Can probiotic gargles reduce post-tonsillectomy morbidity in adult patients? A pilot, triple-blind, randomised, controlled trial and feasibility study

M V Nasserallah; N M de Silva; V Tobin; W M Rozen; D J Hunter-Smith

doi:10.1017/S0022215122000743

. 2022 Mar 23;137(3):323–341. doi: 10.1017/S0022215122000743

Can probiotic gargles reduce post-tonsillectomy morbidity in adult patients? A pilot, triple-blind, randomised, controlled trial and feasibility study

M V Nasserallah ^1,^4,^✉, N M de Silva ¹, V Tobin ², W M Rozen ^3,⁴, D J Hunter-Smith ^3,⁴

PMCID: PMC9975764 PMID: 35317870

Abstract

Objective

This study aimed to determine the efficacy of probiotic gargles compared with placebo gargles on reducing post-tonsillectomy morbidity in adults.

Method

This was a triple-blind, randomised, controlled trial and feasibility study. Thirty adults underwent elective tonsillectomy and were randomly assigned to receive either probiotic or placebo gargles for 14 days after surgery. Daily pain scores and requirement of analgesia were measured for 14 days post-operatively. Secondary outcomes assessed probiotic safety and tolerability and the feasibility of the trial.

Results

The probiotic group experienced less pain at rest on day 2. However, the amount of oxycodone (5 mg) tablets used was greater in the probiotic group compared with placebo. There were no statistically significant differences in the frequency of adverse effects between both groups. This trial was feasible.

Conclusion

This pilot study suggested that probiotic gargles do not reduce post-tonsillectomy pain or bleeding, highlighting the importance of pilot and feasibility studies in clinical research.

Key words: Tonsillectomy, Postoperative Complications, Hemorrhage, Analgesia, Pilot Projects, Feasibility Studies, Randomized Controlled Trial, Double-Blind Method, Probiotics, Microbiota

Introduction

Over 30 000 tonsillectomies are performed annually in Australia, making it one of the most commonly performed procedures in otolaryngology head and neck surgery.^1,2 Despite advances in surgical techniques and peri-operative management, post-tonsillectomy morbidity continues to burden patients and the health system.^3,4 Pain and secondary haemorrhage (bleeding occurring more than 24 hours after surgery) are the most common and significant causes of post-tonsillectomy morbidity.⁵ Post-operative pain is commonly experienced by all patients and can persist for several weeks. Post-tonsillectomy pain often results in time off work, an inability to resume normal diet and a requirement of opiate analgesics. Furthermore, the incidence of secondary haemorrhage varies from 2–40 per cent⁶ and may result in additional morbidity in the form of readmission, blood transfusion and return to the operating theatre for haemostasis.³

Post-tonsillectomy morbidity is a significant health issue worldwide. Countries such as Sweden, the UK and the USA have noted steadily increasing rates of unplanned readmission following surgery.^7–9 Unplanned or unexpected readmissions after surgery are an important metric to assess the quality and efficiency of admitted patient care in public hospitals.¹ In Australia, tonsillectomy and adenoidectomy surgery is the most common procedure leading to unplanned readmissions (see Figure 1).¹ In 2018 to 2019, 40 out of every 1000 tonsillectomy and adenoidectomy procedures performed in public hospitals were followed by unplanned readmission within 28 days.¹ This rate has significantly increased since 2007 to 2008 when the rate was 26 per 1000 operations.¹⁰ In addition, the annual cost of unplanned hospital readmissions is estimated to be approximately A$1.5 billion nationally.¹¹ Thus, the resultant economic and social costs of post-tonsillectomy morbidity are substantial. Furthermore, adults experience significantly more post-tonsillectomy morbidity than paediatric patients.^9,12 Therefore, interventions to reduce revisits for acute pain and haemorrhage in adults should be explored.

Fig. 1. — Unplanned readmissions per 1000 hospitalisations for selected procedures (2018–19). Taken with permission from Australian Institute of Health and Welfare 2020.¹

Tonsillectomy produces an open wound that heals by secondary intention.^13,14 This process increases the risk of developing pain and secondary haemorrhage. There are various theories behind the aetiology of post-operative pain in tonsillectomies; however, it appears to be multifactorial. Nerve irritation, inflammation and pharyngeal muscle spasm have been proposed as the underlying mechanisms responsible for this complication of tonsillectomy.^13,14 Therefore, anything that elicits any of these three factors will worsen pain caused by tonsillectomy. Furthermore, secondary haemorrhage is caused by retraction and sloughing of the primary eschar tissue covering the healing tonsillar bed with the concomitant formation of new blood vessels. This usually occurs between day 5 and 14.^3,14 Many factors influence post-tonsillectomy pain and haemorrhage,^6,14,15 and the available literature examining these factors is extensive.

Although the aetiology of post-tonsillectomy pain and bleeding appears to be multifactorial, post-operative infection has been proposed as a significant contributing factor to post-operative pain and bleeding.^14,16,17 In the first 24–48 hours after surgery, the colonisation and subsequent infection of the surgical site with oral commensals further compounds the inflammatory response and may worsen pain and bleeding risk.¹⁴ However, antibiotics have not demonstrated a consistent, clinically significant effect in reducing the incidence of post-operative pain or bleeding.³

Numerous studies have explored various surgical and non-surgical factors that influence post-tonsillectomy morbidity. However, the use of probiotic gargles to reduce post-tonsillectomy morbidity is a novel idea. Probiotics are live micro-organisms that, when administered in adequate amounts, confer health benefits on the host (International Scientific Association for Probiotics and Prebiotics in conjunction with the Food and Agriculture Organization of the United Nations and the World Health Organization).¹⁸ The role of beneficial bacteria on human health evolved from the work of Nobel prize laureate Elie Metchnikoff in 1908, in which he investigated the longevity and general health of a population of peasants residing in Bulgaria who consumed primarily fermented dairy products.¹⁹ Metchnikoff introduced the idea that lactic acid bacteria in yoghurt may counteract harmful gut pathogens and be the reason for this population's increased life-expectancy.¹⁹

It is now understood that the human body accommodates a very diverse and abundant collection of micro-organisms.^20,21 These micro-organisms outweigh the number of human cells by a ratio of 10:1.²² Additionally, there is considerable diversity in the microbiota between body sites (e.g. oral cavity, gastrointestinal tract, skin and vagina), with each performing specific functions beneficial to the host.²³ In 2001, Nobel prize laureate Joshua Lederberg coined the term ‘microbiome’, referring to the ecosystem of symbiotic, commensal and pathogenic microorganisms that reside in the human body.²⁴ The human microbiome is composed of all the genes isolated from microorganisms (bacteria, viruses and fungi) that reside on or within human tissues and biofluids.²⁴ The total number of genes in the microbiome is approximately 200-fold that of the human genome.²² Therefore, it is clear that symbiosis with these micro-organisms seems to be a condition for survival.²⁴

The human microbiome is influenced by a host of endogenous and exogenous factors. These include genetics, diet, antibiotics, smoking, alcohol consumption, socioeconomic status and pregnancy.²⁰ Any disruption in the human microbiome, also known as dysbiosis, may alter the normal function of that organ and result in disease.²² Therefore, a logical management approach to situations that alter our microbiota would be to deliberately increase our association with specific non-pathogenic organisms to maintain microbial homeostasis.

Our understanding of the structure and function of the human microbiome in both diseased and healthy states has significantly improved with the development of new gene-sequencing techniques. These innovative genomic technologies, such as shotgun metagenomics and next-generation sequencing techniques, have vastly revolutionised the throughput and accuracy of DNA sequencing of the microbiome in human samples compared with conventional culture-based detection methods.^20,25 As a result, the body of scientific literature to support the use of probiotics to maintain human health and prevent disease has exponentially risen over the past 20 years.²¹

The Streptococcus salivarius K12 probiotic strain has demonstrated an ability to reduce the growth of pathogenic organisms commonly implicated in upper respiratory tract infections.^26,27 Furthermore, in vitro and in vivo studies have also demonstrated that the K12 strain possesses immunomodulatory and anti-inflammatory properties that can upregulate the human body's innate immune response and concomitantly suppress the release of pro-inflammatory cytokines.^28,29 Therefore, the use of a probiotic strain that is native to the oral cavity, such as S salivarius K12, may reduce post-tonsillectomy morbidity.

This pilot and feasibility study was the first trial exploring the role of probiotics in reducing post-tonsillectomy morbidity. The efficacy of a 14-day course of probiotic (S salivarius K12) gargles in reducing adult post-tonsillectomy morbidity was compared with placebo gargles. The hypothesis was that this was a feasible trial and that probiotic gargles were safe, tolerable and would reduce post-tonsillectomy pain and bleeding. Finally, an ancillary analysis comparing gargles versus no gargles (using data from a similar study³⁰) was conducted to explore whether the act of gargling itself can reduce post-tonsillectomy pain.

Materials and methods

Study design

This study was a pilot, prospective, triple-blind, randomised, controlled trial and feasibility study. The trial was performed at a single-centre (Frankston Hospital, Australia) between October 2019 and February 2021 in an adult population (aged 18–55 years), with a parallel group study design using an allocation ratio of 1:1.

All procedures contributing to this work complied with the ethical standards of the Australian guidelines. This study was approved by the human research ethics committee of Peninsula Health (protocol number: HREC/51745/PH-2019) and the Department of Health and Ageing, Therapeutic Goods Administration (trial number: CT-2019-CTN-03230-1). The trial was registered with the Australian New Zealand Clinical Trials Registry (trial identification number: ACTRN12619001474145) and was performed according to the Consolidated Standards of Reporting Trials 2010 extension to randomised pilot and feasibility trials. The investigation complied with the Helsinki Declaration of 1975, as revised in 2008. Screening, recruitment and study retention for this study is summarised in a consort diagram (Figure 2).

Fig. 2. — Consolidated Standards of Reporting Trials Flow diagram. Thirty patients were recruited and divided into each arm, with no dropouts.

Eligibility and selection of participants

All participants were adult patients scheduled for elective tonsillectomy or adenotonsillectomy on the ENT surgical waiting list at Frankston Hospital. Pre-operatively, 38 patients were interviewed in the out-patient clinic by the operating surgeon from October 2019 to February 2021.

Patients were selected only if they satisfied the inclusion criteria. Patients included were aged 18–55 years, weighed more than 50 kg, and were scheduled to undergo either tonsillectomy or adenotonsillectomy, with indications for surgery being tonsillar hypertrophy, asymmetrical tonsillar enlargement, recurrent tonsillitis or previous quinsy.

The exclusion criteria for this trial included: allergies to non-steroidal anti-inflammatory drugs, opioids, codeine, oxycodone or paracetamol; lactose intolerance; unstable metabolic diseases or disorder; history of endocarditis; immunocompromised patients; kidney, liver or cardiovascular disease; haemorrhagic diathesis; requirement for other concomitant surgical procedures; recent use of probiotics within one month; patients taking regular non-steroidal anti-inflammatory drugs, paracetamol or opiates; and women who were pregnant, nursing or trying to conceive. Eight patients were excluded as they did not satisfy these criteria.

Informed consent

Informed consent was obtained by the participant signing the patient information and consent form at the pre-operative visit before surgery.

Operative method

Thirty participants were recruited and randomly assigned to each study arm (15 patients per group). A single experienced surgeon performed all operations under general anaesthesia with the use of orotracheal intubation. Tonsillectomy with or without adenoidectomy was performed with the use of the Boyle–Davis mouth gag. The post-nasal space was inspected and adenoidectomy was performed, if clinically necessary, using curettage or a suction diathermy device at 25 W (using a Valleylab Force FX^™ Electrosurgical Generator C). Tonsils were then removed using electrocautery, with monopolar diathermy set at 15 W for dissection and bipolar cautery set at 12 W for haemostasis. On induction of general anaesthesia, all patients received a single dose of 1.2 g of intravenous (IV) benzylpenicillin (or 600 mg of IV clindamycin if allergic) to reduce the risk of bacteraemia and eliminate the presence of pathogenic organisms.³¹ Furthermore, antibiotic pre-treatment is used to eliminate pathogenic pathogens, allowing live therapeutic bacteria to colonise the target site better when using probiotics.³² Peri-operative parecoxib and dexamethasone were used for all patients to reduce pain and improve recovery in the immediate post-operative period.³³

Peri-operative care

After surgery, patients were transferred to the post-anaesthesia care unit for monitoring and then moved to the ward once they were awoken and deemed safe. During the post-operative period, patients received regular analgesics, with allowance for oral oxycodone for breakthrough pain relief, ondansetron and metoclopramide as antiemetics and other medications as deemed necessary.

Randomisation and blinding

Prior to the study's commencement, the trial pharmacist generated a randomised order that dictated the allocation of the trial intervention (probiotic powder) and placebo (isomalt powder) to the recruited participants in chronological order. This order was generated using the randomisation function in Microsoft Excel® spreadsheet software. Block randomisation was used with a predetermined ratio of 1:1 for the 30 participants. Once a patient was identified as eligible to participate in the trial by the study investigator, the patient's details were provided to the trial pharmacist. Each trial participant was then given a trial pack (which contained the probiotic or placebo) and was allocated a unique identification number (1 to 30) by the pharmacist packaging the medication. The pharmacist was the only person who had information on what product each patient was receiving until the completion of data collection.

Patients were allocated to either probiotic gargles or placebo gargle groups according to the generated randomisation schedule. The probiotic BLIS K12 Daily Defence Junior powder (containing 125 million colony forming units per scoop of S salivarius K12; BLIS Technologies, Dunedin, New Zealand) and placebo powder (isomalt) were identical in appearance and taste. They were pre-packed in identical bottles and consecutively labelled with a unique identification number for each participant according to the randomisation schedule. The allocation sequence and bottle contents were concealed from the investigator enrolling and assessing participants.

This information was kept in sealed envelopes, stored in a locked cupboard in the hospital pharmacy. The investigators, participants and statistician were all blinded to the allocation process.

Post-operative care and instructions

After morning breakfast, all participants were discharged home with regular medications and the trial intervention (probiotic gargles or placebo gargles). Study medications were distributed by an independent pharmacist at the hospital with no clinical involvement in the study. Patients were advised to dissolve two pre-measured scoops of the trial powder into 20 ml of warm water, gargle for 30 seconds and then swallow. Participants were instructed to gargle 4 times a day for 14 days, ideally 30 minutes after brushing teeth and before meals. Regularly prescribed medications consisted of 1 g of paracetamol (4 times a day for 10–14 days), 5–10 mg of oxycodone (4-hourly as required for rescue analgesia), 10 mg of metoclopramide (3 times a day as needed for nausea and vomiting) and aperients as needed. Participants were also advised to consume regular rough textured foods, coordinate analgesia consumption approximately 30–60 minutes before meals and avoid strenuous activity two weeks after surgery.

Daily questionnaires and follow up

Participants were sent an electronic survey (daily 14-day questionnaire) to their mobile or e-mail via SurveyMonkey® daily (see Appendix 1). This questionnaire was specifically designed for this trial but was adapted from a similar study using a paper form.³⁰ Alternatively, a paper form of the diary (see Appendix 2) was provided to the participant if they did not have access to mobile or e-mail. Only one participant preferred completing the paper form of the diary.

Patients were followed up on days 5, 14 and 28 post-operatively. Day 14 and day 28 out-patient visits were conducted in person at Frankston hospital, and patients were followed up via telephone on day 5. On day 14, participants returned any unused powder from the trial intervention, which was delivered to and weighed by the trial pharmacist to measure compliance. If a participant required additional information or analgesia, they were advised to speak to the study investigator at any time from day 1 to day 28 after surgery.

Coronavirus disease 2019 precautions

As a result of coronavirus disease 2019 (Covid-19) restrictions on trial continuity and trial protocols, the following amendments were made. (1) Day 5 follow-up was via telephone as per protocol. (2) Day 14 and day 28 follow ups were in the out-patient clinic as per protocol. (3) Before the out-patient visit, the associate investigator contacted patients and asked if they had experienced any fever or respiratory symptoms, were close contacts with Covid-19 suspected or proven patients or if they had tested positive for Covid-19. (4) If patients had no risk factors, they were seen in the out-patient clinic as planned. The associate investigator wore gloves and mask and eye protection during the consultation and conducted appropriate hand hygiene. The patient was also advised to wear a mask and conduct appropriate hand hygiene. (5) At the end of the consultation, a disinfectant wipe was used to wipe down all surfaces contacted by the patient and the investigator, and appropriate hand hygiene was completed. (6) If the patient had any of the above risk factors, the associate investigator advised them to have a Covid-19 polymerase chain reaction swab test if they had not had one already and to remain self-isolated until the result was negative before reviewing them in the out-patient clinic. If this was not feasible, a telephone consultation was completed using the same questions from the day 5 telephone consultation. (7) If participants could not attend the out-patient clinic, they were advised to bring back the remaining powder to the pharmacy on day 14 as per protocol. If participants could not return unused medication themselves, a family member was asked to do so. Powder containers were handled with gloves and appropriate hand hygiene when returning to the trial pharmacist.

Outcomes measures

Primary outcome

The primary outcomes assessed were post-tonsillectomy pain and the requirement of opiate analgesia. Participants recorded average daily pain scores at rest and for drinking and eating over the preceding 24-hour period, with a numerical rating scale (0 being no pain to 10 being the worst pain experienced) for 14 days after surgery. Additionally, the daily requirement of paracetamol and opiate analgesics was recorded as the number of 500 mg tablets of paracetamol and 5 mg tablets of oxycodone (Endone®) that the participant consumed daily for 14 days after surgery. These outcomes were recorded using the ‘daily 14-day questionnaire’.

Secondary outcome

The secondary outcomes assessed the safety and tolerability of probiotics. The readmission rates because of pain or dehydration were recorded using hospital records. The rate of post-tonsillectomy haemorrhage was assessed using the ‘daily 14-day questionnaire’ and by examination of the participants’ hospital records. A four-point haemorrhage scale was used to categorise the severity of bleeding (1 = no bleeding; 2 = minimal bleeding less than a mouthful, managed at home with ice gargles; 3 = moderate bleeding, managed medically in hospital with gargle or silver nitrate cautery without blood transfusion requirement; 4 = profuse bleeding, requiring the operating theatre or needing a blood transfusion). The number of side effects experienced daily (e.g. nausea, vomiting, constipation, drowsiness, halitosis, abdominal pain) was also documented by participants in their ‘daily 14-day questionnaire’.

Feasibility measures

Design

The feasibility of the study's design was determined by examining the following factors: the ability and time required of study staff to coordinate recruitment, screening and clinic tasks; the ability of staff to contact participants; the duration of the initial phone call to participants; and the number of staff required for the initial recruitment phone call. Screening and clinic tasks were also assessed by recording the number of staff required and the duration (in minutes) of interviews at participant visits on day 5 (via phone), day 14 and day 28 (in the out-patient clinic).

Recruitment and screening

The ability to recruit and screen participants was assessed by measuring the time and people required to be screened to enrol 30 participants to completion of the final trial visit.

Randomisation

The balance of characteristics in each group determined the trial's ability to perform successful randomisation.

Adherence

Adherence in both groups was assessed by: the amount of probiotic or placebo gargle consumed as measured by participant diaries and bottle return, their attendance at follow-up appointments and their completion of daily questionnaires.

Safety

Safety was assessed by the number and description of serious adverse events (any admission to the emergency department or hospitalisation, life-threatening events or results in significant morbidity or death) and other adverse events. Serious adverse events (including haemorrhage requiring operative intervention or blood transfusion, readmission because of pain and dehydration or septicaemia) were adjudicated by an independent medical monitoring team (two independent ENT specialists) as either unrelated, possibly related, probably related or definitely related to trial intervention.

Retention

The study design was assessed for number of participants that withdrew in each treatment arm.

Ancillary analysis

An exploratory analysis comparing the effect of placebo gargles versus placebo tablets on pain scores and the requirement of analgesics post-tonsillectomy was also performed. A co-author of our study (NMdS) provided anecdotal evidence that probiotic gargles significantly reduced post-tonsillectomy pain. Therefore, this additional analysis was performed to delineate whether the act of gargling can reduce post-operative pain compared with no gargles. The raw data for participants who consumed placebo tablets from a recently published study was obtained with the author's permission.³⁰ This study was a double-blind, placebo-controlled, randomised, controlled trial conducted in the same setting (Peninsula Health) and utilised a similar study design as our trial. This earlier study explored the efficacy of celecoxib in reducing post-tonsillectomy pain compared with placebo. Pain scores were assessed using a numerical rating scale (0–10) and the requirement of oxycodone in both the amount of 5 mg tablets consumed and the number of days. Oxycodone was used in the placebo gargle and placebo tablet groups. However, as these outcomes were reported for only up to 10 days post-operatively in the celecoxib study, these outcomes from both groups (placebo gargles and placebo tablets) were assessed and compared for 10 days after surgery.

Statistical analysis

The statistician remained blinded to trial intervention allocation while performing the statistical analysis. Once data collection was complete, the pharmacist was notified to provide a list of the two separate treatment groups by their identification numbers without revealing which group was the intervention and the placebo. The excel spreadsheet data was de-identified by deleting each participant's name and unit record number and was henceforth identified only by the study identification number. As mentioned previously, the statistician performed the analysis on two groups of patients, without the knowledge of which group was allocated to the probiotic and which group was allocated to the placebo.

The collected data was entered into a Microsoft Excel® spreadsheet software before being imported into Stata (version 16, StataCorp, College Station, USA) for statistical analysis. The distribution of continuous data was determined using the Shapiro–Wilk test for normality. Normal data has been presented as mean ± standard deviation (SD) and non-normal as median (interquartile range). Comparisons of normally distributed continuous variables were made using t-tests or repeated measure analysis of variance (ANOVA) with Bonferroni post hoc tests. Continuous data that failed the Shapiro–Wilk test for normality were compared using the Wilcoxon Mann–Whitney or Kruskal–Wallis tests. Categorical or interval data have been presented as percentage frequency and assessed using Fisher's exact test. P-values less than 0.05 were assessed as statistically significant.

Results

Demographic data

From October 2019 to January 2021, 30 adult patients (18–55 years old) were enrolled in the study, with 15 in the probiotic group and 15 in the placebo group. There were no statistically significant differences between these treatment groups in demographic or surgical characteristics (Table 1), including age, sex, indication of surgery and surgery type (tonsillectomy vs adenotonsillectomy).

Table 1.

Demographic and surgical characteristics

Parameter	Probiotic	Placebo	P-value
Age (median (interquartile range); years)	30 (12)	25 (5)	0.31
Male (n (%))	3/15 (20)	1/15 (6.7)	0.30
Indication (n (%))			0.21
– Recurrent tonsillitis	12/15 (80)	9/15 (60)
– Tonsillolith	3/15 (20)	1/15 (6.7)
– Recurrent peritonsillar abscess	0	3/15 (20)
– Sleep-disordered breathing	0	1/15 (6.7)
– Asymmetric tonsillar hypertrophy	0	1/15 (6.7)
Surgery type (n (%))			0.43
– Tonsillectomy	9/15 (60)	12/15 (80)
– Adenotonsillectomy	6/15 (40)	3/15 (20)

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Pain scores

Post-operative pain scores during rest and eating and drinking were reported during the first 14 post-operative days (Figure 3). There was no statistically significant difference in pain scores at rest on each day (Figure 3a) except on day 2, with statistically significantly lower pain scores in the probiotic group (probiotic vs placebo, mean ± SD: 3.5 ± 1.8 vs 5 ± 2, respectively; p = 0.02 by repeated measures ANOVA). No statistically significant differences were observed in the daily pain scores while drinking (Figure 3b) or eating (Figure 3c). Although there was a trend for lower reported pain scores during the first five post-operative days at rest and for drinking and eating in the probiotic group compared with the placebo group (data pooled from days 1–5, data not shown), this difference was not significant.

Fig. 3. — Mean pain scores at (a) rest, (b) drinking and (c) eating from day 1 to day 14. *Only the mean pain score at rest on day 2 alone was statistically significantly lower in the probiotic group compared with the placebo group (mean ± standard deviation, probiotic versus placebo group: 3.5 ± 1.8 vs 5 ± 2, respectively; p = 0.02 by repeated measures analysis of variance).

Oxycodone use

The reported daily number of 5 mg oxycodone tablets (Figure 4a), total number of oxycodone tablets (Figure 4b) and the total number of days (Figure 4c) that oxycodone was used for each group over the post-operative 14 days were examined to provide an overall estimation for the requirement of analgesia.

Fig. 4. — (a) Daily mean number of oxycodone (Endone®) tablets used. (b) Median total number oxycodone tablets. (c) Mean total number of days oxycodone used day 1 to 14. *Mean number of oxycodone tablets used was statistically significantly higher in the probiotic group only on day 6 (probiotic vs placebo, mean ± SD: 4.4 ± 2.8 vs 3 ± 2.3, respectively; *p =* 0.03 by repeated measures analysis of variance). **Total number of oxycodone tablets used was statistically significantly higher in the probiotic group (probiotic group vs placebo median and interquartile range: 34 (31) vs 23 (27), respectively; *p =* 0.00 by Mann–Whitney test).

Although the average number of oxycodone tablets taken on day 6 was higher in the probiotic group compared with the placebo group (mean ± SD for number of oxycodone tablets used for probiotic vs placebo (day 6): 4.4 ± 2.8 vs 3 ± 2.3, respectively; p = 0.03 by repeated measures ANOVA), there were no statistically significant differences between the treatment groups detected on any other day (Figure 4a). The median total number of oxycodone (5 mg) tablets (Figure 4b) used was statistically significantly higher in the probiotic group compared with the placebo group (total number of oxycodone tablets used (day 1 to day 14, median (interquartile range): 34 (31) vs 23 (27), respectively; p = 0.00 by Wilcoxon Mann–Whitney test). Finally, there were no statistically significant differences (p = 0.14) in the mean total number of days that oxycodone was used between the groups, with the probiotic group using oxycodone for 9.8 ± 3.4 days (mean ± SD) compared with 7.9 ± 3.5 days in the placebo group (Figure 4c).

Paracetamol use

Although the daily average number of paracetamol tablets taken on days 8, 9 and 10 was statistically significantly higher in the probiotic group compared with the placebo group (amount of paracetamol used (mean ± SD) on day 8: 6.8 ± 1.8 vs 5.2 ± 2.7, p = 0.05; day 9: 6.8 ± 1.7 vs 4.9 ± 3.2, p = 0.02; and day 10: 5.5 ± 2.3 vs 3.9 ± 3, p = 0.04, respectively), there were no statistically significant differences on any other post-operative day (Figure 5a).

Fig. 5. — (a) Mean daily number of paracetamol tablets used, (b) median total number of paracetamol tablets used and (c) median total number of days paracetamol used. *Mean number of paracetamol used was statistically significantly higher in the probiotic group on days 8, 9 and 10 (probiotic vs placebo, mean ± SD: day 8: 6.8 ± 1.8 vs 5.2 ± 2.7, *p =* 0.05; day 9: 6.8 ± 1.7 vs 4.9 ± 3.2, *p =* 0.02; and day 10: 5.5 ± 2.3 vs 3.9 ± 3, *p =* 0.04 by repeated measures analysis of variance. **Total number of paracetamol tablets used day 1 to day 14 was statistically significantly higher in the probiotic group (median interquartile range for probiotic group vs placebo: 82 (32) vs 74 (38), respectively; *p =* 0.00 by Mann–Whitney test).

Both the total amount of 500 mg paracetamol tablets consumed (Figure 5b) and the total number of days paracetamol was used (Figure 5c) over the 14 days after surgery were also calculated to provide additional measures for the requirement of analgesia. The median total number of paracetamol (500 mg) tablets (Figure 5b) used was statistically significantly higher in the probiotic group compared with the placebo group (amount of total paracetamol used (day 1 to day 14), median (interquartile range): 82 (32) vs 74 (38), respectively; p = 0.00). However, there was no statistically significant difference in the median total number of days paracetamol was used between the two groups (Figure 5c).

Side effects

Participants recorded whether they experienced any of the following side effects daily: nausea, vomiting, diarrhoea, constipation, drowsiness, bleeding and bad breath. The total number of days of reported adverse effects are presented by group. There were no statistically significant differences in the total number of days that any of the side effects were reported between the probiotic and placebo groups (Figure 6).

Fig. 6. — Median total number of days the various adverse effects were reported. There were no statistically significant differences in the number of days that any of the side effects were reported between both groups.

Haemorrhage rates

The incidence of post-tonsillectomy haemorrhage using a four-point haemorrhagic scale was assessed over the 28 days post-surgery. No patients had a primary haemorrhage event (occurring equal to or less than 24 hours post-surgery). Six patients (3 in each treatment group) required readmission because of secondary haemorrhage but did not require operative intervention or blood transfusions (p = 1.00). There were no statistically significant differences between the two groups with respect to the frequency of the haemorrhage categories (p = 0.48; Table 2).

Table 2.

Post-tonsillectomy haemorrhage classification

Bleeding	Probiotic (n (%))	Placebo (n (%))	P-value
1 – None	10/15 (66.7)	7/15 (46.7)	0.48
2 – Minimal	2/15 (13.3)	5/15 (33.3)
3 – Moderate	3/15 (20)	3/15 (20)
4 – Profuse	0	0

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Readmission for pain or dehydration

The number of participants requiring admission because of pain or dehydration was assessed over the 28 days post-surgery. Only one patient in the trial was admitted with pain, and they had received the probiotic treatment (p = 1.00). This patient presented on day 6 with thick tonsillar slough in bilateral tonsillar fossa and 10 out of 10 pain. The thick slough was suctioned, and the patient was given two doses of 8 mg IV dexamethasone and discharged the same day.