Optimization of Sepsis Therapy Based on Patient-specific Digital Precision Diagnostics — DigiSep  

Sepsis Clinical Trial

Official title: Optimization of Sepsis Therapy Based on Patient-specific Digital Precision Diagnostics

Status Recruiting

Clinical Trial Summary

Sepsis is triggered by an infection and represents one of the greatest challenges of modern intensive care medicine. With regard to a targeted antimicrobial treatment strategy, the earliest possible pathogen detection is of crucial importance. Until now, culture-based detection methods represent the diagnostic gold standard, although they are characterized by numerous limitations. Culture-independent molecular diagnostic procedures may represent a promising alternative. In particular, the concept of plasmatic detection of circulating, free DNA employing next-generation sequencing (NGS) has shown to be suitable for the detection of disease-causing pathogens in patients with bloodstream infections. The DigiSep-Trial is a randomized, controlled, interventional, multicenter trial to characterize the effect of the combination of NGS-based digital precision diagnostics, standard-of-care microbiological analyses and optional expert exchanges compared to solely standard-of-care microbiological analyses in the clinical picture of sepsis / septic shock. The study examines in 410 patients (n = 205 per arm) with sepsis / septic shock whether the so-called DOOR-RADAR (Desirability of Outcome Ranking / Response Adjusted for Duration of Antibiotic Risk) score (representing a combined endpoint including the criteria (1) inpatient admission time, (2) consumption of antibiotics, (3) mortality and (4) acute renal failure (ARF)) can be significantly improved, by application of an additional NGS-based diagnostic concept. We also aim to investigate whether the new diagnostic procedure is cost-effective. It is postulated that the inpatient admission time, mortality rate, incidence of ARF, the duration of antimicrobial therapy as well as the costs of complications and outpatient aftercare can be reduced. Moreover, a significant improvement in the quality of life (QoL) of the affected patients can be expected. Extensive preparatory work suggests that NGS-based diagnostics have higher specificity and sensitivity compared to standard-of-care microbiological analyses for detecting bloodstream infections. This preliminary work for the DigiSep-Trial with the help of an interventional study design provides the optimal basis to establish this new concept as part of the national standard based on the best possible evidence.

Clinical Trial Description

Sepsis is a disease which is triggered by an infection and represents one of the greatest challenges of modern intensive care medicine. With regard to targeted anti-microbial therapy, the earliest possible pathogen detection is of crucial importance. Until now, culture-based detection methods represent the gold standard for diagnosis, although numerous limitations characterize these. In this context, culture-independent molecular biological processes are an alternative. In particular, the concept of serum detection of circulating, free DNA employing next-generation sequencing (NGS) seems to represent a promising diagnostic procedure in patients with bloodstream infections. The applicant's extensive preparatory work suggests that NGS-based diagnostics using the SIQ score have higher specificity and sensitivity compared to traditional culture-based methods for detecting bloodstream infections. This preliminary work for the DigiSep trial with the help of interventional study design provides the optimal basis to establish this new concept as part of the national standard based on the best possible evidence. The DigiSep trial is intended to characterize the effect of the combination of digital precision diagnostics, expert exchange and culture-based standard diagnostics compared to a purely culture-based conventional diagnosis in the clinical picture of sepsis / septic shock. The study examines in 410 patients (n = 205 per arm) with sepsis / septic shock whether the so-called DOOR-RADAR score (Desirability of Outcome Ranking / Response Adjusted for Duration of Antibiotic Risk Score) can be significantly improved, by application of the NGS. We also aim to also study whether the new procedure is cost-effective. It is postulated that the inpatient admission time, mortality rate, incidence of acute renal failure (ARF), the duration of anti-microbial therapy as well as the costs of complications and outpatient aftercare can be reduced. Also, a significant improvement in the quality of life of the affected patients can be expected. As part of the study, the essential data is collected once at the time of sepsis (= onset). The culture-based diagnostics include the guideline-oriented collection of 2 blood culture sets (2 x aerobic / 2 x anaerobic) to the onset and three days later. At the same time, serum samples are obtained for NGS-based pathogen diagnostics. Additional sampling for NGS-based diagnostics can be made up to day 14 after onset or whenever the attending physician establishes a clinical indication for the collection of further blood cultures. The aforementioned cultures vs NGS-based pathogen diagnostics are also accompanied by extended immunological monitoring from blood plasma samples as well as an NGS-based transcriptome analysis. The associated sampling takes place at the time of onset, 3, 7 and 14 days after the beginning of sepsis. Routine microbiological findings from other biological samples (e.g. surgical swabs, drainage secretions, tracheal secretions, tissue samples) are included in the evaluation if these were collected three days before or after the extraction of serum samples for NGS-based diagnostics. The clinical data collection is also carried out at the time of sepsis (= onset), 3, 7 and 14 days later, analogous to the above-mentioned sample collection. The final outcome evaluation takes place 28 days (= 28 d) after the onset of sepsis. The study-related burden on the individual study patient includes a total of 17 ml of whole blood for NGS-based diagnostics, the four samples of 7.5 ml of whole blood for immunological monitoring and the four samples of 2.7 ml of whole blood for transcriptome analysis. The minimum total volume, therefore, amounts to the collection of approximately 75 ml of whole blood within the first 14 days after the onset of sepsis. The sampling takes place with the collection of the blood cultures or within the framework of the daily routine blood samples so that no further venous punctures are required here. Infection parameters such as procalcitonin (PCT) are carried out within the framework of daily regular blood collection and therefore, do not require any additional vascular punctures. The same principle applies to the collection of blood cultures which are routinely obtained as part of standard diagnostics in patients with suspected or proven sepsis. The required blood samples of two 40 ml of whole blood (each two sets of 2 x aerobic / 2 x anaerobic = 4 x 10 ml = 40 ml) therefore do not represent any additional burden due to the study. A further additional burden for the patient concerning invasive procedures or examinations is not expected in the study. ;

Related Conditions & MeSH terms

• Sepsis
• Septic Shock
• Toxemia

• NCT number: NCT04571801
• Study type: Interventional
• Source: University Hospital, Essen
• Contact: Thorsten Brenner, MD
• Phone: +49 201 723
• Email: thorsten.brenner@uk-essen.de
• Status: Recruiting
• Phase: N/A
• Start date: March 16, 2022
• Completion date: August 31, 2024