Article Text
Abstract
Background Synovial tissue research has become widely developed in several rheumatology centres, however, large discrepancies exist in the way synovial tissue is handled and, more specifically, how data pertaining to biopsy procedure, quality check and experimental results are reported in the literature. This heterogeneity hampers the progress of research in this rapidly expanding field. In that context, under the umbrella of European Alliance of Associations for Rheumatology, we aimed at proposing points to consider (PtC) for minimal reporting requirements in synovial tissue research.
Methods Twenty-five members from 10 countries across Europe and USA met virtually to define the key areas needing evaluation and formulating the research questions to inform a systematic literature review (SLR). The results were presented during a second virtual meeting where PtC were formulated and agreed.
Results Study design, biopsy procedures, tissue handling, tissue quality control and tissue outcomes (imaging, DNA/RNA analysis and disaggregation) were identified as important aspects for the quality of synovial tissue research. The SLR interrogated four databases, retrieved 7654 abstracts and included 26 manuscripts. Three OPs and nine PtC were formulated covering the following areas: description of biopsy procedure, overarching clinical design, patient characteristics, tissue handling and processing, quality control, histopathology, transcriptomic analyses and single-cell technologies.
Conclusions These PtC provide guidance on how research involving synovial tissue should be reported to ensure a better evaluation of results by readers, reviewers and the broader scientific community. We anticipate that these PtC will enable the field to progress in a robust and transparent manner over the coming years.
- synovitis
- ultrasonography
- inflammation
- arthritis
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Introduction
Analyses of synovial tissue (ST) at both cellular and molecular levels offer a promising approach for personalised therapy in rheumatic diseases. ST analysis may also advance understanding of disease pathophysiological mechanisms and permit identification of potential therapeutic targets.1–3 Moreover, new developments in single cell methodologies are driving innovation and demand for ST-based studies.4–6 Methods to obtain ST, namely synovial biopsy (SB) procedures, are becoming more acceptable to patients and have been performed with increasing frequency over recent years for both clinical and translational research purposes. This is due in part to the introduction of ultrasound (US) guidance enabling minimally invasive approaches that have now been extensively validated in terms of safety, tolerability and tissue yield.7–11
However, the recent increase in numbers of studies using ST as a source of scientific material also raises questions in terms of interpretability and generalisability. Previous efforts have been initiated by the Outcome Measures in Rheumatology (OMERACT) group and the European Alliance of Associations for Rheumatology (EULAR) Synovitis Study Group (ESSG) in providing guidance on harmonisation of ST analysis procedures across centres for both clinical practice and research.12–16 Nevertheless, minimal requirements for reporting of SB procedures and handling methods of ST remain to be defined. Both reliability and validity of results in the field rely critically on tissue quality and processing. Moreover, selection of patients, methods of retrieval (as well as location within the joint), experience of the operator, handling and analysis methods and quality of the tissue have potential to affect the final research outcome. Therefore, there is an unmet need for evidence and consensus-based points to consider (PtC) defining minimum reporting requirements that could ensure interpretability of the research. Complete and accurate reporting will allow the reader to detect potential biases in the study (internal validity) and to assess the generalisability and applicability of the results (external validity). In this context, the aim of this work was to formulate the EULAR PtC for minimal reporting requirements in ST clinical practice and research in rheumatology.
Methods
From December 2020 to May 2021, a steering committee composed of the conveners (AN—also fellow—and AF) and the senior and junior methodologists (M-AD’A and FC) led a multidisciplinary task force following the 2014 updated EULAR standardised operating procedures.17 The task force included in total 25 members (including the steering committee) from 10 countries, composed of 19 rheumatologists (2 of them also representing the Emerging EULAR Network), 1 translational immunologist and 2 pathologists alongside one allied health professional and two patient representatives. Two virtual meetings of the task force were held, one in December 2020 and one in May 2021. During the first task force meeting, research questions pertaining to the project were formulated. The fellow (AN), guided by the methodologists, performed an systematic literature review (SLR), gathering articles on ST biopsy procedures, their tolerance and outcomes, tissue handling and randomisation, tissue quality control and tissue outcomes. The SLR is published separately, and it forms an integral part of the project.
During the second task force meeting, the results of the SLR were presented and discussed, leading to the formulation of PtC based on evidence and expert opinion. Every statement was presented, iteratively discussed and voted on (informal voting). The level of evidence (LoE) supporting each statement was assigned according to the Oxford Centre for Evidence Based Medicine 2011 Levels of Evidence.18 Of note, an LoE of five corresponds to expert opinion and an LoE of four corresponds to case–control studies. Finally, each task force member anonymously indicated their level of agreement (LoA) with each PtC online (Numerical Rating Scale ranging from 0=‘completely disagree’ to 10=‘completely agree’). The aspects emerging during discussion that required further evidence were integrated in the research agenda. All these steps are summarised in figure 1. The final manuscript was reviewed and approved by all task force members, followed by verification by the EULAR Executive Committee.
Results
Three overarching principles (OP) and nine PtC were formulated (table 1). All OP and PtC were approved after one round of hand raised voting during the task force meeting and one round of online voting after the task force meeting. The mean LoAs were higher or equal to 9, with a percentage of votes above 8/10 of 100% for most of the OP and PtC. LoA was reported in table 1. The LoE was 4 or 5 for all PtCs. The PtC is intended to provide guidance on how research involving ST should be reported in the following areas: biopsy procedures, study design, patients and disease characteristics, handling and processing methods of tissue, quality control, histological analysis, molecular analysis and single cell technologies. The target population was identified as rheumatologists, pathologists and scientists (eg, computational biologists, translational immunologists, molecular scientists), using or involved in research on ST. The target users were defined as physicians and allied health professionals (eg, physiotherapists and specialist nurses), patient research partners and patient charities and organisations, reviewers, journal editors, scientific societies and OMERACT, pharmaceutical industry, biopsy device manufacturers, and the enhancing the quality and transparency of health research network.
Overarching principles
OP-1: Synovial biopsies (single and sequential), performed in aseptic conditions, are safe, well tolerated and can be performed for both clinical and research purposes
SB is performed in both clinical and research settings across numerous centres in Europe. The body of evidence suggesting that the technique is safe and well tolerated has grown over the years, and the safety of the procedure is now well established.7 8 10 11 19–23 The task force emphasised that this applies to both single and sequential biopsies.11 20
OP-2: In both clinical and research settings, synovial biopsies should be guided by imaging techniques. Arthroscopy and ultrasonography are the preferred techniques to guide synovial biopsies
The task force strongly felt that SB should no longer be performed without imaging guidance. This is justified by the fact that blind needle biopsy (NB) procedures retrieve less graded tissue than guided techniques.24 The most commonly used imaging techniques to guide synovial biopsies are US-guided NB, US-guided portal and forceps and arthroscopy. CT and MRI guidance are not used commonly and therefore cannot be recommended.
OP-3: US or arthroscopy can be used to guide the SB without affecting the tolerability of the procedure or the minimal required tissue for meaningful analysis
While the number of graded ST fragments/total number of ST fragments does not differ with US and arthroscopic guided biopsy, the quantity and quality of RNA retrieved was superior with arthroscopy in a study comparing the tissue outputs of different techniques.24 Nevertheless, all techniques allow retrieval of a sufficient quantity of ST for meaningful analysis. Short-term and long-term tolerance is satisfactory with all guided techniques in terms of Visual Analogue Scale pain, swelling and stiffness for both small and large joints, with no difference reported between techniques in a study of over 500 procedures.11
Points to consider
PtC-1: The details of the biopsy procedure should be reported in every study. This should include non-exhaustively:
Exclusion criteria for biopsy.
Target joint(s) and recess.
Intra-articular steroids in the previous 4 weeks or during the procedure.
Technique used (type and size of biopsy retrieval device).
Machine/probe for US-guided biopsies, arthroscopic equipment.
Adverse events.
Operator’s experience and training.
Among the 26 manuscripts retrieved by the supporting SLR reporting on biopsy procedures, details of the procedure were very heterogeneously reported. For instance, exclusion criteria for biopsy and intra-articular treatments in the previous 4 weeks or during the procedure (intra-articular steroids) were reported in less than 10% of the manuscripts, while the target joint(s) and recess, technique used, and equipment were more frequently reported (>75% of included studies). Adverse events were reported in only 20% of the manuscripts and none reported operator’s experience.
Based on these results, the task force developed a non-exhaustive list of elements pertaining to the procedure itself that should be mentioned in every study involving SB. Although minimal training requirements for SB are not yet defined, operator’s experience and training should be reported in every study. Of note, a standardised training model for US-guided, minimally invasive SB procedures in large and small joints constitutes another EULAR task force initiative.25 In addition, depending on the study design, a description of patient tolerability of the procedure is desirable.
PtC-2: Overarching clinical study design, including aspects related to participant disease characteristics and treatments, must be defined in order to evaluate the generalisability and validity of the outcome
This point refers to the study design, defined a priori when the study framework is elaborated by authors. It is known that treatments and disease phenotype can affect ST outcomes in terms of histopathology and transcriptomics especially in inflammatory arthritis.1 4 26–32 Therefore, the task force recommends that aspects pertaining to study design, including participants, disease characteristics (including fulfilment of classification criteria) and treatments, should always be reported in manuscripts.
PtC-3: Conventional patient disease activity measures, disease stage and treatment should be described in order to evaluate the generalisability and validity of the outcome
This point refers specifically to outcome measures and characteristics of the patients included in the study that should always be reported. In the SLR, 100% of studies reported patient demographics and diagnosis, but only 62% reported clinical data, such as disease activity and current therapy. More specifically, disease activity measures should be outlined, including Disease Activity Score 28 C reactive protein or erythrocyte sedimentation rate (ESR), Clinical Disease Activity Index or Simple Disease Activity Index for rheumatoid arthritis or other measures depending on the rheumatic disease under evaluation. Disease duration and conventional synthetic, targeted synthetic or biologic disease-modifying antirheumatic drugs should be reported.
PtC-4: Clinical and contemporary imaging characteristics of the biopsied joints should be described in order to evaluate the generalisability and validity of the outcome
First, the task force felt that clinical assessment of the biopsied joint including swelling should be reported. In the context of US guided SB, the US synovitis grade of the target joint is typically assessed. Surprisingly, these data were described in only 36% of the manuscripts describing US-guided SB in the SLR. The task force emphasised that the US grade of the synovitis in B mode and Doppler can affect tissue quality and outcomes,7 15 33 and therefore, recommends that contemporary imaging characteristics of the biopsied joint are described. In addition, when available, radiographic aspects should be described and when the erosive status of the biopsied joint is known, this information should be provided.
PtC-5: Tissue handling and processing methods must be described in order to ensure reproducibility, including numbers and size of fragments allocated to each analytic.
Our SLR retrieved numerous studies looking into intra-articular variability of tissue outcomes and sampling error.15 34–39 More specifically, immune cell infiltrate, immunohistochemistry, cytokine mRNA and T cell repertoire displayed little or no difference when retrieved in different parts of large joints.36–38
Of interest, studies assessing sampling error showed that a minimum of 4 tissue fragments provided a reliable sample with 10% sampling error for small joint histopathological analysis,15 while 4–7 tissue fragments were required to detect a twofold change with a 25% sampling error in PCR in large joints34 and the percentage mean difference for the staining of immunohistochemical cellular markers decreases below ±10% when a minimum of eight samples are considered in the evaluation.39 In addition, a minimum of 6 fragments and the assessment of an area of tissue of minimum 2.5 mm2 were deemed necessary to ensure representativity of histological analysis.40 41 In this context, the task force recommends that authors report data pertaining to tissue handling and processing, including numbers and size of fragments allocated to each analytic.
PtC-6: Method and results of tissue quality assessment should be reported, including the percentage of graded tissue
Among the 26 studies included in the SLR, only 17 reported having controlled the tissue quality during their study (65%). The task force felt it was absolutely necessary for a quality control to be performed and reported by authors in manuscripts in order to ensure reliability and reproducibility of the results. When histopathological analysis is performed, the percentage of tissue presenting with a typical ST structure and an intact lining layer or positive CD68 staining should be reported.7 15 16
PtC-7: When histological or immunohistological analysis is performed, the scoring or analysis system should be defined including
Representative images.
Reference to original publication for validated scoring systems only.
Digital analysis software, including version numbers of platforms used.
Immunohistological staining protocol, including antibody sources and clones.
Area assessed and sampling strategy.
Number of observers and intraobserver and interobserver variability.
Since numerous studies assess histological aspects of the tissue, it was felt important by the task force to formulate a PtC related to histological scoring. More specifically, several aspects were deemed mandatory by the task force, such as describing staining protocols and antibodies sources and clones, providing representative images illustrating the findings and describing area assessed and sampling strategy. In the manuscripts included in the SLR, scoring systems were rarely described and chains of references to previous publications, but not the original scoring system, were often observed. Subsequently, the task force recommended that only the original publication describing the scoring system should be cited. The interobserver and intraobserver variability for histological analysis was similarly rarely described (n=4/26 publications, 15%) and should always be reported for studies using scoring by observers.
PtC-8: Methods of extraction and quantification should be defined and purity, quantity and quality of DNA/RNA should be reported
Although no study specifically assessed the difference in outcomes arising from tissues yielding DNA or RNA of high versus poor quality (measured by the RNA integrity number for RNA), it was considered important by the task force members that such information should be reported in every manuscript. It is indeed anticipated that poor quality RNA, if used for RNA sequencing, will provide unreliable results. In addition, it has been noted in the SLR that such information was very rarely reported in the analysed publications (two out eight publications looking at molecular aspects of ST (25%)).
PtC-9: In case of single cell analysis, methods used and quality outcomes should be detailed, including
Methods of tissue or cell preservation.
Methods of tissue dissociation.
Percentage of viable cells recovered or analysed.
Percentage of mitochondrial gene expression seen in the sequenced cells and the threshold chosen for analysis.
If sorting is used, the strategy used and purity of sorted cells.
The recent development of single cell technologies has also raised methodological challenges. Of interest, the methods of tissue conservation or dissociation can influence the tissue outcome. In a study from Donlin et al, mechanical versus mechanical and enzymatic ST dissociation methods have been compared, showing that the latter retrieved a higher total cell count per gram of tissue, a higher viable cell count and a more representative number of cell subpopulations. In addition, they compared methods of tissue preservation, showing that cryopreserved samples retrieved similar numbers of viable cells and a similar variety of cell subpopulations to fresh samples.35 Therefore, the task force recommends that these elements are reported in every publication, in addition to other aspects related to quality, such as the percentage of viable cells and percentage of mitochondrial gene expression seen in the sequenced cells alongside parameters related to cell sorting methods, including flow cytometric staining protocols.
Discussion
These are the first EULAR-endorsed PtC on ST research in rheumatology with the aim of them serving as a reference and checklist for clinicians and scientists involved in publishing, reviewing and reading manuscripts reporting ST research. They have been proposed by a multidisciplinary team of international experts in the field involving rheumatologists, translational researchers, methodologists and pathologists.
Our SLR retrieved several manuscripts, which were analysed from different perspectives. With respect to the OPs, we emphasised that the body of evidence on SB tolerability and safety is very reassuring for both single and sequential biopsies. In addition, the task force stated that SB should no longer be performed without imaging guidance, more specifically blind needle biopsies are no longer recommended. There is no preferred guiding technique between US or arthroscopy, since both allow retrieval of a sufficient quantity of tissue for meaningful analysis and are well tolerated.11 24 Of interest, we assessed how comprehensively data relevant to study design, patients’ characteristics, biopsy procedures, tissue handling, quality control and tissue outcomes were reported in the publications. In this regard, these PtC focus on specific areas requiring attention from authors when reporting their study results in order to ensure internal and external validity of the studies and generalisability. These PtCs are also proposed in an editor friendly document appearing as a checklist and provided in online supplemental material 1.
Supplemental material
While conducting this work, we realised that the paucity of literature on clinical applications of tissue analysis did not allow the formulation of PtC dedicated to the clinical aspects. Indeed, although recent publications propose encouraging data for the use of SB for diagnosis, outcome prediction or disease management in clinical practice, the task force felt that these aspects should be included in the research agenda.2 4 42–44 One major limitation encountered in the development of these PtC was the scarcity of literature appraising the practical aspects of tissue retrieval, handling and analysis. Due to the paucity of evidence comparing methods or outcomes based on tissue handling, quality or analysis, most of these PtC rely on expert opinion. In this respect, it is noteworthy that the members of this task force acted as representatives of the most prominent centres working in the field of translational research in ST, including EULAR centres of excellence. Based on the SLR results and the inputs and discussion arising from the second task force meeting, other relevant items were incorporated in the research agenda (box 1).
Research agenda
Research agenda
Minimal training requirement for ultrasound guided SB for physicians and allied health professionals.
Impact of training on patient tolerability; tissue yield/quality/outcomes.
Influence of tissue handling and processing (fixation, standardised operating procedures for freezing in optimal cutting temperature (OCT), fixation, and freezing (and time to freezing) for subsequent live tissue/cell analysis) on tissue quality/outcome.
Clinical practice: supportive data for diagnosis or prognosis or disease management.
Risk of Bias tools for translational research.
Tissues considered as best ‘non-inflammatory’ controls (eg, healthy subjects, meniscectomy surgery, traumatic arthritis, cadavers).
In conclusion, these EULAR PtCs provide relevant guidance on minimal reporting requirements in ST research in Rheumatology. These first EULAR PtCs are intended to be disseminated and used by the broad research community, adding to previous initiatives from OMERACT and ESSG in order to allow the field of ST research to evolve in a robust and transparent manner in the future.
Ethics statements
Patient consent for publication
Ethics approval
This study does not involve human participants.
References
Supplementary materials
Supplementary Data
This web only file has been produced by the BMJ Publishing Group from an electronic file supplied by the author(s) and has not been edited for content.
Supplementary Data
This web only file has been produced by the BMJ Publishing Group from an electronic file supplied by the author(s) and has not been edited for content.
Footnotes
M-AD and AF are joint senior authors.
Handling editor Josef S Smolen
Twitter @JustSoren, @A_Filer
Contributors All authors formulated the recommendation. All authors contributed to and finally approved the current manuscript.
Funding This work was funded by EULAR (SCI020).
Competing interests AN has received consulting and/or speaker’s fees from UCB, CHUGAI, BMS all unrelated to this manuscript. FC has received consulting and/or speaker’s fees from Lilly, Novartis and UCB, all unrelated to this manuscript. M-AD'A has received consulting and/or speaker’s fees from Lilly, Novartis, AbbVie, BMS, Pfizer, Galapagos, and UCB, all unrelated to this manuscript. AF has received consulting and/or speaker’s fees from Janssen, GSK, Abbvie, Galapagos and receives research funding from Janssen, GSK, Mestag, Roche and Celsius, all unrelated to this manuscript. EN has received consulting and/or speaker’s fees from Roche, BMS, UCB, Lilly Celgene GmbH, all unrelated to this manuscript. SA has received research funding by Abbvie, Pfizer, BMS and GSK and has received consulting and/or speaker’s fees from Abbvie, Pfizer, BMS, Galapagos, Novartis, Janssen and Lilly all unrelated to this manuscript. JEF has received research funding and/or speaker’s fees from Abbvie, Ache, Biogen, Janssen, Lilly, MSD, Novartis, Pfizer, UCB, all unrelated to this manuscript. SWT received research funding and/or speaker’s fees from AbbVie, Arthrogen/MeiraGTx, AstraZeneca, BMS, Celgene, Galapagos, GSK, MSD, Pfizer, Roche, Sanofi-Genzyme, all unrelated to this manuscript. VCR has received research funding and non-financial support from Merck Sharp and Dohme; personal fees and non-financial support from Pfizer and Janssen; non-financial support from Lilly and Roche, outside the submitted work. MM Supported by the National Institute of Health Research (NIHR) Birmingham Biomedical Research Centre at the University Hospitals Birmingham NHS Foundation Trust and the University of Birmingham. The author(s) views unrelated to the NIHR or the department of Health and Social Care.
Provenance and peer review Not commissioned; externally peer reviewed.
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