Hostname: page-component-cd9895bd7-8ctnn Total loading time: 0 Render date: 2024-12-23T13:28:08.628Z Has data issue: false hasContentIssue false

Improved gastrointestinal tolerance and iron status via probiotic use in iron deficiency anaemia patients initiating oral iron replacement: a randomised controlled trial

Published online by Cambridge University Press:  04 November 2024

Gokhan Koker
Affiliation:
Department of Internal Medicine, University of Health Sciences Antalya Training and Research Hospital, Antalya, Turkey
Yasin Sahinturk*
Affiliation:
Department of Internal Medicine, University of Health Sciences Antalya Training and Research Hospital, Antalya, Turkey
Gulhan Ozcelik Koker
Affiliation:
Department of Internal Medicine, University of Health Sciences Antalya Training and Research Hospital, Antalya, Turkey
Muhammed Ali Coskuner
Affiliation:
Department of Internal Medicine, University of Health Sciences Antalya Training and Research Hospital, Antalya, Turkey
Merve Eren Durmus
Affiliation:
Department of Gastroenterology, University of Health Sciences Antalya Training and Research Hospital, 07100 Muratpaşa, Antalya, Turkey
Mehmet Mutlu Catli
Affiliation:
Department of Internal Medicine, University of Health Sciences Antalya Training and Research Hospital, Antalya, Turkey
Ayhan Hilmi Cekin
Affiliation:
Department of Gastroenterology, University of Health Sciences Antalya Training and Research Hospital, 07100 Muratpaşa, Antalya, Turkey
*
Corresponding author: Yasin Sahinturk; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

This study aimed to investigate gastrointestinal tolerability, treatment persistence and iron status markers in patients with iron deficiency anaemia (IDA) who received oral iron replacement therapy (IRT) with v. without concomitant Lactobacillus plantarum 299v (L. plantarum 299v) probiotic supplementation. A total of 295 patents with newly diagnosed IDA were randomly assigned to receive either IRT alone (n 157, IRT-only group) or IRT plus L. plantarum 299v (n 138, IRT-Pro group) in this prospective randomised non-placebo-controlled study (ClinicalTrials.gov Identifier: NCT06521879). Gastrointestinal intolerance symptoms (at baseline, within the first 30 d of IRT and at any time during 3-month IRT), serum Hb levels (at baseline and 3rd month of IRT) and iron status markers (at baseline and 3rd month of IRT) were recorded. IRT-Pro group, when compared with IRT-only group, experienced significantly lower rates of gastrointestinal intolerance over the course of IRT (13·0 % v. 46·5 %, P < 0·001) and treatment discontinuation within the first 30 d (3·6 % v. 15·9 %, P < 0·001). At 3rd month of therapy, IRT-Pro v. IRT-only group had significantly higher serum levels for iron (76·0 (51·0–96·0) v. 60·0(43·0–70·0) µg/dl, P < 0·001) and transferrin saturation (20·1 (12·5–28·5) v. 14·5 (10·5–19·0) %, P < 0·001) and higher change from baseline Hb (0·9 (0·3–1·3) v. 0·4 (–0·1–1·1) g/dl, P < 0·001) levels. Use of L. plantarum 299v probiotic supplementation during the first 30 d of IRT in IDA patients significantly reduces the gastrointestinal burden of IRT (particularly abdominal pain and bloating), the likelihood of intolerance development (by ∼3 times) and treatment discontinuation (by∼5 times), as accompanied by improved serum Hb levels and serum iron markers.

Type
Research Article
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 (https://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), 2024. Published by Cambridge University Press on behalf of The Nutrition Society

Iron deficiency anaemia (IDA) is one of the most prevalent micronutrient deficiencies and a global health concern(Reference Stevens and Finucane1,Reference Kumar, Arnipalli and Mehta2) . IDA has detrimental health consequences such as severe fatigue, dyspnoea and impaired thermoregulatory, neurocognitive and immune functions, in addition to its association with adverse outcomes in chronic kidney disease or chronic heart failure(Reference Seo, Yoon and Ul-Haq3Reference Vonderheid, Tussing-Humphreys and Park6).

Considering its hazard for the worldwide population, prevention and treatment of iron deficiency and IDA is of critical importance, while the strategies are mainly based on combination of dietary improvement, iron fortification of food, and iron supplementation(Reference Korčok, Tršić-Milanović and Ivanović7Reference Bazeley and Wish9). Amongst these, oral iron supplementation (i.e. ferrous sulphate, gluconate and fumarate) is the most widely available and affordable method but its effectiveness is considerably limited by gastrointestinal side effects (in up to 70 % of patients), markedly impairing adherence to treatment and repletion of iron stores(Reference Kumar, Arnipalli and Mehta2,Reference Vonderheid, Tussing-Humphreys and Park6,Reference Kumar, Sharma and Marley10Reference Tolkien, Stecher and Mander13) .

Besides the inadequate iron intake, low iron bioavailability and absorption are also implicated in IDA pathogenesis and are highly affected by the gut microbiota composition(Reference Rusu, Suharoschi and Vodnar8). The absorption of iron from diet or oral supplements is a complex mechanism, while oral iron supplements may also alter the composition of the gut microbiota towards a more pro-inflammatory milieu and decrease iron bioavailability(Reference Vonderheid, Tussing-Humphreys and Park6,Reference Rusu, Suharoschi and Vodnar8,Reference Deschemin, Noordine and Remot14,Reference Jaeggi, Kortman and Moretti15) . Hence, strategies that consider enhancing iron absorption and reducing the risk of gastrointestinal side effects are important for effective iron replacement in patients with IDA(Reference Vonderheid, Tussing-Humphreys and Park6,Reference Hoppe, Önning and Berggren16) .

The gut microbiota enhances the host’s access to dietary iron by reducing the concentration of iron-binding compounds in the gut, and by converting Fe3+ to Fe2+, the absorbable ion form(Reference Skrypnik, Bogdański and Schmidt17). Due to the role of gut microbiota in regulating iron balance, probiotics have been suggested as a potential strategy to enhance iron absorption and alleviate deficiency, enabling a higher reduction of ferric iron to a bioavailable form, improved iron uptake by enterocytes, and an anti-inflammatory immune response(Reference Vonderheid, Tussing-Humphreys and Park6,Reference Rusu, Suharoschi and Vodnar8) .

Use of probiotics, mostly the Lactobacillus and Bifidobacterium strains, as live microorganisms that improve composition of the gut microbiota, has gained public popularity because of their wide range of preventative and therapeutic potentials(Reference Zakrzewska, Zawartka and Schab4,Reference Korčok, Tršić-Milanović and Ivanović7,Reference Rusu, Suharoschi and Vodnar8,Reference Gómez-Ramírez, Brilli and Tarantino11) .

Lactic acid-forming bacteria (lactobacilli) can increase iron absorption by lowering intestinal pH, activating phytases, causing shifts in gut microbiota metabolism and inducing anti-inflammatory immunomodulation(Reference Vonderheid, Tussing-Humphreys and Park6,Reference Hoppe, Önning and Berggren16,Reference Wells18) . This suggests that utilisation of probiotic bacteria may be a valuable clinical tool in prevention and amelioration of IDA, by optimising dietary iron bioavailability and thus improving iron status without the gastrointestinal burden of additional supplemental iron(Reference Goodnough, Nemeth and Ganz5Reference Rusu, Suharoschi and Vodnar8). Specifically, the strain Lactobacillus plantarum 299v (L. plantarum 299v) with the ability to survive the passage through acid stomach and colonise the intestine(Reference Hoppe, Önning and Berggren16,Reference Goossens, Jonkers and Russel19) has been shown to reduce bloating and abdominal pain in irritable bowel syndrome patients(Reference Ducrotté, Sawant and Jayanthi20,Reference Niedzielin, Kordecki and Birkenfeld21) and to increase iron absorption and dietary iron bioavailability in IDA patients(Reference Vonderheid, Tussing-Humphreys and Park6,Reference Hoppe, Önning and Berggren16,Reference Bering, Sjøltov and Wrisberg22,Reference Scheers, Rossander-Hulthen and Torsdottir23) . However, while probiotics were reported to be associated with amelioration of gastrointestinal intolerance symptoms in different settings(Reference Ducrotté, Sawant and Jayanthi20,Reference Niedzielin, Kordecki and Birkenfeld21,Reference Şahin, Şahintürk and Köker24Reference Asemi, Bahmani and Shakeri27) , their effects on gastrointestinal burden of iron replacement therapy (IRT) as well as on body iron status are less extensively studied in patients with IDA(Reference Zakrzewska, Zawartka and Schab4,Reference Vonderheid, Tussing-Humphreys and Park6Reference Rusu, Suharoschi and Vodnar8,Reference Axling, Önning and Martinsson Niskanen28,Reference OjiNjideka Hemphill, Pezley and Steffen29) .

Therefore, this study aimed to investigate the effects of L. plantarum 299v probiotic supplementation added to oral IRT on gastrointestinal burden, tolerability, treatment compliance and serum iron status markers in patients with newly diagnosed IDA.

Materials and methods

Study population

A total of 295 patients with newly diagnosed IDA who were planned to receive routine oral IRT were included in this prospective randomised non-placebo, controlled 3-month follow-up study (ClinicalTrials.gov Identifier: NCT06521879) conducted between September 2020 and March 2022 at a tertiary care internal medicine clinic. Patients were randomly assigned via simple randomisation method (computer-generated random number sequence) to receive either IRT alone (n 157, IRT-only group) or IRT plus L. plantarum 299v probiotic support (n 138, IRT-Pro group). Adult (aged > 18 years) treatment-naïve patients diagnosed with newly diagnosed IDA without previous IRT were included in the study, while those with irritable bowel syndrome, previous IRT therapy or intolerance to IRT and those with a known chronic disease (i.e. inflammatory bowel disease and celiac disease) or untreated active menometrorrhagia and haemorrhoid were excluded from the study.

Written informed consent was obtained from each subject following a detailed explanation of the objectives and protocol of the study which was conducted in accordance with the ethical principles stated in the ‘Declaration of Helsinki’ and approved by the Clinical Research and Ethics Committee of University of Health Sciences Antalya Training and Research Hospital (Date of Approval: 27/08/2020; Protocol No: 13/15).

IDA definition

IDA was defined as having ferritin levels of < 20 ng/ml or transferrin saturation < 15 %, while the Hb levels were below 12 mg/dl(Reference Buttarello, Pajola and Novello30).

Treatments

All patients received IRT with ferrous sulphate (Fe2+: 304·2 mg ferrous fumarate in pellet form, equivalent to 100 mg elemental iron) preparation (100 mg, once daily) for 3 months, while those in the IRT-Pro group also received daily (10B CFU) L. plantarum 299v (Probest®, Abdi Ibrahim, Turkey) probiotic supplementation for 30 d starting from the first day of IRT.

Assessments

Data on gastrointestinal intolerance symptoms (loss of appetite, nausea, vomiting, abdominal pain, diarrhoea, constipation and bloating) were recorded at three time points including baseline, within the first 30 d of IRT and at any time during 3-month IRT. Overall, intolerance symptoms were evaluated based on new-onset (not present at baseline but appeared on IRT), ameliorated (present at baseline but disappeared on IRT) and total ((baseline + new onset) – (ameliorated)) symptom rates. A seven-item questionnaire was used to assess the presence of gastrointestinal intolerance symptoms during the past week on a binary scale (Yes or No), including the six items (nausea, vomiting, abdominal pain, bloating, constipation, diarrhoea) of Gastrointestinal Symptom Rating Scale(Reference Kulich, Madisch and Pacini31) and the loss of appetite (poor or very poor appetite) as the seventh item using the first question of the Appetite and Dietary Assessment Tool(Reference Burrowes, Powers and Cockram32).

Serum Hb levels (g/dl) and serum iron status markers including ferritin (ng/ml), iron (µg/dl), total iron-binding capacity (TIBC, µg/dl) and transferrin saturation (%) were recorded at baseline and at 3rd month of IRT. Samples for complete blood count were collected in K3EDTA tubes and analysed with an automated haematology analyser including Beckman-Coulter for Hb measurement and LISA 500 Plus automated chemical analyser (Hycell Diagnostics, Paris, France) for serum iron markers. Transferrin saturation was calculated by dividing serum iron by TIBC X 100.

Data on treatment discontinuation (persistence to IRT) were also recorded in study groups along with comparison of study variables in patients with v. without treatment discontinuation within the first 30 d of IRT.

Statistical analysis

At least 189 patients were calculated to be included via sample size estimation (G * Power 3·1·9 program) based on a power of 80 % at a type I error of 0·05 and an effect size (w = 0·261) calculated using data from a previous study by Cekin et al.(Reference Çekin, Şahintürk and Akbay Harmandar25). Given the high likelihood of missing data, a total of 200 patients were planned to be included in the study population with the use of 25 % lost to follow-up ratio.

Statistical analysis was made using IBM SPSS Statistics for Windows, Version 22.0 (IBM Corp.). Pearson’s chi-square test, Fisher’s exact test and McNemar test were used for analysis of categorical variables. Mann–Whitney U test was used for analysis of non-normally distributed numerical data while independent sample t test was used for normally distributed data. The number needed to treat (NNT) analysis was performed to determine how many patients must receive IRT-Pro instead of IRT to prevent one additional treatment discontinuation. Data are expressed as mean (sd, median, interquartile range, minimum-maximum and per cent (%) where appropriate. P < 0·05 was considered statistically significant.

Results

Patient demographics, intolerance development and treatment discontinuation

A total of 295 patents with newly diagnosed IDA were included in the study as randomly assigned to IRT-only (n 157) or IRT-Pro (n 138) groups. Mean (sd) patient age was 36·1(10·7) years and 96·3 % of patients were females. Both in the overall study population (n 295) and in patients with gastrointestinal intolerance symptoms (n 91), IRT-only and IRT-Pro groups were homogenous in terms of patient demographics (Table 1).

Table 1. Patient demographics, intolerance development and treatment discontinuation (Numbers and percentages; mean values and sd)

IRT: Iron replacement therapy; IRT-only: received IRT alone; IRT-Pro: received IRT plus L. plantarum 299v.

Independent t test, Mann–Whitney U test, Pearson’s chi-square test, Fisher’s exact test.

*P < 0·01 and **P < 0·001 compared with IRT-Pro group.

Overall, 91 (30·8 %) of 295 patients reported gastrointestinal intolerance symptoms within 3 months of IRT. Patients in the IRT-Pro group compared with those in the IRT-only group had significantly lower rate of gastrointestinal intolerance development within 3 months of IRT (13·0 % v. 46·5 %, P < 0·001) (Table 1).

Treatment discontinuation within 3 months of IRT occurred in 36 (12·2 %) of 295 patients, while it was within the first 30 d of IRT in 30 (10·2 %) patients. Overall (17·8 v. 5·8 %, P < 0·01) and first 30-day (15·9 % v. 3·6 %, P < 0·001) treatment discontinuation rates were significantly higher in the IRT-only group than in the IRT-Pro group (Table 1).

IRT-Pro had an NNT of 3, indicating that 3 patients have to be treated with IRT-Pro instead of IRT-only to prevent one additional treatment discontinuation.

Among patients who discontinued IRT within the first 30 d, constipation was the leading symptom (30·0 %), followed by nausea (23·3 %) and abdominal pain (20·0 %), all of which were particularly noted in the IRT-only group (23·3 %, 16·7 % and 16·7 %, respectively) (Table 1).

Intolerance data at baseline and within 3 months of iron replacement in study groups

Baseline rates for abdominal pain (17·4 v. 4·5 %, P < 0·001) and diarrhoea (5·8 v. 1·3 %, P = 0·049) were significantly higher in the IRT-Pro group (n 138) than in the IRT-only (n 157) group (Table 2).

Table 2. Intolerance symptoms at baseline and during 3 months of IRT in study groups (Numbers and percentages)

IRT: Iron replacement therapy; IRT-only: received IRT alone; IRT-Pro: received IRT plus L. plantarum 299v.

New-onset: not present at baseline but appeared on IRT; ameliorated: present at baseline but disappeared on IRT; total: ((baseline + new onset) – (ameliorated)).

*Fisher exact test, Pearson’s chi-square test, McNemar test (baseline v. during 3 months of IRT).

All relevant values were formatted in italic and bold face.

In the IRT-only group, symptom rates significantly increased from baseline over the course of iron replacement (n 132), including loss of appetite (1·3 v. 6·8 %, P = 0·008), nausea (0·0 v. 17·4 %, P < 0·001), abdominal pain (4·5 v. 19·7 %, P < 0·001) and constipation (1·3 v. 14·4 %, P < 0·001). In the IRT-pro group (n 133), significant decrease from baseline rates was noted in the abdominal pain (17·4 v. 13·3 %, P < 0·001) and bloating (20·3 v. 8·3 %, P = 0·006), while constipation (4·3 v. 7·5 %) showed significant increase from baseline (Table 2).

Loss of appetite (0·8 v. 6·8 %, P = 0·010), nausea (3·8 v. 17·4 %, P < 0·001), abdominal pain (3·0 v. 19·7 %, P < 0·001) and bloating (8·3 v. 24·2 %, P < 0·001) were significantly less common in the IRT-Pro group than in the IRT-only group (Table 2).

Considering the intolerance symptoms newly emerged under IRT, the likelihood of developing de novo loss of appetite (6·1 v. 0·8 %, P = 0·019), nausea (17·4 v. 3·8 %, P < 0·001), abdominal pain (15·2 v. 0·0 %, P < 0·001) and constipation (13·6 v. 4·5 %, P = 0·010) were significantly higher in the IRT group than in the IRT-Pro group (Table 2).

Serum iron status markers

At baseline, serum ferritin levels (5·0 (3·0–7·0) v. 7·0 (4·0–12·0) ng/ml, P < 0·001) and transferrin saturation (10·05 (5·2–16·0) v. 12·1 (8·1–17·1)%, P = 0·029) were significantly lower in the IRT-Pro group (n 138) than in the IRT-only (n 157) group (Table 3).

Table 3. Serum iron status markers from baseline to 3rd month of iron replacement therapy (Median values and interquartile ranges)

IRT-only: received IRT alone; IRT-Pro: received IRT plus L. plantarum 299v; IQR: Interquartile range; TIBC: Total iron-binding capacity.

Mann–Whitney U test.

All relevant values were formatted in bold face.

At 3rd month of therapy, IRT-Pro (n 130) v. IRT-only (n 129) group had significantly higher serum levels for iron (76·0 (51·0–96·0) v. 60·0 (43·0–70·0) µg/dl, P < 0·001) and transferrin saturation (20·1 (12·5–28·5) v. 14·5 (10·5–19·0)%, P < 0·001) as well as higher change from baseline ferritin (13·0 (8·0–17·0) v. 5·0 (–1·0–15·0 ng/ml, P < 0·001), iron (23·5(5·0–48·0) v. 8·0 (–6·0–23·0) µg/dl, P < 0·001), transferrin saturation (8·2 (2·7–14·1) v. 2·1 (–1·5–6·3)%, P < 0·001) and Hb (0·9 (0·3–1·3) v. 0·4 (–0·1–1·1) g/dl, P < 0·001) (Table 3).

The 3rd-month TIBC levels were significantly lower (368·5 (327·0–402·0) v. 396·0 (374·0–421·0) µg/dl, P < 0·001) in the IRT-Pro group, as well as more remarkable decrease from baseline TIBC (–45·5 (–76·0/ −3·0) v. −11·0 (–40·0/24·0) µg/dl, P < 0·001) (Table 3).

Patient demographics and baseline serum iron markers according to treatment discontinuation

No significant difference was noted in patients who discontinued treatment within 30 d and those who continued therapy in terms of patient demographics or baseline serum iron status markers (Table 4).

Table 4. Patient demographics and baseline serum iron status markers according to treatment discontinuation within 30 d (Mean values and sd; median values and minimum and maximum values)

IRT-only: received IRT alone; IRT-Pro: received IRT plus L. plantarum 299v.

*Independent t test, Fisher exact test, Mann–Whitney U test.

Discussion

Our findings revealed that at least one-third of patients developed gastrointestinal intolerance within 3 months of IRT, while the first 30 d of IRT was the most critical period for treatment discontinuation. Importantly, concomitant use of L. plantarum 299v probiotic supplementation during this critical period significantly reduced the likelihood of intolerance development (by ∼3 times) and treatment discontinuation (by∼5 times), increasing the gastrointestinal tolerability of the IRT, which also enabled the significantly improved serum iron status markers.

In addition, patients in the IRT-Pro group were more advantageous not only in terms of prevention of intolerance symptoms emerging over the course of IRT (loss of appetite, nausea, abdominal pain and constipation) but also in terms of amelioration of symptoms recorded at baseline (loss of appetite, nausea, abdominal pain and bloating), which seemed to positively affect their adherence to IRT. In contrast, IDA patients who received only IRT experienced significant increase of symptoms recorded at baseline such as loss of appetite, nausea and abdominal pain as well as a greater increase in constipation (∼10-fold v. ∼2-fold in IRT-Pro group). These findings seem notable given that constipation, nausea and abdominal pain were also the leading symptoms in patients who discontinued IRT within the first 30 d, and all were particularly noted in the IRT group.

Consistent with our findings, L. plantarum 299v supplementation has been reported to have many clinically confirmed positive effects such as improving gastrointestinal wellbeing in a healthy population, symptom relief by decreasing bloating and abdominal pain and normalisation of stool frequency as early as in the 2nd week of consumption in irritable bowel syndrome patients and decreasing the incidence of diarrhoea among patients receiving antibiotics(Reference Ducrotté, Sawant and Jayanthi20,Reference Niedzielin, Kordecki and Birkenfeld21,Reference Kujawa-Szewieczek, Adamczak and Kwiecień33,Reference Kaźmierczak-Siedlecka, Daca and Folwarski34) .

L. plantarum 299v has also the ability to survive passage through gastrointestinal tract and to inhibit the growth of potentially pathogenic bacteria in the intestine in addition to anti-inflammatory effects(Reference Ducrotté, Sawant and Jayanthi20,Reference Niedzielin, Kordecki and Birkenfeld21,Reference Kaźmierczak-Siedlecka, Daca and Folwarski34) . Notably, many studies indicated a link between gut microbiota (dysbiosis) and IDA as well as the association of iron therapy with the diversity and composition of the intestinal flora(Reference Seo, Yoon and Ul-Haq3,Reference Zakrzewska, Zawartka and Schab4,Reference Sandberg, Önning and Engström35Reference Liu, Wu and Luo37) .

While iron therapy is considered to normalise Hb within 2 months of treatment onset, and to build up iron stores within the next 2–3 months, many patients face considerable challenges in adhering to and persisting with the full iron replacement regimen(Reference Serati and Torella38). Our results showed that IRT-Pro regimen had an NNT of 3, indicating that 3 patients have to be treated with IRT-Pro instead of IRT alone to prevent one additional treatment discontinuation Hence, use of L. plantarum 299v for the first 30 d of iron replacement seems to be a favourable treatment approach in IDA patients in terms of preventing the considerable gastrointestinal burden, including the amelioration of the symptoms already existent before IRT, and increasing patient adherence to IRT(Reference Vonderheid, Tussing-Humphreys and Park6,Reference Korčok, Tršić-Milanović and Ivanović7,Reference Finlayson-Trick, Fischer and Goldfarb39) .

The iron replacement aims not only to correct the Hb deficit but also to provide enough iron for measurable iron stores(Reference Auerbach and Adamson12). Our findings emphasise the potential benefit of using L. plantarum 299v supplementation in provision of more adequate supply of iron for Hb synthesis and in increasing the iron stores (improved iron status markers such as serum iron, ferritin, TIBC and transferrin saturation) and thus improving the effectiveness of oral iron replacement in patients with IDA.

The positive effects of using L. plantarum 299v supplementation for the first 30 d of IRT seem to indicate the likelihood of this probiotic strain to counteract the adverse effects of residual iron supplement that remains largely unabsorbed in the digestive tract, commonly causing adverse gastrointestinal events, reduced compliance and inefficient repletion of iron stores(Reference Seo, Yoon and Ul-Haq3,Reference Zakrzewska, Zawartka and Schab4,Reference Tolkien, Stecher and Mander13,Reference Richards, Breymann and Brookes40) .

In fact, given the improved tolerability and iron status markers within 3 months of therapy, use of L. plantarum 299v may also decrease the need for longer-term use of oral iron replacement or use of IV replacement, as well as the related gastrointestinal burden, offering a potentially cost-effective alternative in the management of IDA patients.

Data from clinical studies also revealed the association of L. plantarum 299v supplementation with increased bioavailability and absorption of iron in different types of iron deficiencies(Reference Zakrzewska, Zawartka and Schab4,Reference Vonderheid, Tussing-Humphreys and Park6,Reference Hoppe, Önning and Berggren16,Reference Bering, Sjøltov and Wrisberg22,Reference Scheers, Rossander-Hulthen and Torsdottir23,Reference Bering, Suchdev and Sjøltov41) . The exact mechanism behind the beneficial effects of L. plantarum 299v on dietary non-heme iron absorption is not known. Nonetheless, the process is considered likely to be mediated by the formation of bioavailable ferrous form by reduction of ferric iron (increasing iron uptake by enterocytes), the enhanced mucin production at the intestinal surface (promoting enterocyte iron uptake) and the immunomodulation promoting an anti-inflammatory immune response that suppresses the inflammatory cytokine-mediated increase in circulating hepcidin which otherwise blocks the passage of iron from the intestinal cell to the plasma (enhancing iron bioavailability)(Reference Zakrzewska, Zawartka and Schab4,Reference Vonderheid, Tussing-Humphreys and Park6,Reference Axling, Önning and Martinsson Niskanen28,Reference Hurrell42) . Hence, L. plantarum 299v supplementation seems to ensure adequate iron absorption by affecting multitude of factors implicated in the iron bioavailability, such as the choice of iron compound, the physiological state of the consumer (i.e. iron status, other nutritional deficiencies and inflammatory disorders) and the presence of enhancers and inhibitors of absorption in the food matrix(Reference Hurrell42,Reference Suchdev, Williams and Mei43) .

Similar to our results, in a recent randomised clinical trial in iron-deficient athletes, intake of L. plantarum 299v plus 20 mg of iron was considered likely to result in a more substantial and rapid improvement in iron status compared with 20 mg of iron alone(Reference Axling, Önning and Combs44). In addition, L. plantarum 299v (plus sucrosomial iron and vitamin C) was reported to have a positive effect on the treatment and prevention of IDA, which causes higher iron blood levels (by 11 %) because of increased iron absorption compared with use of only sucrosomial iron and vitamin C(Reference Korčok, Tršić-Milanović and Ivanović7). Studies in pregnant women also showed the association of L. plantarum 299v with slower decline in maternal haematological and iron parameters across pregnancy in non-anaemic women as well as in those who are at risk for IDA in pregnancy(Reference Axling, Önning and Martinsson Niskanen28,Reference OjiNjideka Hemphill, Pezley and Steffen29) .

In a meta-analysis of eight studies on the effect of the probiotic L. plantarum 299v on iron absorption in healthy women of childbearing age, pregnant women and patients with IDA, L. plantarum 299v was concluded to significantly improve non-heme dietary iron absorption in humans(Reference Vonderheid, Tussing-Humphreys and Park6), while only one of eight studies reported improvement in iron status-related indices(Reference Vonderheid, Tussing-Humphreys and Park6,Reference Korčok, Tršić-Milanović and Ivanović7) . Importantly, providing data on the beneficial effects of L. plantarum 299v probiotic strain in IDA patients also in terms of iron status markers, our results indicate the likelihood of using L. plantarum 299v probiotic supplementation within the first 30 d of IRT to enable two sine qua non of the proper medication adherence and persistence, namely the perceived efficacy (reduced symptoms of iron deficiency) and the improved tolerability(Reference Serati and Torella38,Reference Fikri, Ridha and Putri45) . Nonetheless, there remains a need for further research toward filling gaps in the existing literature given that the effect of probiotics on body iron status remains to be less certain than their effects on iron absorption(Reference Vonderheid, Tussing-Humphreys and Park6).

Certain limitations to this study should be considered. First, single-centre study design, preponderance of female participants and exclusion of patients with known intolerance to oral iron or those with chronic diseases (i.e. İBS and inflammatory bowel disease) limit the generalisability of the findings to broader populations, including males, diverse ethnic groups and unselected patient populations. This might have also caused a selection bias toward a favourable tolerability for oral iron and affected our tolerability and treatment discontinuation results. Second, given the potential psychological effects of probiotic support, the lack of a placebo group seems to be another limitation of the present study in terms of the likelihood of a placebo effect with potential impact on the subjective symptom reporting. Nonetheless, the marked differences between treatment groups in gastrointestinal intolerance and treatment discontinuation seem to indicate a strong impact of probiotic therapy which cannot be explained solely by the placebo effect. Also, NNT analysis, which was performed particularly for this reason (lack of placebo arm), did not reveal a high NNT value which otherwise would indicate the likelihood of placebo effect. Third, assessment of symptom frequency was based on subjective reporting along with lack of items on symptom severity. Fourth, use of only the persistence (treatment discontinuation) measure of compliance with lack of adherence data is another important limitation of the study. Fifth, lack of data on iron regulation, including hepcidin, erythropoietin and erythroferrone, as the potential players, as well as the lack of data on purity testing of probiotic and no stool collection to demonstrate LP299V colonisation in gut or changes to microbiome are other limitations. Nevertheless, despite these certain limitations, given the restricted amount of data on iron status changes in IDA patients treated with probiotic plus IRT, our findings represent a valuable contribution to the literature.

Conclusion

In conclusion, our findings in IDA patients revealed that using L. plantarum 299v probiotic supplementation during the first 30 d of IRT significantly reduced the gastrointestinal burden (particularly abdominal pain and bloating) related to IRT, the likelihood of developing de novo symptoms (loss of appetite, nausea, abdominal pain and constipation) under IRT and the likelihood of intolerance development (by ∼3 times) within 3 months of therapy and treatment discontinuation (by∼5 times) within 30 d of therapy. The improved gastrointestinal tolerability and patient adherence to oral IRT was also accompanied by a more remarkable improvement in serum iron markers in patients who received L. plantarum 299v. Hence, using L. plantarum 299v probiotic supplementation for the first 30 d of iron replacement seems to be a favourable treatment approach in IDA patients, given that oral IRT is limited by gastrointestinal side effects and noncompliance. Given the complex interplay between gut microbiota and iron bioavailability, and the research gap regarding the effects of probiotics on iron status, the long-term effects of different probiotic strains in combination with different iron preparations on iron status markers should further be investigated in unselected IDA populations.

Acknowledgements

None.

The authors did not receive support from any organisation for the submitted work.

Y. S. and G. K. contributed to conception and design. Y. S., G. K., G. O. K., A. C., M. E. D., M. M. C. and A. H. C. contributed to data acquisition. Y. S., G. K., G. O. K., A. C., M. E. D., M. M. C. and A. H. C. performed data analysis and interpretation. Y. S. performed drafting the manuscript. A. H. C. performed critical revision of the manuscript for important intellectual additions. All authors approved the final version of the manuscript for publication.

The authors declare that they have no conflicts of interest.

References

Stevens, GA, Finucane, MM, Nutrition Impact Model Study Group (Anaemia), et al. (2013) Global, regional, and national trends in haemoglobin concentration and prevalence of total and severe anaemia in children and pregnant and non-pregnant women for 1995–2011: a systematic analysis of population-representative data. Lancet Glob Health 1, e16e25.CrossRefGoogle ScholarPubMed
Kumar, SB, Arnipalli, SR, Mehta, P, et al. (2022) Iron deficiency anemia: efficacy and limitations of nutritional and comprehensive mitigation strategies. Nutrients 14, 2976.CrossRefGoogle ScholarPubMed
Seo, H, Yoon, SY, Ul-Haq, A, et al. (2023) The effects of iron deficiency on the gut microbiota in women of childbearing age. Nutrients 15, 691.CrossRefGoogle ScholarPubMed
Zakrzewska, Z, Zawartka, A, Schab, M, et al. (2022) Prebiotics, probiotics, and postbiotics in the prevention and treatment of anemia. Microorganisms 10, 1330.CrossRefGoogle ScholarPubMed
Goodnough, LT, Nemeth, E & Ganz, T (2010) Detection, evaluation, and management of iron-restricted erythropoiesis. Blood 116, 47544761.CrossRefGoogle ScholarPubMed
Vonderheid, SC, Tussing-Humphreys, L, Park, C, et al. (2019) A systematic review and meta-analysis on the effects of probiotic species on iron absorption and iron status. Nutrients 11, 2938.CrossRefGoogle ScholarPubMed
Korčok, DJ, Tršić-Milanović, NA, Ivanović, ND, et al. (2018) Development of probiotic formulation for the treatment of iron deficiency anemia. Chem Pharm Bull (Tokyo) 66, 347352.CrossRefGoogle ScholarPubMed
Rusu, IG, Suharoschi, R, Vodnar, DC, et al. (2020) Iron supplementation influence on the gut microbiota and probiotic intake effect in iron deficiency-a literature-based review. Nutrients 12, 1993.CrossRefGoogle ScholarPubMed
Bazeley, JW & Wish, JB (2022) Recent and emerging therapies for iron deficiency in anemia of CKD: a review. Am J Kidney Dis 79, 868876.CrossRefGoogle ScholarPubMed
Kumar, A, Sharma, E, Marley, A, et al. (2022) Iron deficiency anaemia: pathophysiology, assessment, practical management. BMJ Open Gastroenterol 9, e000759.CrossRefGoogle ScholarPubMed
Gómez-Ramírez, S, Brilli, E, Tarantino, G, et al. (2018) Sucrosomial® iron: a new generation iron for improving oral supplementation. Pharmaceuticals (Basel) 11, 97.CrossRefGoogle ScholarPubMed
Auerbach, M & Adamson, JW (2016) How we diagnose and treat iron deficiency anemia. Am J Hematol 91, 3138.CrossRefGoogle ScholarPubMed
Tolkien, Z, Stecher, L, Mander, AP, et al. (2015) Ferrous sulfate supplementation causes significant gastrointestinal side-effects in adults: a systematic review and meta-analysis. PLoS One 10, e0117383.CrossRefGoogle ScholarPubMed
Deschemin, JC, Noordine, ML, Remot, A, et al. (2016) The microbiota shifts the iron sensing of intestinal cells. FASEB J 30, 252261.CrossRefGoogle ScholarPubMed
Jaeggi, T, Kortman, GA, Moretti, D, et al. (2015) Iron fortification adversely affects the gut microbiome, increases pathogen abundance and induces intestinal inflammation in Kenyan infants. Gut 64, 731742.CrossRefGoogle ScholarPubMed
Hoppe, M, Önning, G, Berggren, A, et al. (2015) Probiotic strain lactobacillus plantarum 299v increases iron absorption from an iron-supplemented fruit drink: a double-isotope cross-over single-blind study in women of reproductive age. Br J Nutr 114, 11951202.CrossRefGoogle ScholarPubMed
Skrypnik, K, Bogdański, P, Schmidt, M, et al. (2019) The effect of multispecies probiotic supplementation on iron status in rats. Biol Trace Elem Res 19, 234243.CrossRefGoogle Scholar
Wells, JM (2011) Immunomodulatory mechanisms of lactobacilli. Microb Cell Fact 10, S17.CrossRefGoogle ScholarPubMed
Goossens, D, Jonkers, D, Russel, M, et al. (2005) Survival of the probiotic, L. plantarum 299v and its effects on the faecal bacterial flora, with and without gastric acid inhibition. Dig Liver Dis 37, 4450.CrossRefGoogle ScholarPubMed
Ducrotté, P, Sawant, P & Jayanthi, V (2012) Clinical trial: lactobacillus plantarum 299v (DSM 9843) improves symptoms of irritable bowel syndrome. World J Gastroenterol 18, 40124018.CrossRefGoogle ScholarPubMed
Niedzielin, K, Kordecki, H & Birkenfeld, B (2001) A controlled, double-blind, randomized study on the efficacy of Lactobacillus plantarum 299V in patients with irritable bowel syndrome. Eur J Gastroenterol Hepatol 13, 11431147.CrossRefGoogle Scholar
Bering, S, Sjøltov, L, Wrisberg, SS, et al. (2007) Viable, lyophilized lactobacilli do not increase iron absorption from a lactic acid-fermented meal in healthy young women, and no iron absorption occurs in the distal intestine. Br J Nutr 98, 991997.CrossRefGoogle Scholar
Scheers, N, Rossander-Hulthen, L, Torsdottir, I, et al. (2016) Increased iron bioavailability from lactic-fermented vegetables is likely an effect of promoting the formation of ferric iron (Fe(3+)). Eur J Nutr 55, 373382.CrossRefGoogle ScholarPubMed
Şahin, K, Şahintürk, Y, Köker, G, et al. (2022) Metformin with v. without concomitant probiotic therapy in newly diagnosed patients with type 2 diabetes or prediabetes: a comparative analysis in relation to glycemic control, gastrointestinal side effects, and treatment compliance. Turk J Gastroenterol 33, 925933.CrossRefGoogle ScholarPubMed
Çekin, AH, Şahintürk, Y, Akbay Harmandar, F, et al. (2017) Use of probiotics as an adjuvant to sequential H. pylori eradication therapy: impact on eradication rates, treatment resistance, treatment-related side effects, and patient compliance. Turk J Gastroenterol 28, 311.CrossRefGoogle Scholar
Endo, H, Higurashi, T, Hosono, K, et al. (2011) Efficacy of Lactobacillus casei treatment on small bowel injury in chronic low-dose aspirin users: a pilot randomized controlled study. J Gastroenterol 46, 894905.CrossRefGoogle ScholarPubMed
Asemi, Z, Bahmani, S, Shakeri, H, et al. (2015) Effect of multispecies probiotic supplements on serum minerals, liver enzymes and blood pressure in patients with type 2 diabetes. Int J Diabetes Dev Ctries 35, 9095.CrossRefGoogle Scholar
Axling, U, Önning, G, Martinsson Niskanen, T, et al. (2021) The effect of Lactiplantibacillus plantarum 299v together with a low dose of iron on iron status in healthy pregnant women: a randomized clinical trial. Acta Obstet Gynecol Scand 100, 16021610.CrossRefGoogle ScholarPubMed
OjiNjideka Hemphill, N, Pezley, L, Steffen, A, et al. (2023) Feasibility study of Lactobacillus Plantarum 299v probiotic supplementation in an urban academic facility among diverse pregnant individuals. Nutrients 15, 875.CrossRefGoogle Scholar
Buttarello, M, Pajola, R, Novello, E, et al. (2016) Evaluation of the hypochromic erythrocyte and reticulocyte hemoglobin content provided by the Sysmex XE-5000 analyzer in diagnosis of iron deficiency erythropoiesis. Clin Chem Lab Med 54, 19391945.CrossRefGoogle ScholarPubMed
Kulich, KR, Madisch, A, Pacini, F, et al. (2008) Reliability and validity of the Gastrointestinal Symptom Rating Scale (GSRS) and Quality of Life in Reflux and Dyspepsia (QOLRAD) questionnaire in dyspepsia: a six-country study. Health Qual Life Outcomes 6, 12.CrossRefGoogle ScholarPubMed
Burrowes, JD, Powers, SN, Cockram, DB, et al. (1996) Use of an appetite and diet assessment tool in the pilot phase of a hemodialysis clinical trial: mortality and morbidity in hemodialysis study. J Renal Nutr 6, 229232.CrossRefGoogle Scholar
Kujawa-Szewieczek, A, Adamczak, M, Kwiecień, K, et al. (2015) The effect of lactobacillus plantarum 299v on the incidence of clostridium difficile infection in high risk patients treated with antibiotics. Nutrients 7, 1017910188.CrossRefGoogle ScholarPubMed
Kaźmierczak-Siedlecka, K, Daca, A, Folwarski, M, et al. (2020) The role of Lactobacillus plantarum 299v in supporting treatment of selected diseases. Cent Eur J Immunol 45, 488493.CrossRefGoogle ScholarPubMed
Sandberg, AS, Önning, G, Engström, N, et al. (2018) Iron supplements containing Lactobacillus Plantarum 299v increase ferric iron and up-regulate the ferric reductase DCYTB in human Caco-2/HT29 MTX co-cultures. Nutrients 10, 1949.CrossRefGoogle Scholar
Jaramillo, Á, Briones, L, Andrews, M, et al. (2015) Effect of phytic acid, tannic acid and pectin on fasting iron bioavailability both in the presence and absence of calcium. J Trace Elem Med Biol 30, 112117.CrossRefGoogle ScholarPubMed
Liu, H, Wu, W & Luo, Y (2023) Oral and intravenous iron treatment alter the gut microbiome differentially in dialysis patients. Int Urol Nephrol 55, 759767.CrossRefGoogle ScholarPubMed
Serati, M & Torella, M (2019) Preventing complications by persistence with iron replacement therapy: a comprehensive literature review. Curr Med Res Opin 35, 10651072.CrossRefGoogle ScholarPubMed
Finlayson-Trick, EC, Fischer, JA, Goldfarb, DM, et al. (2020) The effects of iron supplementation and fortification on the gut microbiota: a review. Gastrointest Disord 2, 327340.CrossRefGoogle Scholar
Richards, T, Breymann, C, Brookes, MJ, et al. (2021) Questions and answers on iron deficiency treatment selection and the use of intravenous iron in routine clinical practice. Ann Med 53, 274285.CrossRefGoogle ScholarPubMed
Bering, S, Suchdev, S, Sjøltov, L, et al. (2006) A lactic acid-fermented oat gruel increases non-haem iron absorption from a phytate-rich meal in healthy women of childbearing age. Br J Nutr 96, 8085.CrossRefGoogle ScholarPubMed
Hurrell, RF (2012) Influence of inflammatory disorders and infection on iron absorption and efficacy of iron-fortified foods. Nestle Nutr Inst Workshop Ser 70, 107116.CrossRefGoogle Scholar
Suchdev, PS, Williams, AM, Mei, Z, et al. (2017) Assessment of iron status in settings of inflammation: challenges and potential approaches. Am J Clin Nutr 106, 1626S1633S.CrossRefGoogle Scholar
Axling, U, Önning, G, Combs, MA, et al. (2020) The effect of Lactobacillus plantarum 299v on iron status and physical performance in female iron-deficient athletes: a randomized controlled trial. Nutrients 12, 1279.CrossRefGoogle ScholarPubMed
Fikri, B, Ridha, NR, Putri, SH, et al. (2022) Effects of probiotics on immunity and iron homeostasis: a mini-review. Clin Nutr ESPEN 49, 2427.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Patient demographics, intolerance development and treatment discontinuation (Numbers and percentages; mean values and sd)

Figure 1

Table 2. Intolerance symptoms at baseline and during 3 months of IRT in study groups (Numbers and percentages)

Figure 2

Table 3. Serum iron status markers from baseline to 3rd month of iron replacement therapy (Median values and interquartile ranges)

Figure 3

Table 4. Patient demographics and baseline serum iron status markers according to treatment discontinuation within 30 d (Mean values and sd; median values and minimum and maximum values)