Article Text
Abstract
Objective: To evaluate the use of ultrasound, including quantitative Doppler analysis of synovial vascularisation, before and after intra-articular treatment with glucocorticosteroids in patients with rheumatoid arthritis (RA).
Methods: 51 patients with RA were followed prospectively after an intra-articular glucocorticosteroid injection. Disease modifying antirheumatic drug treatment was kept unchanged and no further injections given in this observation period. At baseline, disease activity was estimated clinically by target join pain on a 100 mm visual analogue scale, on which the target joint was scored 0–3 for swelling and tenderness, and by ultrasound measurements of grey scale pixels, colour Doppler pixels, and the spectral Doppler resistive index (RI) as indicators of synovial swelling and inflammation. After four weeks, the measurements were repeated on the same joint. An observer unaware of the sequence and patient number evaluated the ultrasound images.
Results: At one month follow up after the glucocorticosteroid injection, a marked decrease in the fraction of colour pixels was seen in 41/51 patients (Student’s t test p<0.001). Correspondingly, the RI increased indicating a diminished flow to the synovium (Student’s t test p<0.01). Both the fraction of colour pixels and the RI values corresponded with the clinical evaluation and with the subjective effect of the treatment. The synovial membrane volume estimated by total amount of pixels showed a significant decrease by 31% after treatment.
Conclusion: Ultrasound-Doppler seems to be a promising tool for the estimation of synovial activity in arthritis. After intra-articular glucocorticosteroid, changes in RI and fraction of colour pixels may both be used as quantitative measurements of the blood flow.
- Rheumatoid arthritis
- Doppler ultrasonography
- glucocorticosteroids
- inflammation
- CDI, colour Doppler image
- CRP, C reactive protein
- DMARD, disease modifying antirheumatic drug
- ESR, erythrocyte sedimentation rate
- HAQ, Health Assessment Questionnaire
- MRI, magnetic resonance imaging
- NSAID, non-steroidal anti-inflammatory drug
- RA, rheumatoid arthritis
- RI, resistive index
- ROI, region of interest
- US, ultrasound
- VAS, visual analogue scale
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- CDI, colour Doppler image
- CRP, C reactive protein
- DMARD, disease modifying antirheumatic drug
- ESR, erythrocyte sedimentation rate
- HAQ, Health Assessment Questionnaire
- MRI, magnetic resonance imaging
- NSAID, non-steroidal anti-inflammatory drug
- RA, rheumatoid arthritis
- RI, resistive index
- ROI, region of interest
- US, ultrasound
- VAS, visual analogue scale
In rheumatological research non-invasive imaging methods such as magnetic resonance imaging (MRI) and ultrasound (US) have been proposed for the detection and grading of rheumatic inflammatory lesions as they have the potential to provide objective analysis of the disease without ionising radiation.1 Among the two imaging modalities, US has the potential of becoming a tool used in daily rheumatology practice as it is already accessible in many outpatient clinics, has no contraindications, and poses no problems of patient compliance. Studies have shown that US is comparable with MRI in detecting synovitis in rheumatoid arthritis (RA).1,2 Macroscopically the synovial membrane in RA joints is greatly increased and reflects vascular congestion, oedema and cellular infiltration as well as synovial lining hyperplasia and pannus tissue formation.3 US may visualise the vascularity in the pannus and the hyperaemic synovium by the use of Doppler, and several studies have indicated that power and colour Doppler ultrasonography can detect treatment response.4–7 The evaluation of the degree of inflammation and the treatment response has in general been based on a semiobjective scoring system grading the disease activity—for example, from 0 to 3,4,5 while a more quantitative analysis of the amount of pixels with signs of vascular activity has been proposed.6,8
With spectral Doppler it is possible to evaluate the type of flow in the synovium—that is, low peripheral resistance versus high peripheral resistance. The degree of peripheral resistance is expressed numerically by the resistive index (RI).9 In this way it is possible to obtain objective information on the quality of flow in the synovium as a supplement to the estimation of vascularisation by colour pixels. Preliminary data have indicated low resistance flow and low RI values in pannus in RA.10 The dramatic effect of intra-articular injections of glucocorticosteroid has been known since 1951,11 and as glucocorticosteroid treatment has previously been seen to diminish the power Doppler signal,4,5 it seems ideal to choose intra-articular treatment for an evaluation of the ability of a new measure to detect and quantify an anti-inflammatory effect.
This study aimed at evaluating the quantitative response to glucocorticosteroid treatment by both colour and spectral Doppler in the diagnosis of inflammatory joint involvement in patients with RA and comparing the treatment with clinical estimates of the disease activity.
PATIENTS AND METHODS
Patients
Fifty one patients with rheumatoid arthritis were included (11 men, 40 women; mean age 63, range (29–93); mean disease duration 12 years, range (1–42); 34 had positive rheumatoid factor). All the patients needed an intra-articular glucocorticosteroid injection to treat a single joint flare up. The joints included 30 wrists, 9 elbows, 5 proximal interphalangeal joints, 2 metacarpophalangeal joints, 1 metatarsophalangeal joint, 3 talocrural joints, and 1 sternoclavicular joint. For at least three months before the study all patients were receiving stable disease modifying antirheumatic drug (DMARD) and non-steroidal anti-inflammatory drug (NSAID) treatment. During the observation period of four weeks their drugs were unchanged and no further injections were given. None of the patients received oral glucocorticosteroid treatment in doses larger than 7.5 mg daily. The patients fulfilled the 1987 American College of Rheumatology criteria for RA.12
Clinical evaluation included pain in the target joint on a 100 mm visual analogue scale (VAS), Health Assessment Questionnaire (HAQ), morning stiffness in minutes, and the degree of swelling and tenderness of the target joint graded from 0 to 3. Blood samples were obtained for the determination of erythrocyte sedimentation rate (ESR) and C reactive protein (CRP).
Ultrasound
An Acuson Sequoia ultrasound system (Mountainview, California, USA) was used for the ultrasound examinations using a 15 MHz linear array transducer. The target joint was scanned at predefined transducer positions for that particular joint and the synovial membrane was examined longitudinally and transversally. Blood flow in the synovial membrane was visualised with colour Doppler ultrasonography. The colour Doppler settings were the same for all joints and all patients with a gain setting just below the noise level using our set up for low flow—Nyquist limit +/− 0.014 m/s and 7 MHz Doppler frequency. With this set up all the colour pixels in the image correspond to motion—that is, blood flow. Quantitative estimation of the vascularisation in the synovial membrane was performed using the selected colour Doppler image (CDI) with maximum colour activity. At present the colour Doppler is as sensitive as the power Doppler on the Sequoia. The digitally stored CDI in DICOM format was transferred to a processing program (Corel Photo-Paint 7) (Corel Corporation, Ottawa, Ontario, Canada). The synovium was traced, indicating the region of interest (ROI). On the US image the synovium appears as a predominantly hypoechoic mass covering the bony surfaces adjacent to the joint. By using a colour recognition function the number of colour pixels as well as the total number of pixels in the ROI were counted.8 The number of colour pixels was then expressed in relation to the total amount of pixels in the ROI as the colour fraction. The total number of pixels (= synovial area) was also noted separately, as an estimate of the synovial membrane volume. The images were evaluated with the sequence and name of the patient “blinded”.
With colour Doppler as guidance, the spectral Doppler sampling area was placed over an intrasynovial artery and the spectrum was obtained. Three random synovial arteries were sampled in this way. The ultrasound unit traced the Doppler spectra electronically and identified the cardiac cycles as well as peak systolic flow and end diastolic flow. The unit then calculated the RI as (peak systolic flow – end diastolic flow)/peak systolic flow. In this paper we used a mean RI value obtained from three different synovial artery values as described above. Low RI values correlate with a low peripheral resistance, indicating an increased tissue perfusion.13–15 When spectral Doppler measurements could not be measured owing to the lack of inflammatory activity in the examined joint, the RI was defined as 1.00, assuming the resistance in the synovial arteries to be the same as in extrasynovial musculoskeletal tissue.
The synovium was noted as non-inflamed when no pixels were present in the ROI.
After four weeks the measurements were repeated on the same joint using the predefined positioning of the probe.
Injections
All injections were carried out guided by ultrasound. The ultrasound probe was held just outside the disinfected area but with a clear view of the area of interest. Using the “no-touch” technique, the needle was then inserted into the joint cavity visualised on ultrasound to ensure correct placement of the needle. The injection site was determined from the ultrasound image as the area with the most pronounced Doppler activity. The following injection with 40 mg methylprednisolone was monitored and the injected fluid was seen distributing in the joint cavity. In some of the finger joints it was impossible to inject all 40 mg of methylprednisolone because of lack of space. In these situation as much as possible was injected (⩾20 mg).
Statistics
Statistical analysis was performed using the SPSS 10.0 program.
Student’s t test for paired samples was used for continuous data, which include ESR, CRP, the pixel fraction, the total number of pixels, and mean RI. We also chose to regard HAQ and VAS as continuous data in this study. As model control the difference between the baseline and follow up visits was tested for normality (1−sample Kolmogorow-Smirnoff test). The CRP had a borderline normal distribution, but the choice of test had no influence on the statistical result. Wilcoxon signed rank sum test was used for categorical data, including morning stiffness and assessment for tender and swollen joints. For the correlation between the US parameters and the clinical evaluation Pearson’s test was used.
For statistical reasons we needed a value for RI even when no vessels were detectable in the synovium and we defined it as 1.00 in those situations. Level of significance was chosen at p⩽0.05
RESULTS
Table 1 shows the changes in clinical, biochemical, and ultrasound parameters during the observation period. There was a significant change in the global disease activity parameters such as CRP, morning stiffness and HAQ, after the intra-articular treatments, while the ESR remained stable. The local disease activity parameters such as synovial area, VAS, tender and swollen joint assessment of the target joint all showed significant changes after the treatment.
For the ultrasound parameters 41/51 had a significant decrease in colour fraction after the treatment, whereas only 32/51 had a significant increase in mean RI. The synovial volume assessed by the total amount of grey pixels decreased in 38/51.
The presence or absence of a positive rheumatoid factor had no impact on the treatment response. We found a significant correlation between the mean RI and the colour fraction (r= −0.32, p=0.02), between the pixel fraction and the tender joint assessment of the target joint (r= 0.6, p=0.02) and the ESR (r= 0.34, p=0.02), and between mean RI and the VAS (r= −0.38, p=0.02). No other significant correlations were found.
DISCUSSION
This study showed a significant effect of intra-articular glucocorticosteroid injections on the quantitative ultrasound measurements of synovial disease activity. The effect was demonstrated on both the synovial vascularisation (as measured by the colour fraction) (fig 1) and in the flow profile indicated by the increasing RI values due to a higher peripheral resistance (fig 2). Our findings of a decrease in colour fraction are in accordance with those of other studies.4,5 Also the synovial volume expressed by the total amount of pixels in ROI, showed a significant decrease by 31% after anti-inflammatory treatment, which is in agreement with other studies.16,17 The ultrasound changes in our study paralleled the clinical evaluation by the clinician and the subjective pain evaluation, morning stiffness, global evaluation, and HAQ by the patient.
The dramatic anti-inflammatory effect of intra-articular treatment with glucocorticosteroids has been known since 1951, when Hollander et al first injected hydrocortisone acetate intrasynovially into patients with RA and found that they acted quickly on pain and joint swelling in 90% of the treated joints.11 Since then, intra-articular injections have become standard adjuvant treatment to normal NSAID and/or DMARD treatment of RA. One or several injections into the same joint may improve the patient’s condition significantly by decreasing joint pain and swelling, leading to improved function. The effect of intra-articular treatment varies from patient to patient, but may last for years.18,19 Intra-articular treatment has the advantage over oral glucocorticosteroid treatment in that the systemic effects of the drug used are minimal, though they may be seen in some patients.20
Doppler US is a relatively new tool in the investigation of local inflammation.10,21 The Doppler signals are a reflection of the number of red blood cells that pass the transducer and the speed with which they pass. The colour pixels are therefore an estimate of the relative amount of moving blood in the investigated area.22,23 The appearance of colour pixels in a synovial membrane is a sign of an increase in the relative amount of moving blood, because colour pixels are rarely seen in normal joints. The number of vessels does not correspond with the number of colour pixels visualised by Doppler ultrasound but rather with the area of the already existing vessels.24 The colour pixels may therefore be interpreted as a sign of hyperaemia.5 Although Doppler ultrasonography does not depict hyperaemia itself,25 it depicts the increase in flow that is a part of the inflammatory process. Spectral as well as colour Doppler seems to offer an objective and easily obtainable estimate of the degree of synovial inflammation, which may be used both in clinical trials and in daily clinical practice. The RI (resistive index, resistance index, or Pourcelot index9 ) is a numerical value of the amount of diastolic flow and is directly proportional to the peripheral vascular resistance. The RI has been used in obstetrics and in nephrology to give a numerical value for the diastolic component in the umbilical arteries and arteries of the transplanted kidney.26,27 In normal resting musculoskeletal tissues flow is seen with colour or power Doppler in muscles, connective tissue, seldom in joints, and never in tendons. When assessed by spectral Doppler, no diastolic flow is found in the resting tissues and, consequently, the RI is 1.00. In rheumatology low values of RI indicate disease, which has been observed in previous studies,7,8,10,28,29 although a definite cut off level for abnormality remains to be established.
Colour and power Doppler have been used to identify the hyperaemia associated with inflammation.2,21,24,30 The use of the colour fraction as an anti-inflammatory measure has in other studies been evaluated after treatment with glucocorticosteroids4,5 and has also been found to be comparable with the changes in histology and MRI.2,30 The number of colour pixels in the synovium thus seems to correlate with the disease activity. The determination of the colour fraction within the ROI as described in this paper is suggested as an objective measure. The intra- and interobserver intraclass correlation coefficients for this method have been determined in an earlier study as 0.82–0.97 and 0.82, respectively.8 Alternatively, as described in other studies hyperaemia may be graded 0–3 based on the subjective estimate of the examiner, although the reproducibility has not yet been determined.4,5 A comparison of scoring systems remains to be undertaken, but a standardised quantitative measurement will be of advantage in longitudinal studies. The RI, on the other hand, is determined by the ultrasound machine and is not dependent on the level of experience of the investigator. We found that the decrease in colour pixel fraction after treatment was paralleled by an increase in vascular resistance (RI). Both changes indicate a diminished flow in the synovium and thus a decrease in inflammatory activity. It may be speculated that the RI indicates changes in inflammation despite the presence of flow—that is, when pixel evaluation is more or less unchanged. Only weak or no associations have been observed between imaging parameters and estimates of the global clinical status.2,8,31 This may be due to differences in the general state of the disease and the local disease activity in, for example, a finger or a wrist joint. In our study, the US parameters (colour fraction and the mean RI) correlated with ESR, VAS, and tender joint assessment.
CONCLUSION
This study shows that the colour fraction can detect changes in the synovial vascularisation due to treatment. It also suggests that RI may be an objective measure of inflammation and treatment response in patients with RA. The RI measure may be used as an alternative or adjunct to the estimation of the colour fraction and has the advantage of being automated.
Acknowledgments
The study was supported by the OAK foundation