Barrier Repair in ME/CFS: Lessons from Prototype Diseases

1. Introduction

Dr. Anouk W. Vaes and collaborators at CIRO performed one of the largest systematic surveys of ME/CFS symptom patterns, applying clustering methods to patient-reported outcomes to identify recurring constellations of symptoms ¹. The study demonstrated that ME/CFS can be partitioned into multiple reproducible subgroups, each with distinct symptom burdens and emphases. While this clustering approach highlighted the extent of heterogeneity in ME/CFS, it also left unresolved why certain symptoms consistently co-occur and what biological processes might underlie those patterns.

We analyzed symptom severity patterns and, like many before us, found that symptoms were strongly correlated. Several stood out as plausibly gut-related, prompting us to ask whether symptoms could localize patient clusters to a specific gut region but they were unable to. Instead, these symptoms tracked closely with overall post-exertional malaise (PEM) severity. This suggested a broader gut barrier problem rather than a localized one. We therefore turned to prototype diseases with established barrier dysfunction, asking whether they could help clarify how barrier breakdown itself contributes to illness — in other words, to distinguish root disease mechanisms from the direct consequences of barrier breach.

2. Paracellular Pathways

To explain our findings, we first review paracellular pathways. Two major types are recognized in the gut epithelium: claudin pores and the leak pathway^2,3.

2.1. Characteristics

Each pathway can be characterized by:

• Size range of molecules transported
• Charge selectivity (cations, anions, or both)
• Potential for activation independent of overt inflammation
• Mechanisms of closure or deactivation

In normal physiology, claudin pores provide regulated passage of small, charged molecules, while the leak pathway accommodates larger, less selective solutes during epithelial turnover. When dysregulated, these same routes can become conduits for gut-derived metabolites.

• Anion-selective pores favor small, negatively charged solutes such as lactate and organic acids.
• Cation-selective pores favor small, positively charged solutes such as histamine and polyamines.
• Leak pathway is less selective, admitting medium- to large-sized molecules during periods of inflammation or cytoskeletal stress⁴.

Unlike claudin pores, leak pathways do not create high-flux channels for ions. Their permeability is passive and limited to existing gradients, so they allow entry of ions and small solutes, but less efficiently than pore pathways.

Chronic dysbiosis may alter not only pore signaling but also pore distribution. Over time, the number and type of pores in each gut segment can shift, and clinical improvement may require months of epithelial remodeling before a stable, healthy population of channels is restored.

Table 1. Summary of Gut Paracellular Pathways.

Pathway	Size Range	Activation	Closure/Deactivation
Leak	Up to a few kDa	Inflammatory / cytoskeletal stress	Requires resolution of inflammation / cytoskeletal reset
Anion Pore	Small molecules (< 6–8 Å)	Claudin isoform–specific signals	Rapid closure via tight junction proteins
Cation Pore	Small molecules (< 6–8 Å)	Claudin isoform–specific signals	Rapid closure via tight junction proteins

Table 1. Summary of Gut Paracellular Pathways.

Pathway	Size Range	Activation	Closure/Deactivation
Leak	Up to a few kDa	Inflammatory / cytoskeletal stress	Requires resolution of inflammation / cytoskeletal reset
Anion Pore	Small molecules (< 6–8 Å)	Claudin isoform–specific signals	Rapid closure via tight junction proteins
Cation Pore	Small molecules (< 6–8 Å)	Claudin isoform–specific signals	Rapid closure via tight junction proteins

These pathways are not mutually exclusive—simultaneous opening of leak and pore routes provides an explanation for the partial effects of interventions that address only one pathway² as well as symptom complexity.

2.2. Pathway Interventions

Leak and pore pathways differ in how they respond to interventions.

Leak: Experimental physiology shows that leak openings are driven primarily by inflammatory and cytoskeletal processes⁴. They can close rapidly once inflammation resolves but do not respond to ion-channel or charge-selective signals.

Pore: In contrast, pore-mediated transport is regulated by claudin-specific, charge-selective signaling^2,3. Pores open and close independently of inflammation, often with rapid gating in response to ionic or metabolic cues.

In practice, interventions that resolve inflammation target the leak pathway most directly, whereas interventions that alter charge-selective signaling primarily affect pores.

3. Prototype Diseases

Diseases were selected based on the following criteria:

• Gut-centric in origin
• Documented evidence of:

  –

  Barrier dysfunction

  –

  Metabolites exported from the lumen

  –

  Symptom associations for each metabolite

  –

  Clear identification of unique metabolites (e.g., ethanol) unlikely to be universal

• Some symptom overlap with the Vaes patient clusters beyond fatigue and brain fog
• Broad coverage across the gastrointestinal tract

All of the prototype diseases release metabolites that, once absorbed, can trigger host cytokine expression. These metabolites may contribute to common ME/CFS symptoms such as fatigue and brain fog, in addition to their metabolite-specific effects. We present the final list of diseases below:

Table 2. Disease and Gut Region Association

Disease	Gut Region
Celiac disease	Duodenum / Jejunum
SIBO / D-lactic acidosis	Duodenum / Jejunum
Crohn’s ileitis	Ileum
IBS-D	Proximal Colon
Microscopic / Inflammatory colitis	Colon (diffuse)
Ulcerative colitis (UC)	Distal Colon
Clostridioides difficile colitis	Distal Colon

Table 2. Disease and Gut Region Association

Disease	Gut Region
Celiac disease	Duodenum / Jejunum
SIBO / D-lactic acidosis	Duodenum / Jejunum
Crohn’s ileitis	Ileum
IBS-D	Proximal Colon
Microscopic / Inflammatory colitis	Colon (diffuse)
Ulcerative colitis (UC)	Distal Colon
Clostridioides difficile colitis	Distal Colon

3.1. Metabolites, Symptoms, and Paths

The set of metabolites documented in our prototype illnesses is surprisingly small — roughly a dozen. Here we list each one, the prototype illness associated with it, the path by which it is thought to reach the extra-luminal space, and the symptoms reported in that disease context.

Fatigue or brain fog are included only when directly attributed to the metabolite itself, rather than as secondary consequences of cytokine activation.

Path definitions:

• Diffusion: Metabolite passes freely through the gut epithelium without requiring barrier dysfunction.
• Overproduction: Metabolite is produced in excess in the gut (e.g., by enterochromaffin cells) and enters circulation independently of barrier disruption.
• Pore: Metabolite crosses via small, selective paracellular channels formed by tight junctions.
• Leak: Metabolite crosses via larger, non-selective paracellular defects associated with tight junction breakdown.

Table 3. Metabolites, Paths and Illnesses

Metabolite	Illnesses	Path	Documented Symptoms in Those Illnesses	Citation
Acetaldehyde	SIBO / D-lactic acidosis	Diffusion	Cognitive impairment, dizziness	5,6
Bile acids	Crohn’s ileitis, IBS-D	Pore	Diarrhea/urgency, abdominal pain, sleep/circadian disturbance, weight change	7;8
D-lactate	SIBO / D-lactic acidosis	Pore	Neurocognitive dysfunction, dizziness, fatigue*	9;10
Ethanol	SIBO / D-lactic acidosis	Diffusion	Dizziness, alcohol intolerance, malaise	11;12
Gliadin peptides	Celiac disease	Leak	Food intolerance, brain fog	13;14
Histamine	Celiac disease, Crohn’s ileitis, IBS-D, Microscopic colitis, SIBO	Pore	Flushing, headaches, abdominal pain, dizziness, fatigue	15;16
${\mathrm{H}}_2$S (diffused)	Ulcerative colitis, Clostridioides difficile colitis	Diffusion	Nausea, toxic-feeling flares, headaches	17;18
Indoxyl sulfate	Ulcerative colitis, Clostridioides difficile colitis	Pore	Chemical/odor sensitivity, vascular headaches	19;20
p-Cresol	Ulcerative colitis, Clostridioides difficile colitis	Pore	Chemical/odor sensitivity, vascular headaches	21;22
SCFAs (e.g., butyrate, acetate, propionate)	IBS-D, Microscopic colitis	Over produced/pore	Bloating, abdominal pain, malaise	23;24
Serotonin	Celiac disease, IBS-D	Over produced	Sleep disturbance, mood lability, GI motility issues	25;26

Table 3. Metabolites, Paths and Illnesses

Metabolite	Illnesses	Path	Documented Symptoms in Those Illnesses	Citation
Acetaldehyde	SIBO / D-lactic acidosis	Diffusion	Cognitive impairment, dizziness	5,6
Bile acids	Crohn’s ileitis, IBS-D	Pore	Diarrhea/urgency, abdominal pain, sleep/circadian disturbance, weight change	7;8
D-lactate	SIBO / D-lactic acidosis	Pore	Neurocognitive dysfunction, dizziness, fatigue*	9;10
Ethanol	SIBO / D-lactic acidosis	Diffusion	Dizziness, alcohol intolerance, malaise	11;12
Gliadin peptides	Celiac disease	Leak	Food intolerance, brain fog	13;14
Histamine	Celiac disease, Crohn’s ileitis, IBS-D, Microscopic colitis, SIBO	Pore	Flushing, headaches, abdominal pain, dizziness, fatigue	15;16
${\mathrm{H}}_2$S (diffused)	Ulcerative colitis, Clostridioides difficile colitis	Diffusion	Nausea, toxic-feeling flares, headaches	17;18
Indoxyl sulfate	Ulcerative colitis, Clostridioides difficile colitis	Pore	Chemical/odor sensitivity, vascular headaches	19;20
p-Cresol	Ulcerative colitis, Clostridioides difficile colitis	Pore	Chemical/odor sensitivity, vascular headaches	21;22
SCFAs (e.g., butyrate, acetate, propionate)	IBS-D, Microscopic colitis	Over produced/pore	Bloating, abdominal pain, malaise	23;24
Serotonin	Celiac disease, IBS-D	Over produced	Sleep disturbance, mood lability, GI motility issues	25;26

* Emerging [https://biosignaling.biomedcentral.com/articles/10.1186/s12964-025-02132-z]

Not listed in this table are cytokines, which do not cross the gut barrier but are immune moderated causes for fatigue, malaise, fever/flu-like symptoms, and inflammatory flares

4. Disease, Metabolite, Path Summary

When summarized by pathway and metabolite, our prototype diseases share two broad associations: pore-mediated leakage and histamine involvement.

We infer the pathway by the metabolite and based on this all of these diseases would involve significant pore activity, and most — with the exception of the two colitis forms — are associated with histamine leakage.

Table 4. Disease, region and pathways

Disease	Gut Region	Pathways Used for Metabolite Leakage
Celiac disease	Duodenum / Jejunum	Pore (histamine), Leak (gliadin peptides), Overproduction of Serotonin
SIBO / D-lactic acidosis	Duodenum / Jejunum	Pore (D-lactate,histamine), diffusion (Ethanol, Acetaldehyde)
Crohn’s ileitis	Ileum	Pore (bile acids, histamine)
IBS-D	Proximal Colon	Pore (SCFAs, histamine, serotonin, bile acids), Overproduction of serotonin
Microscopic / Inflammatory colitis	Colon (diffuse)	Pore (SCFAs, histamine), Leak
Ulcerative colitis (UC)	Distal Colon	Pore (indoxyl sulfate, p-cresol), diffusion (${\mathrm{H}}_2$S)
Clostridioides difficile colitis	Distal Colon	Pore* (secondary bile acids, p-cresol, indoxyl sulfate); Diffusion (${\mathrm{H}}_2$S)

Table 4. Disease, region and pathways

Disease	Gut Region	Pathways Used for Metabolite Leakage
Celiac disease	Duodenum / Jejunum	Pore (histamine), Leak (gliadin peptides), Overproduction of Serotonin
SIBO / D-lactic acidosis	Duodenum / Jejunum	Pore (D-lactate,histamine), diffusion (Ethanol, Acetaldehyde)
Crohn’s ileitis	Ileum	Pore (bile acids, histamine)
IBS-D	Proximal Colon	Pore (SCFAs, histamine, serotonin, bile acids), Overproduction of serotonin
Microscopic / Inflammatory colitis	Colon (diffuse)	Pore (SCFAs, histamine), Leak
Ulcerative colitis (UC)	Distal Colon	Pore (indoxyl sulfate, p-cresol), diffusion (${\mathrm{H}}_2$S)
Clostridioides difficile colitis	Distal Colon	Pore* (secondary bile acids, p-cresol, indoxyl sulfate); Diffusion (${\mathrm{H}}_2$S)

* Toxin-mediated epithelial injury (TcdA/TcdB) disrupts the barrier; classification reflects metabolite passage routes but the initiating damage is toxin-driven, not a canonical tight-junction pathway change.

5. Interventions

Looking across the prototypes, a consistent pattern emerges in the interventions that fail versus those that succeed (see Appendix A).

• Inflammation-only strategies do not resolve the root problem
  • Steroids, 5-ASA, biologics, or antihistamines alone can suppress cytokines or dampen symptoms, but they do not prevent metabolite leakage across the barrier.
  • This explains relapses in UC, Crohn’s disease, and microscopic colitis, as well as only partial symptom relief in CFS-type patients.
• Symptom-only drugs fail
  • Agents such as loperamide in IBS-D, antidiarrheals in SIBO, or painkillers in colitis provide temporary relief but leave the underlying export of metabolites unaddressed.
  • As a result, the disease process continues despite symptomatic improvement.
• Barrier repair and metabolite-targeted interventions show the greatest promise
  • Remove the offending metabolite (e.g., gluten-free diet in celiac).
  • Reduce metabolite production (e.g., antibiotics in SIBO, low-FODMAP diet in IBS-D).
  • Bind or block metabolites (e.g., bile acid sequestrants in Crohn’s disease, IBS-D, microscopic colitis).
  • Normalize barrier function (e.g., larazotide in celiac, though Phase 3 trials failed).
  • Restore metabolite ecology (e.g., fecal microbiota transplantation in C. difficile and UC).

These pattenrs mimic what we see for ME/CFS, and other diseases.

6. Discussion

If ME/CFS gut involvement parallels the patterns observed in our prototype diseases, then effective interventional trials should prioritize two strategies: normalizing pore pathway function and reducing histamine activity.

Moreover, the relatively small number of distinct metabolites identified across prototypes suggests that metabolite leakage in ME/CFS may also be limited in scope, even when multiple gut regions are involved. This constraint may help explain why patients exhibit overlapping symptom clusters despite heterogeneous overall presentations.

7. Conclusions

We have presented a survey of prototype diseases that shed light on ME/CFS interventions and potentially other chronic illnesses. Although these diseases differ in pathogenesis, they share two key features: gut barrier disruption and metabolite leakage. Their treatment responses are also broadly shared with ME/CFS, in that anti-inflammatory agents fail to provide durable benefit or yield only limited improvements.

Appendix A.1

Celiac disease (Duodenum/Jejunum)

Barrier pathway focus	Successful / promising	Failed / limited
Leak (gliadin peptides); Pore (histamine)	Gluten-free diet (GFD): normalizes permeability and resolves symptoms in adherent patients1. Larazotide (TJ modulator): Phase 2 RCTs showed symptom benefit during gluten challenge2.	Larazotide Phase 3: discontinued for lack of efficacy3. Anti-inflammatories/biologics: not effective for routine CeD, do not address barrier leak4.

SIBO / D-lactic acidosis (Duodenum/Jejunum)

Barrier pathway focus	Successful / promising	Failed / limited
Pore (D-lactate, histamine); Diffusion (ethanol, acetaldehyde)	Antibiotics such as rifaximin and metronidazole reduce bacterial overgrowth and improve symptoms5. Dietary carbohydrate restriction (low-FODMAP, low simple sugars) reduces fermentation and metabolite load6. Some probiotics reduce D-lactate producers, though evidence is mixed7.	Anti-inflammatories do not address metabolite production or permeability8. Symptomatic drugs (antidiarrheals) do not address underlying leakage9.

Crohn’s ileitis (Ileum)

Barrier pathway focus	Successful / promising	Failed / limited
Pore (bile acids, histamine)	Bile-acid sequestrants (cholestyramine, colesevelam) reduce bile-acid diarrhea in ileal Crohn’s and resection patients10. Nutritional therapy (exclusive enteral nutrition) improves barrier integrity and reduces inflammation11.	Antihistamines (H1/H2) alone have not shown consistent benefit in IBD12. Anti-TNF and other biologics reduce inflammation but do not directly normalize bile-acid–driven barrier leakage13.

Barrier pathway focus	Successful / promising	Failed / limited
Pore (SCFAs, histamine, bile acids); Overproduction (serotonin)	Rifaximin improves global symptoms and bloating in IBS-D1415. Bile-acid sequestrants (e.g., colesevelam/cholestyramine) help IBS-D subsets with bile-acid excess16. Low-FODMAP diet reduces fermentation load → symptom improvement1718. 5-HT3 antagonists (e.g., alosetron; ondansetron in smaller trials) reduce urgency/diarrhea1920.	Anti-inflammatory/biologic therapies (cytokine-targeted) are not effective for IBS-D21. Symptom-only meds (e.g., loperamide) don’t address metabolite production or permeability22.

IBS-D (Proximal Colon)

Barrier pathway focus	Successful / promising	Failed / limited
Pore (SCFAs, histamine, bile acids); Overproduction (serotonin)	Rifaximin improves global symptoms and bloating in IBS-D2324. Bile-acid sequestrants (e.g., colesevelam, cholestyramine) help subsets with bile-acid excess25. Low-FODMAP diet reduces fermentation load and improves symptoms2627. 5-HT3 antagonists (e.g., alosetron; ondansetron in smaller trials) reduce urgency and diarrhea2829.	Anti-inflammatory/biologic therapies (cytokine-targeted) are not effective in IBS-D30. Symptom-only meds (e.g., loperamide) do not address metabolite production or permeability31.

Microscopic / Inflammatory colitis (Colon, diffuse)

Barrier pathway focus	Successful / promising	Failed / limited
Pore (SCFAs, histamine); Leak	Budesonide is first-line therapy and effective at inducing remission, though relapse is common after withdrawal3233. Bile-acid sequestrants are helpful in patients with bile-acid malabsorption, with ~2/3 showing benefit3435.	Mesalamine and other anti-inflammatories show inconsistent or minimal efficacy36. Probiotics have not shown consistent benefit37.

Ulcerative colitis (Distal Colon)

Barrier pathway focus	Successful / promising	Failed / limited
Pore (indoxyl sulfate, p-cresol); Diffusion (${\mathrm{H}}_2$S)	5-ASA (mesalamine) and steroids induce remission by reducing inflammation, though they do not prevent metabolite leakage3839. Dietary modulation (e.g., low-sulfur diets) may reduce ${\mathrm{H}}_2$S burden, limited supportive evidence40. FMT shows benefit in some patients, likely by restoring bile-acid and SCFA metabolism41.	Biologics (anti-TNF, anti-integrin) are effective for inflammation but do not address barrier dysfunction or metabolite leakage42. Barrier-directed agents (e.g., larazotide) have not been tested in UC.

Clostridioides difficile colitis (Distal Colon)

Barrier pathway focus	Successful / promising	Failed / limited
Pore* (secondary bile acids, p-cresol, indoxyl sulfate); Diffusion (${\mathrm{H}}_2$S)	FMT is highly effective for recurrent CDI, restoring secondary bile acid metabolism that inhibits C. difficile germination4344. Standard antibiotics (vancomycin, fidaxomicin) resolve acute infection but do not restore barrier or metabolite balance45. Bezlotoxumab (anti-toxin B monoclonal) reduces recurrence in high-risk patients46.	Anti-inflammatories provide no benefit as they do not address toxin or metabolite leakage47. Recurrence rates remain high with antibiotics alone.

* Toxin-mediated epithelial injury (TcdA/TcdB) disrupts the barrier; classification reflects metabolite passage routes but the initiating damage is toxin-driven, not classic tight junction dysfunction.