving transgenic animals with Alzheimer’s disease (AD), seeking to improve symptoms from changes in the intestinal microbiota through probiotics and faecal microbiota transplantation (FMT). The results indicate that probiotic supplementation in mice decreased β-amyloid plaques in the hippocampus, when combined to exercises (Abraham et al., Reference Abraham, Feher, Scuderi, Szabo, Dobolyi, Cservenak, Juhasz, Ligeti, Pongor, Gomez-Cabrera, Vina, Higuchi, Suzuki, Boldogh and Radak2019). In addition, probiotic treated mice show reduced inflammation and permeability of the intestinal wall, as well as a tendency to normalise inflammatory modulators in the systemic circulation, although central-level effects on the reduction of β-amyloid plaques, cytokine levels and gliosis were absent (Kaur et al., Reference Kaur, Nagamoto-Combs, Golovko, Golovko, Klug and Combs2020). FMT also affects these animals since the transplantation of microbiota from healthy animals to models with Alzheimer’s caused a decrease in the number of central B-amyloid plaques, improvement in cognition, and reversal of abnormalities in the expression of genes that modulate the activity of macrophages (Kim et al., Reference Kim, Kim, Choi, Kim, Park, Lee, Kim, Kim, Choi, Hyun, Lee, Choi, Lee, Bae and Mook-Jung2020; Dodiya, Reference Dodiya, Lutz, Weigle, Patel, Michalkiewicz, Roman-Santiago, Zhang, Liang, Srinath, Zhang, Xia, Olszewski, Zhang, Schipma, Chang, Tanzi, Gilbert and Sisodia2021). Furthermore, the Federal Drug Administration (FDA) recently approved the rectal administration of a probiotic suspension to prevent recurrent C. difficile infection. The technique is also more cost-effective when compared to traditional treatment (i.e., prolonged use of antibiotics, without subsequent administration of the probiotic suspension; Lodise et al., Reference Lodise, Guo, Yang, Cook, Song, Yang, Wang, Zhao and Bochan2023; Walter and Shanahan, Reference Walter and Shanahan2023).

Due to the beneficial effects of healthy microbiota on the brain–gut axis and its repercussion on AD symptoms, already demonstrated in extensive literature with animal models, intestinal microbiota emerges as a potential ally in treating AD patients.

Objectives

The objective of the present study was to search the literature for correlations between alterations caused in the intestinal microbiota of patients with AD and the consequent change in the clinical profile of patients through the superposition of data obtained in a systematic literature review.

Specific Objectives

Identify in the literature and overlap the results of recent clinical studies that test the efficacy of the use of probiotics and FMT in patients with Alzheimer’s.

Describe the data found in order to objectively expose the results obtained from each study using probiotics or FMT.

Correlate the results found with pathophysiological hypotheses that seek to explain the results obtained in the studies described to prove or rule out the effectiveness of the use of probiotics or FMT in patients with AD.

Methods

A systematic literature review was conducted using the PubMed (https://pubmed.ncbi.nlm.nih.gov) and CAPES journals (https://www-periodicos-capes-gov-br.ezl.periodicos.capes.gov.br) databases. The search keywords were: microbiota, Alzheimer’s, gut–brain, microbiota–gut–brain, probiotics, FMT, and microbiome. The results were restricted between 2015 and 2022 since clinical trials involving patients with Alzheimer’s and intervention on intestinal microbiota were not carried out before that period, only using an animal model. The filters “articles” and “peer-reviewed journals” were also used. In all, 7,050 articles were found. Of these, 471 articles were selected after reading the titles and abstracts, as they fit the theme focused on intervention in the intestinal microbiota in patients with AD. These articles were then submitted to the following inclusion and exclusion criteria based on their methodology: the articles should be empirical studies, excluding reviews and study protocols; studies should be clinical trials or case reports, excluding studies performed in animal models; duplicates were excluded. Through these criteria, 18 articles were selected. A careful reading of the 18 articles was carried out is considered suitable for this systematic review those in which there was an adequate description of the intervention in the intestinal microbiota through the use of probiotics or transplantation of faecal microbiota in patients with AD, having as an evaluation method of the variation of the patient’s symptomatology objective questionnaires approved for this purpose. Finally, five articles met these requirements and were described in this systematic review.

Results and discussion

In the clinical trial developed by Leblhuber et al. (Reference Leblhuber, Steiner, Schuetz, Fuchs and Gostner2018), 20 AD patients were subjected to the mini-mental state examination (MMSE) and the Clock Drawing Test (CDT), before and after intervention with probiotics. For 28 days, patients regularly used probiotics containing Lactobacillus sp., Lactococcus lactis, and Bifidobacterium sp. After treatment ceased, no changes were observed in the MMSE and CDT scores. It was concluded that, despite increased serum levels of inflammatory markers, no substantial changes were seen on the patients’ cognitive levels, possibly due to the short duration and small sample investigated.

Subsequently, Hazan (Reference Hazan2020) clarified the case of an 82-year-old man with AD and recurrent C. difficile infection. The patient was evaluated through the MMSE before and after the FMT procedure using the Borody method. After 8 weeks, there was an increase in the MMSE score of +6 points. In addition, the wife also reported improvement in mental acuity and mood. After 16 weeks, there was an improvement in memory capacity and no negative progression of Alzheimer’s symptoms. Finally, after 24 weeks, the MMSE score increased by +9 from baseline; improvements in mood, social interaction, and affection were also observed. In the final considerations, the author explained that due to the potential role of the intestinal microbiome in the pathogenesis of Alzheimer’s, microbiome modulation represents a promising treatment route.

More recently, Park et al. (Reference Park, Lee, Shin, Kim, Cha, Lee, Kwon, Shin and Choi2021) followed a 90-year-old woman with AD, systemic arterial hypertension (SAH), type II diabetes mellitus (DMII), chronic kidney disease (CKD), and recurrent C. difficile infection, who required perform FMT for the treatment of reinfections. Before the procedure, she was assessed using the MMSE, Montreal Cognitive Assessment (MoCA), and Clinical Assessment of Dementia (ACD). After 4 weeks of FMT, she showed an increase of +3 in MMSE (baseline 15), +1 in MoCA (baseline 11), and +0 in ACD (baseline 1). After 12 weeks, the scores changed again from baseline: MMSE +5, MoCA +5, and ACD -0.5. It is concluded that the case offers evidence of the benefits of FMT in Alzheimer’s patients. It also suggests an association between the gut microbiome and cognitive function.

In a recent clinical trial conducted by Akhgarjand et al. (Reference Akhgarjand, Vahabi, Shab-Bidar, Etesam and Djafarian2022), 90 patients with AD were sorted out into three groups using age and sex criteria. Firstly, all individuals were subjected to the MMSE for illiterate patients, to the categorical test of verbal fluency (CFT) and to the evaluation of the performance of daily activities through the Barthel Index (BI). Over the next 12 weeks, one group received Bifidobacterium longum, another received Lactobacillus rhamnosus HA-114, and the last group received placebo. Following the intervention period, MMSE was found higher in both Bifidobacterium and Lactobacillus groups, when compared to baseline. No changes were observed in MMSE of placebo group, as compared to baseline. CFT was found higher in both intervention groups, Bifidobacterium and Lactobacillus, when compared to baseline and compared to placebo. Finally, BI was found similar following 12 weeks of treatment in both B. longum and L. rhamnosus groups. All parameters assessed remained unchanged in placebo groups following the 12-week period. Authors concluded that the use of probiotics, as an adjuvant, has benefits on disease progression and quality of life of patients with AD.

Although most studies assessing the effects of probiotics therapy in AD patients have short-duration protocols and involve small groups of individuals, some hypotheses may be raised. Seeking to correlate the data presented, we must remember that AD is a neurodegenerative pathology that has shown an increase in prevalence in recent years (Doifode et al., Reference Doifode, Giridharan, Generoso, Bhatti, Collodel, Schulz, Forlenza and Barichello2021). It mainly affects the elderly over 65, ranking first among the causes of dementia (Alzheimer’s Association, 2019). It begins its symptoms insidiously, first affecting learning and memory, progressing to deficits in attention, language, and social behaviour. After the first symptoms, the carrier usually clinically involutes for approximately 5 to 12 years, when, inevitably, he dies (Long and Holtzman, Reference Long and Holtzman2019). In addition to the direct impact on the patient’s quality of life, family members and caregivers are emotionally and financially affected as the patient develops irreversible dependence (Doifode et al., Reference Doifode, Giridharan, Generoso, Bhatti, Collodel, Schulz, Forlenza and Barichello2021). The main responsible for all these described conditions is the β-amyloid peptide (PβA), which, when deposited in the extracellular epithelial tissue of the brain, aggregates and gives rise to amyloid neuritic plaques. It then affects synaptic activity and local capillary blood flow as it binds to oligomers and fibrils, preventing them from acting normally in these functions (Long and Holtzman, Reference Long and Holtzman2019). However, ironically, there have been recent reports that PβA is produced on demand from signals from the immune system, acting as a defence, precisely because it performs extracellular aggregation (Wang et al., Reference Wang, Kulas, Wang, Holtzman, Ferris and Hansen2021). In addition to PβA, the increase in tau protein phosphorylation, involved in the regulation of axonal transport and stabilisation of neuronal microtubules, also contributes to the progression of the disease. Hyperphosphorylation leads to changes that culminate in the formation of neurofibrillary tangles, making synapses even more complex and making axonal transport insufficient (John and Reddy, Reference John and Reddy2021). From the deposition of PβA, there is an induction of oxidative stress, which increases the phosphorylation of the tau protein (Belkouch et al., Reference Belkouch, Hachem, Elgot, Lo Van, Picq, Guichardant, Lagarde and Bernoud-Hubac2016).

Regarding PβA aggregation, it was shown that the greater the production of different types of β-amyloid protein, the more intensely and earlier the aggregation occurs. Physiologically, the human organism can produce around 30 different types of amyloidogenic proteins. However, depending on its composition, the intestinal microbiome can contribute to the production of more subtypes, increasing aggregation (Sampson et al., Reference Sampson, Challis, Jain, Moiseyenko, Ladinsky, Shastri and Mazmanian2020). In addition, the use of antibiotic cocktails in transgenic mice and rats carrying “APP SWE” and “PS1 L166P” – family genes linked to Alzheimer’s – caused less progression of amyloid plaques in male brains when compared to the group that did not receive the cocktail, in addition to reduced neuroinflammatory activity, mediated by microglia. The change in the microbiome also led to an increase in anti-inflammatory substances in the plasma and a decrease in pro-inflammatory cytokines (Minter et al., Reference Minter, Zhang, Leone, Ringus, Zhang, Oyler-Castrillo, Musch, Liao, Ward, Holtzman, Chang, Tanzi and Sisodia2016; Dodiya et al., Reference Dodiya, Kuntz, Shaik, Baufeld, Leibowitz, Zhang and Sisodia2019). There was also a difference in the gene expression induced by the microbiota between the group treated with antibiotics and the untreated group. When performing FMT from the untreated group to the treated group, partial restoration of the pathology by PβA deposition was described (Dodiya et al., Reference Dodiya, Kuntz, Shaik, Baufeld, Leibowitz, Zhang and Sisodia2019). Probiotics also can alter the inflammatory response, as observed by Leblhuber et al. (Reference Leblhuber, Steiner, Schuetz, Fuchs and Gostner2018). The researchers observed an increase in serum inflammatory markers, probably due to the activation of macrophages, questioning whether this modulation could delay or accelerate neurodeterioration in patients with AD, depending on the level of immune response triggered (Leblhuber et al., Reference Leblhuber, Steiner, Schuetz, Fuchs and Gostner2018). Harach et al. (Reference Harach, Marungruang, Duthilleul, Cheatham, Mc Coy, Frisoni, Neher, Fåk, Jucker, Lasser and Bolmont2017) also evidenced differences in central PβA deposition when comparing GF and conventional mice, both transgenic for the mutations linked to Alzheimer’s. In addition to reduced plaque in the GF mice, decreased cortical inflammation and increased enzymes that degrade PβA were also demonstrated. However, in the long term, the use of antibiotics causes changes in the morphology and reactivity of microglia, primarily responsible for physiological neuroinflammatory responses in the CNS and a decrease in astrocyte reactivity, which also contribute to the neuroinflammatory response (Minter et al., Reference Minter, Zhang, Leone, Ringus, Zhang, Oyler-Castrillo, Musch, Liao, Ward, Holtzman, Chang, Tanzi and Sisodia2016). It has already been shown that the intestinal microbiota is responsible for the constant physiological modulation and maturation of microglia in the CNS (Erny et al., Reference Erny, Hrabě de Angelis, Jaitin, Wieghofer, Staszewski, David, Keren-Shaul, Mahlakoiv, Jakobshagen, Buch, Schwierzeck, Utermöhlen, Chun, Garrett, KD, Diefenbach, Staeheli, Stecher, Amit and Prinz2015).

Conclusion

Changes in the intestinal microbiota from probiotics and FMT are shown to be effective in improving the symptoms of AD when used as an adjunct to the treatment of already established drugs, usually when medications do not achieve sufficient symptom control. However, FMT still requires clinical trials with larger samples to demonstrate the safety of the procedure in patients with AD since the few case reports in patients with recurrent infection by associated C. difficile are insufficient to establish efficacy and safety to apply the therapy in AD patients widely.

Data availability statement

Data used and presented for the preparation of the systematic analysis are available on the drive at https://drive.google.com/drive/folders/1NvCLbyfqpHtQwjUxhpOUxlhtZm5-inZn?usp=sharing.

Acknowledgements

I would like to thank my colleagues Ana Karen de Medeiros and Celso Aurélio Emídio Lopes for their collaboration during the bibliographic data collection process and conceptualisation of this review.

Author contribution

Conceptualisation: S.S.H., D.P.M.D.; Data curation: S.S.H., D.P.M.D.; Investigation: S.S.H.; Methodology: S.S.H.; Project administration: S.S.H., D.P.M.D.; Supervision: D.P.M.D.; Writing – original draft: S.S.H.; Writing – review and editing: S.S.H., D.P.M.D.

Competing interest

The authors declare no competing interests exist.

Funding

This research received no specific grant from any funding agency, commercial or not-for-profit sectors.

References

Abraham, D, Feher, J, Scuderi, GL, Szabo, D, Dobolyi, A, Cservenak, M, Juhasz, J, Ligeti, B, Pongor, S, Gomez-Cabrera, MC, Vina, J, Higuchi, M, Suzuki, K, Boldogh, I and Radak, Z (2019) Exercise and probiotics attenuate the development of Alzheimer’s disease in transgenic mice: Role of microbiome. Experimental Gerontology 115, 122131. https://doi.org/10.1016/j.exger.2018.12.005CrossRefGoogle ScholarPubMed
Akhgarjand, C, Vahabi, Z, Shab-Bidar, S, Etesam, F and Djafarian, K (2022) Effects of probiotic supplements on cognition, anxiety, and physical activity in subjects with mild and moderate Alzheimer’s disease: A randomized, double-blind, and placebo-controlled study. Frontiers in Aging Neuroscience 14, 1032494. https://doi.org/10.3389/fnagi.2022.1032494CrossRefGoogle ScholarPubMed
Alzheimer’s Association (2019) Alzheimer’s disease facts and figures. Alzheimer’s & Dementia 15(3), 321387. https://doi.org/10.1016/j.jalz.2019.01.010Google Scholar
André, L, Laugerette, F and Féart, C (2019) Metabolic endotoxemia: A potential underlying mechanism of the relationship between dietary fat intake and risk for cognitive impairments in humans? Nutrients 11(8), 1887. https://doi.org/10.3390/nu11081887CrossRefGoogle ScholarPubMed
Banks, WA (1980) Evidence for a cholecystokinin gut-brain axis with modulation by bombesin. Peptides 1(4), 347351. https://doi.org/10.1016/0196-9781(80)90013-3CrossRefGoogle ScholarPubMed
Belkouch, M, Hachem, M, Elgot, A, Lo Van, A, Picq, M, Guichardant, M, Lagarde, M and Bernoud-Hubac, N (2016) The pleiotropic effects of omega-3 docosahexaenoic acid on the hallmarks of Alzheimer’s disease. Journal of Nutritional Biochemistry 38, 111. https://doi.org/10.1016/j.jnutbio.2016.03.002CrossRefGoogle ScholarPubMed
Bove, C and Travagli, RA (2019) Neurophysiology of the brain stem in Parkinson’s disease. Journal of Neurophysiology 121(5), 18561864. https://doi.org/10.1152/jn.00056.2019CrossRefGoogle ScholarPubMed
Bravo, JA, Forsythe, P, Chew, MV, Escaravage, E, Savignac, HM, Dinan, TG, Bienenstock, J and Cryan, JF (2011) Ingestion of lactobacillus strain regulates emotional behavior and central GABA receptor expression in a mouse via the vagus nerve. Proceedings of the National Academy of Sciences 108(38), 1605016055. https://doi.org/10.1073/pnas.1102999108CrossRefGoogle Scholar
Dodiya, HB, Kuntz, T, Shaik, SM, Baufeld, C, Leibowitz, J, Zhang, X and Sisodia, SS (2019) Sex-specific effects of microbiome perturbations on cerebral Aβ amyloidosis and microglia phenotypes. Journal of Experimental Medicine 216(7), 15421560. https://doi.org/10.1084/jem.20182386CrossRefGoogle ScholarPubMed
Dodiya, HB, Lutz, HL, Weigle, IQ, Patel, P, Michalkiewicz, J, Roman-Santiago, CJ, Zhang, CM, Liang, Y, Srinath, A, Zhang, X, Xia, J, Olszewski, M, Zhang, X, Schipma, MJ, Chang, EB, Tanzi, RE, Gilbert, JA and Sisodia, SS (2021) Gut microbiota–driven brain Aβ amyloidosis in mice requires microglia. Journal of Experimental Medicine 219(1), e20200895.CrossRefGoogle ScholarPubMed
Doifode, T, Giridharan, VV, Generoso, JS, Bhatti, G, Collodel, A, Schulz, PE, Forlenza, OV and Barichello, T (2021) The impact of the microbiota-gut-brain axis on Alzheimer’s disease pathophysiology. Pharmacological Research 164, 105314.CrossRefGoogle ScholarPubMed
Eiseman, B, Silen, W, Bascom, GS and Kauvar, AJ (1958) Fecal enema as an adjunct in the treatment of pseudomembranous enterocolitis. Surgery 44(5), 854859.Google ScholarPubMed
Erny, D, Hrabě de Angelis, AL, Jaitin, D, Wieghofer, P, Staszewski, O, David, E, Keren-Shaul, H, Mahlakoiv, T, Jakobshagen, K, Buch, T, Schwierzeck, V, Utermöhlen, O, Chun, E, Garrett, WS, KD, McCoy, Diefenbach, A, Staeheli, P, Stecher, B, Amit, I and Prinz, M (2015) Host microbiota constantly control maturation and function of microglia in the CNS. Nature Neuroscience 18(7), 965977.CrossRefGoogle ScholarPubMed
Euler, USV and Gaddum, JH (1931) An unidentified depressor substance in certain tissue extracts. Journal of Physiology 72(1), 7487. https://doi.org/10.1113/jphysiol.1931.sp002763CrossRefGoogle Scholar
Harach, T, Marungruang, N, Duthilleul, N, Cheatham, V, Mc Coy, KD, Frisoni, G, Neher, JJ, Fåk, F, Jucker, M, Lasser, T and Bolmont, T (2017) Reduction of Abeta amyloid pathology in APPPS1 transgenic mice in the absence of gut microbiota. Scientific Reports 7(1), 41802.CrossRefGoogle ScholarPubMed
Hazan, S (2020) Rapid improvement in Alzheimer’s disease symptoms following fecal microbiota transplantation: A case report. Journal of International Medical Research 48(6), 300060520925930. https://doi.org/10.1177/0300060520925930CrossRefGoogle ScholarPubMed
Heijtz, RD, Wang, S, Anuar, F, Qian, Y, Bjorkholm, B, Samuelsson, A, Hibberd, ML, Forssberg, H and Pettersson, S (2011) Normal gut microbiota modulates brain development and behavior. Proceedings of the National Academy of Sciences 108(7), 30473052. https://doi.org/10.1073/pnas.1010529108CrossRefGoogle Scholar
Holdeman, LV, Good, IJ and Moore, WE (1976) Human fecal flora: Variation in bacterial composition within individuals and a possible effect of emotional stress. Applied and Environmental Microbiology 31(3), 359375. https://doi.org/10.1128/aem.31.3.359-375.1976CrossRefGoogle Scholar
John, A and Reddy, PH (2021) Synaptic basis of Alzheimer’s disease: Focus on synaptic amyloid beta, P-tau and mitochondria. Ageing Research Reviews 65, 101208. https://doi.org/10.1016/j.arr.2020.101208CrossRefGoogle ScholarPubMed
Kaur, H, Nagamoto-Combs, K, Golovko, S, Golovko, MY, Klug, MG and Combs, CK (2020) Probiotics ameliorate intestinal pathophysiology in a mouse model of Alzheimer’s disease. Neurobiology of Aging 92, 114134. https://doi.org/10.1016/j.neurobiolaging.2020.04.009CrossRefGoogle Scholar
Kim, M-S, Kim, Y, Choi, H, Kim, W, Park, S, Lee, D, Kim, DK, Kim, HJ, Choi, H, Hyun, DW, Lee, JY, Choi, EY, Lee, D-S, Bae, J-W and Mook-Jung, I (2020) Transfer of a healthy microbiota reduces amyloid and tau pathology in an Alzheimer’s disease animal model. Gut 69(2), 283294.CrossRefGoogle Scholar
Koch, R (1882) Die Aetiologie der Tuberculose. Berliner Klinischen Wochenschrift, v. 15, p. 221230. Available at https://babel.hathitrust.org/cgi/pt?id=mdp.39015020075001&view=1up&seq=235. Accessed June 2023.Google Scholar
Leblhuber, F, Steiner, K, Schuetz, B, Fuchs, D and Gostner, JM (2018) Probiotic supplementation in patients with Alzheimer’s dementia - An explorative intervention study. Current Alzheimer Research 15(12), 11061113. https://doi.org/10.2174/1389200219666180813144834CrossRefGoogle ScholarPubMed
Leeuwenhoek, A (1683) Letter Nº 39. The Collected Letters of Antoni van Leeuwenhoek. Available at https://lensonleeuwenhoek.net/content/wrote-letter-39-1683-09-17-ab-76-francis-aston. Accessed May 2021.Google Scholar
Leidy, J (2012) “A flora and fauna within living animals” (excerpt), Smithsonian Contributions to Knowledge (1853). In CR Resetarits (ed.), An Anthology of Nineteenth-Century American Science Writing. Cambridge: Cambridge University Press, pp. 98108. https://doi.org/10.7135/upo9780857286512.020CrossRefGoogle Scholar
Lodise, T, Guo, A, Yang, M, Cook, EE, Song, W, Yang, D, Wang, Q, Zhao, A and Bochan, M (2023) Cost-effectiveness analysis of REBYOTATM (fecal microbiota, live-jslm [FMBL]) versus standard of care for the prevention of recurrent Clostridioides difficile infection in the USA. Advances in Therapy 40(6), 27842800. https://doi.org/10.1007/s12325-023-02505-1CrossRefGoogle Scholar
Long, JM and Holtzman, DM (2019) Alzheimer disease: An update on pathobiology and treatment strategies. Cell 179(2), 312339. https://doi.org/10.1016/j.cell.2019.09.001CrossRefGoogle ScholarPubMed
Margolis, KG, Cryan, JF and Mayer, EA (2021) The microbiota-gut-brain axis: From motility to mood. Gastroenterology 160, 14861501. https://doi.org/10.1053/j.gastro.2020.10.066CrossRefGoogle ScholarPubMed
Marshall, JK, Thabane, M, Garg, AX, Clark, WF, Moayyedi, P, Collins, SM and Walkerton Health Study Investigators (2010) Eight year prognosis of postinfectious irritable bowel syndrome following waterborne bacterial dysentery. Gut 59(5), 605611. https://doi.org/10.1136/gut.2009.202234CrossRefGoogle ScholarPubMed
Mayer, EA (2011) Gut feelings: The emerging biology of gut–brain communication. Nature Reviews Neuroscience 12(8), 453466. https://doi.org/10.1038/nrn3071CrossRefGoogle ScholarPubMed
Messaoudi, M, Lalonde, R, Violle, N, Javelot, H, Desor, D, Nejdi, A, Bisson, J-F, Rougeot, C, Pichelin, M, Cazaubiel, M and Cazaubiel, J-M (2011) Assessment of psychotropic-like properties of a probiotic formulation (lactobacillus helveticus R0052 and Bifidobacterium longum R0175) in rats and human subjects. British Journal of Nutrition 105(5), 755764. https://doi.org/10.1017/s0007114510004319CrossRefGoogle ScholarPubMed
Minter, MR, Zhang, C, Leone, V, Ringus, DL, Zhang, X, Oyler-Castrillo, P, Musch, MW, Liao, F, Ward, JF, Holtzman, DM, Chang, EB, Tanzi, RE and Sisodia, SS (2016) Antibiotic-induced perturbations in gut microbial diversity influences neuro-inflammation and amyloidosis in a murine model of Alzheimer’s disease. Scientific Reports 6(1), 30028. https://doi.org/10.1038/srep30028CrossRefGoogle Scholar
Neufeld, KM, Kang, N, Bienenstock, J and Foster, JA (2011) Reduced anxiety-like behavior and central neurochemical change in germ-free mice. Neurogastroenterology & Motility 23(3), 255e119. https://doi.org/10.1111/j.1365-2982.2010.01620.xCrossRefGoogle ScholarPubMed
Nissle, A (1916) Üeber die Grundlagen einer neuen ursächlichen Bekämpfung der pathologischen Darmflora. Deutsche Medizinische Wochenschrift 42, 11811184.Google Scholar
Pariente, N (2019) A field is born. Nature Milestones, S3S4.Google Scholar
Park, S-H, Lee, JH, Shin, J, Kim, J-S, Cha, B, Lee, S, Kwon, KS, Shin, YW and Choi, SH (2021) Cognitive function improvement after fecal microbiota transplantation in Alzheimer’s dementia patient: A case report. Current Medical Research and Opinion 37(10), 17391744. https://doi.org/10.1080/03007995.2021.1957807CrossRefGoogle ScholarPubMed
Reigstad, CS, Salmonson, CE, Rainey, JF, Szurszewski, JH, Linden, DR, Sonnenburg, JL, Farrugia, G and Kashyap, PC (2015) Gut microbes promote colonic serotonin production through an effect of short-chain fatty acids on enterochromaffin cells. FASEB Journal 29(4), 13951403.CrossRefGoogle ScholarPubMed
Sampson, TR, Challis, C, Jain, N, Moiseyenko, A, Ladinsky, MS, Shastri, GG and Mazmanian, SK (2020) A gut bacterial amyloid promotes α-synuclein aggregation and motor impairment in mice. eLife 9, 53111. https://doi.org/10.7554/elife.53111CrossRefGoogle ScholarPubMed
Schiano, TD (2010) Treatment options for hepatic encephalopathy. Pharmacotherapy 30(5), 16S21S. https://doi.org/10.1592/phco.30.pt2.16sCrossRefGoogle ScholarPubMed
Sonnenborn, U (2016) Escherichia colistrain Nissle 1917—From bench to bedside and back: History of a specialEscherichia colistrain with probiotic properties. FEMS Microbiology Letters 363(19), fnw212. https://doi.org/10.1093/femsle/fnw212CrossRefGoogle Scholar
Tannock, GW and Smith, JMB (1972) The effect of food and water deprivation (stress) on salmonella-carrier mice. Journal of Medical Microbiology 5(3), 283289. https://doi.org/10.1099/00222615-5-3-283CrossRefGoogle ScholarPubMed
Walter, J and Shanahan, F (2023) Fecal microbiota-based treatment for recurrent Clostridioides difficile infection. Cell 186(6), 1087. https://doi.org/10.1016/j.cell.2023.02.034CrossRefGoogle ScholarPubMed
Wang, H, Kulas, JA, Wang, C, Holtzman, DM, Ferris, HA and Hansen, SB (2021) Regulation of beta-amyloid production in neurons by astrocyte-derived cholesterol. Proceedings of the National Academy of Sciences 118(33), e2102191118. https://doi.org/10.1073/pnas.2102191118CrossRefGoogle ScholarPubMed
Wang, H-X and Wang, Y-P (2016) Gut microbiota-brain axis. Chinese Medical Journal 129(19), 23732380. https://doi.org/10.4103/0366-6999.190667CrossRefGoogle ScholarPubMed
Yano, JM, Yu, K, Donaldson, GP, Shastri, GG, Ann, P, Ma, L, Nagler, CR, Ismagilov, RF, Mazmanian, SK and Hsiao, EY (2015) Indigenous bacteria from the gut microbiota regulate host serotonin biosynthesis. Cell 161(2), 264276. https://doi.org/10.1016/j.cell.2015.02.047CrossRefGoogle ScholarPubMed