Prophylactic antibiotics to reduce pelvic infection in women having miscarriage surgery – The AIMS (Antibiotics in Miscarriage Surgery) trial: Study protocol for a randomized controlled trial

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Study Justification:
– Miscarriage surgery is a common operation performed in hospitals, particularly in low-income countries.
– Infection following miscarriage surgery is a serious consequence and can lead to serious illness and death.
– Good quality evidence on the use of prophylactic antibiotics for surgical miscarriage management is lacking.
– Prophylactic antibiotics may offer a simple and affordable intervention to improve outcomes.
Study Highlights:
– The study aims to determine whether a single dose of oral doxycycline and metronidazole taken before miscarriage surgery can reduce the incidence of pelvic infection within 2 weeks after surgery.
– The study will also assess the impact of prophylactic antibiotics on maternal mortality, duration of clinical symptoms, hospital admission, unplanned consultations, and overall antibiotic use.
– Subgroup analyses will explore the differential effects of antibiotic prophylaxis in various patient groups.
– An economic evaluation will be conducted to determine the cost-effectiveness of prophylactic antibiotics.
Study Recommendations for Lay Reader and Policy Maker:
– Prophylactic antibiotics may be a simple and affordable intervention to reduce the risk of infection following miscarriage surgery.
– The study findings will provide important evidence on the effectiveness and cost-effectiveness of prophylactic antibiotics in improving outcomes for women undergoing miscarriage surgery.
– Policy makers should consider implementing the use of prophylactic antibiotics in surgical miscarriage management based on the study results.
Key Role Players Needed to Address Recommendations:
– Researchers and clinicians involved in the study
– Healthcare providers and hospitals performing miscarriage surgery
– Policy makers and government health departments
Cost Items to Include in Planning the Recommendations:
– Antibiotics (doxycycline and metronidazole)
– Other medications related to pain, allergy, diarrhea, vomiting, nausea, malaria, and fever
– Inpatient stays, outpatient visits, and laboratory examinations
– Treatment of relevant complications (e.g., blood transfusion, repeat uterine evacuation, anaphylaxis)
– Costs of data collection and analysis
– Costs of implementing and monitoring the use of prophylactic antibiotics in surgical miscarriage management

The strength of evidence for this abstract is 7 out of 10.
The evidence in the abstract is strong, but there are some areas for improvement. The study protocol is well-described, and the objectives and outcomes are clearly stated. However, the abstract could provide more information on the study design, sample size calculation, and statistical analysis plan. Additionally, it would be helpful to include information on the potential limitations of the study and how they will be addressed. To improve the evidence, the abstract could provide more details on the randomization process, blinding procedures, and data collection methods. Furthermore, it would be beneficial to include information on the expected timeline for the study and any potential challenges that may arise. Overall, the evidence in the abstract is promising, but providing more information on these aspects would strengthen it further.

Background: The estimated annual global burden of miscarriage is 33 million out of 210 million pregnancies. Many women undergoing miscarriage have surgery to remove pregnancy tissues, resulting in miscarriage surgery being one of the most common operations performed in hospitals in low-income countries. Infection is a serious consequence and can result in serious illness and death. In low-income settings, the infection rate following miscarriage surgery has been reported to be high. Good quality evidence on the use of prophylactic antibiotics for surgical miscarriage management is not available. Given that miscarriage surgery is common, and infective complications are frequent and serious, prophylactic antibiotics may offer a simple and affordable intervention to improve outcomes. Methods: Eligible patients will be approached once the diagnosis of miscarriage has been made according to local practice. Once informed consent has been given, participants will be randomly allocated using a secure internet facility (1:1 ratio) to a single dose of oral doxycycline (400 mg) and metronidazole (400 mg) or placebo. Allocation will be concealed to both the patient and the healthcare providers. A total of 3400 women will be randomised, 1700 in each arm. The medication will be given approximately 2 hours before surgery, which will be provided according to local practice. The primary outcome is pelvic infection 2 weeks after surgery. Women will be invited to the hospital for a clinical assessment at 2 weeks. Secondary outcomes include overall antibiotic use, individual components of the primary outcome, death, hospital admission, unplanned consultations, blood transfusion, vomiting, diarrhoea, adverse events, anaphylaxis and allergy, duration of clinical symptoms, and days before return to usual activities. An economic evaluation will be performed to determine if prophylactic antibiotics are cost-effective. Discussion: This trial will assess whether a single dose of doxycycline (400 mg) and metronidazole (400 mg) taken orally 2 hours before miscarriage surgery can reduce the incidence of pelvic infection in women up to 2 weeks after miscarriage surgery.

The primary objective is to test the hypothesis that, in women having miscarriage surgery, pre-surgery prophylactic antibiotics (oral doxycycline 400 mg and oral metronidazole 400 mg) reduce the risk of pelvic infection within 14 days of surgery. In cases where participants do not return for follow-up within this period, follow-up until 28 days will be acceptable. The secondary objectives are to test whether prophylactic antibiotics result in a reduction in maternal mortality, duration of clinical symptoms, hospital admission, unplanned consultations and overall antibiotic use. We will also examine the individual components of the primary outcome and test the hypothesis that prophylactic antibiotics, compared to placebo, do not incur serious adverse effects to the mother. We will explore differential effects of antibiotic prophylaxis in the subgroups of (1) type of surgery (manual vacuum aspiration, suction curettage or sharp curettage), (2) type of miscarriage (incomplete or missed), (3) gestational age ( 38.0 °C, (4) uterine tenderness on examination and (4) a white cell count > 12 × 109/L [14], with no other recognised cause of infection upon history taking and examination by the assessing clinician and/or study team (Table 1). Primary outcome measure ascertainment An amendment was made to these criteria, after recruitment commencement, but without reference to study data, as it was observed by the examining clinicians (who were blinded to treatment allocation) that, for some participants, whilst only a single feature of pelvic infection was present, the symptoms were of sufficient severity that, in their clinical judgement, there was a need to provide treatment. After discussion with the independent trial steering committee it was decided that the diagnostic criteria by which pelvic infection was defined should be adjusted. Following this amendment, pelvic infection was diagnosed if the patient had two or more of (1) purulent vaginal discharge, (2) pyrexia > 38.0 °C, (3) uterine tenderness on examination and (4) a white cell count > 12 × 109/L [16], with no other recognised cause of infection upon history taking and examination by the assessing clinician and/or study team, or one of the above features, with a clinically identified need to administer antibiotics for the treatment of presumed pelvic infection (Table 1: primary outcome measure ascertainment). The latter pragmatic criteria will be reported as the primary outcome, but the more specific strict clinical criteria for diagnosis of pelvic infection will also be clearly reported. In cases where participants do not return for follow-up within the specified period of 2 weeks, follow-up until 28 days will be acceptable. The secondary outcomes are overall general antibiotic use (not specifically for pelvic infection), each component of the primary outcome, death, hospital admission, unplanned consultations, blood transfusion, vomiting, diarrhoea, adverse events, anaphylaxis and allergy, duration of clinical symptoms (pain, additional analgesia, vaginal bleeding), and days before return to usual daily activities. We are proactively seeking evidence of adverse events. Each participant will be asked, at each trial visit or interview, about hospitalisations, consultations with other medical practitioners, disability or incapacity, or any other adverse events. The analysis will be by intention-to-treat. The risk ratio of women with pelvic infection in the active arm to the placebo arm will be calculated. This estimate will be adjusted for the minimisation variables although an unadjusted estimate will also be calculated as a sensitivity analysis. In the first instance, analysis will be completed on received data only, with every attempt made to gather data on all subjects randomised, irrespective of compliance with the treatment protocol. To test the robustness of this initial analysis with respect to any missing data, missing responses will be simulated using a multiple imputation approach as a sensitivity analysis. Further sensitivity analysis will be performed assuming all non-responders had a pelvic infection. Seven pre-specified subgroup analyses are planned to assess differential effects of antibiotic prophylaxis in (1) type of surgery (manual vacuum aspiration, suction curettage or sharp curettage; sharp curettage is associated with a higher incidence of pelvic infection when compared to suction curettage [3], so a greater effect of antibiotic prophylaxis may be seen in the sharp curettage group); (2) type of miscarriage (incomplete or missed; incomplete miscarriage may be associated with a higher incidence of pelvic infection when compared to missed miscarriage [3]); (3) gestational age (< 12 weeks or ≥ 12 weeks, when known; pregnancies of a greater gestational age may have a higher incidence of pelvic infection due to the additional complexities involved with the surgical procedure [3]); (4) HIV status (positive or negative, when results are available; participants that are HIV positive may be more likely to experience pelvic infection as they may be immunocompromised); (5) by time between administration of antibiotics and surgery (a reduced time interval between antibiotic administration and surgery, than that specified in the protocol, may result in a reduction in bio-availability and thus in effect reduction; the optimal maximum duration however is unclear); (6) by country and sites; and (7) rural or urban residence (the potential direction of effect is unclear in sub-group analyses (6) and (7)). We will randomise 3400 women in total, which will give 90% power to detect a relative risk reduction of 0.4 (an RR of 0.6) (type I error rate, P = 0.05). A meta-analysis of 18 studies of prophylactic antibiotics used for induced abortion surgery was conducted to inform these calculations and found a pooled RR of 0.60 (95% CI 0.48–0.74) for the reduction of pelvic infection. We calculated sample sizes to detect this size of difference using various scenarios for the baseline risk (varying from 3% to 10%). The best available data for pelvic infection rates specific to spontaneous miscarriage originate from studies in the UK and USA, demonstrating a risk of pelvic infection of up to 6%; the risk of pelvic infection is likely to be higher in low-income countries, yet even for a baseline risk of, the 5% sample size of 3400 will provide over 80% power to detect a difference in primary outcome. Further sensitivity analysis will be performed assuming all non-responders had a pelvic infection. Interim analyses of principal safety and effectiveness endpoints will be conducted on behalf of an independent Data Monitoring Committee (DMC). These will be considered together with a report of serious adverse events. A pragmatic approach to stopping rules was suggested by the DMC members with respect to interpreting the results of any interim analysis. Appropriate criteria of proof will therefore not be specified precisely, but an interim analysis difference equating to P < 0.001 (similar to a Haybittle–Peto boundary) may be needed to justify halting, or modifying, of the study prematurely. This criterion has the practical advantage that the exact number of interim analyses would be of little importance and there would only be minimal inflation of any overall type-I error rate regardless of how many interim analyses are performed, so no exact schedule needs to be proposed. The economic evaluation will determine the relative cost-effectiveness of antibiotic prophylaxis in the surgical management of miscarriage compared to the current practice without antibiotic prophylaxis. All resource use data will be prospectively collected using case report forms completed on at least one occasion prior to discharge after surgery, at every contact during the follow-up period, daily whilst an inpatient, and at final assessment. Resource use information will be employed to estimate the costs associated with the additional use of antibiotics in all participating centres. This will include antibiotics and other medications related to pain, allergy, diarrhoea, vomiting, nausea, malaria and fever as well as inpatient stays, outpatient visits, laboratory examinations and treatment of relevant complications, such as haemorrhage requiring blood transfusion, repeat uterine evacuation and anaphylaxis. Unit cost data will be obtained from the International Drug Price Indicator Guide [17], the World Health Organization (WHO-CHOICE) [16] and other secondary sources, and will be adjusted to 2016 US Dollars. Given the short time horizon, no discounting will be applied to costs. An incremental cost-effectiveness analysis will be conducted from a healthcare provider perspective based on the outcome of cost per pelvic infection avoided within 2 weeks from surgery using established health economic methods for multinational trials [18, 19]. The uncertainty around cost-effectiveness point estimates will be presented using a cost-effectiveness acceptability frontier [20]. Sensitivity analyses will be performed to explore the robustness of the study findings to plausible variations in key values. The Birmingham Clinical Trials Unit is responsible for the coordination of the trial; it is a fully registered UK Clinical Research Collaboration clinical trials unit, and provides a robust quality management system to ensure good practice in the conduct and statistical analysis of the project. The trial is being conducted in accordance with the ethical principles that have their origin in the Declaration of Helsinki, 1996, namely the principles of Good Clinical Practice. The trial was not initiated at each site before full approval from the UK Research Ethics Committee, and the respective national Research Ethics Committee and local regulatory bodies was received. All AIMS investigators are responsible for (1) maintaining the protocol of the trial as described in this document, (2) helping healthcare professionals to ensure the study participants receive appropriate care throughout the period of research enrolment, (3) protecting the integrity and confidentiality of clinical and other records and data that may be generated by the research, and (4) reporting any failures in these respects, adverse drug reactions and other events or suspected misconduct through the appropriate systems (Additional file 1). Accrual is monitored against set targets. If a centre is not meeting its recruitment targets then the Trial Management Group will work with the local Principal Investigator and team to identify barriers to recruitment and solutions to any problems. Communication between the centres will enable the spread of good practice and experience between sites. Follow-up requirements are carefully explained to each participant. Written information is also provided in the form of the “follow-up card” (Additional file 3). Trial participants are given multiple easy access routes to contact the research and clinical teams to report issues and seek advice and care. Women contacting the study or research team are reviewed promptly. Reimbursement for potential telephone and transport costs are offered to participants. Non-attendance at follow-up clinics prompts telephone calls or other means of contacting the participant, which are agreed at recruitment. If possible, contact is made with the participant prior to the clinic to provide them a reminder through, for example, telephone calls or SMS text messages to prompt the reporting of any infection or other adverse events and follow-up clinic attendance. Details about complaints are provided in the patient information sheet. Management of complaints is the responsibility of the local Principal Investigator and should follow any locally available procedures before reporting to the trial management group. Collected data are stored on secure computers. The necessary trial data is encrypted. Electronic data is backed up every 24 h to both local and remote media in encrypted format. Paper-based data (e.g. signed consent forms) are kept locked at each site. Individual participant information obtained as a result of this study is considered confidential. Each participant is allocated a unique study number at recruitment. All documents use this as the identifier. All data will be analysed and reported in summary format. No individual will be identifiable. The Trial Steering Committee provides overall supervision of the trial and ensures that it is being conducted in accordance with the principles of Good Clinical Practice and other relevant regulations. The DMC reviews the accruing trial data and assesses the safety data to make recommendations on whether the trial should continue, be modified or be terminated. In addition, the DMC also examines effectiveness data to determine if continuation of the trial is unethical, and examines the recruitment, loss to follow-up, compliance and protocol violation data to ascertain if continuation of the trial is futile.

One potential innovation to improve access to maternal health is the use of prophylactic antibiotics for women undergoing miscarriage surgery. The AIMS (Antibiotics in Miscarriage Surgery) trial is a randomized controlled trial that aims to assess whether a single dose of oral doxycycline and metronidazole taken before surgery can reduce the incidence of pelvic infection in women up to 2 weeks after miscarriage surgery. The trial will also evaluate secondary outcomes such as overall antibiotic use, maternal mortality, duration of clinical symptoms, hospital admission, and unplanned consultations. Additionally, an economic evaluation will be performed to determine the cost-effectiveness of prophylactic antibiotics in this context. The trial will be conducted in diverse hospitals across four countries, namely Malawi, Uganda, Tanzania, and Pakistan, which were selected based on the prevalence of miscarriage surgery and the importance of the clinical question in those countries.
AI Innovations Description
The recommendation to improve access to maternal health is to conduct the AIMS (Antibiotics in Miscarriage Surgery) trial. This trial aims to test the hypothesis that prophylactic antibiotics given before miscarriage surgery can reduce the risk of pelvic infection within 14 days of surgery. The trial will involve randomizing 3400 women undergoing surgical evacuation of the uterus for a spontaneous miscarriage. The participants will be allocated to receive either a single dose of oral doxycycline (400 mg) and metronidazole (400 mg) or a placebo. The primary outcome of the trial is the incidence of pelvic infection 2 weeks after surgery. Secondary outcomes include overall antibiotic use, maternal mortality, duration of clinical symptoms, hospital admission, unplanned consultations, and days before return to usual activities. An economic evaluation will also be performed to determine the cost-effectiveness of prophylactic antibiotics. The trial will be conducted in hospitals in low-income countries, where miscarriage surgery is common and infective complications are frequent and serious. The results of this trial will provide valuable evidence on the use of prophylactic antibiotics to improve outcomes in women undergoing miscarriage surgery.
AI Innovations Methodology
The AIMS (Antibiotics in Miscarriage Surgery) trial aims to assess the impact of prophylactic antibiotics on reducing pelvic infection in women undergoing miscarriage surgery. The study protocol involves randomizing eligible patients to receive either a single dose of oral doxycycline (400 mg) and metronidazole (400 mg) or a placebo, approximately 2 hours before surgery. The primary outcome is the incidence of pelvic infection 2 weeks after surgery. Secondary outcomes include overall antibiotic use, individual components of the primary outcome, death, hospital admission, unplanned consultations, and other factors related to the surgery and recovery. An economic evaluation will also be performed to determine the cost-effectiveness of prophylactic antibiotics.

To simulate the impact of these recommendations on improving access to maternal health, a methodology could involve the following steps:

1. Define the target population: Identify the specific population that would benefit from improved access to maternal health, such as women in low-income countries undergoing miscarriage surgery.

2. Identify the barriers to access: Determine the existing barriers that limit access to maternal health, such as lack of healthcare facilities, limited availability of trained healthcare providers, or financial constraints.

3. Develop interventions: Based on the findings from the AIMS trial and other relevant research, develop interventions that address the identified barriers to access. For example, if the trial shows that prophylactic antibiotics reduce the risk of pelvic infection, an intervention could involve implementing guidelines or protocols for the use of prophylactic antibiotics in miscarriage surgery.

4. Model the impact: Use mathematical modeling techniques to simulate the impact of the interventions on improving access to maternal health. This could involve estimating the number of cases of pelvic infection that could be prevented, the reduction in hospital admissions or complications, and the potential cost savings.

5. Validate the model: Validate the model by comparing the simulated results with real-world data, if available. This could involve conducting additional studies or analyzing existing data to assess the effectiveness of the interventions in improving access to maternal health.

6. Refine and implement the interventions: Based on the simulated results and validation, refine the interventions as necessary and develop an implementation plan. This could involve working with healthcare providers, policymakers, and other stakeholders to ensure the interventions are effectively implemented and integrated into existing healthcare systems.

By following this methodology, policymakers and healthcare providers can make informed decisions on implementing innovations, such as prophylactic antibiotics, to improve access to maternal health and ultimately reduce the burden of pelvic infection and other complications associated with miscarriage surgery.

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