Abstract
Purpose
The British Society of Interventional Radiology (BSIR) Inferior Vena Cava (IVC) Filter Registry was produced to provide an audit of current United Kingdom (UK) practice regarding placement and retrieval of IVC filters to address concerns regarding their safety.
Methods
The IVC filter registry is a web-based registry, launched by the BSIR on behalf of its membership in October 2007. This report is based on prospectively collected data from October 2007 to March 2011. This report contains analysis of data on 1,434 IVC filter placements and 400 attempted retrievals performed at 68 UK centers. Data collected included patient demographics, insertion and retrieval data, and patient follow-up.
Results
IVC filter use in the majority of patients in the UK follows accepted CIRSE guidelines. Filter placement is usually a low-risk procedure, with a low major complication rate (<0.5 %). Cook Gunther Tulip (560 filters: 39 %) and Celect (359 filters: 25 %) filters constituted the majority of IVC filters inserted, with Bard G2, Recovery filters, Cordis Trapease, and OptEase constituting most of the remainder (445 filters: 31 %). More than 96 % of IVC filters deployed as intended. Operator inexperience (<25 procedure) was significantly associated with complications (p < 0.001). Of the IVC filters initially intended for temporary placement, retrieval was attempted in 78 %. Of these retrieval was technically successful in 83 %. Successful retrieval was significantly reduced for implants left in situ for >9 weeks versus those with a shorter dwell time. New lower limb deep vein thrombosis (DVT) and/or IVC thrombosis was reported in 88 patients following filter placement, there was no significant difference of incidence between filter types.
Conclusions
This registry report provides interventional radiologists and clinicians with an improved understanding of the technical aspects of IVC filter placement to help improve practice, and the potential consequences of IVC filter placement so that we are better able to advise patients. There is a significant learning curve associated with IVC filter insertion, and when a filter is placed with the intention of removal, procedures should be in place to avoid the patient being lost to follow-up.
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Introduction
Venous thromboembolism (VTE), including deep venous thrombosis (DVT) and pulmonary embolism (PE), is a common disorder that affects 100 per 100,000 individuals per annum [1]. The accepted standard treatment is full-dose anticoagulation, which is effective at reducing the risk of recurrent DVT and PE. Inferior vena cava (IVC) filters provide an alternative treatment for prevention of fatal pulmonary embolism in patients with contraindications to anticoagulation (short- or long-term) or when anticoagulation is ineffective [2]. In patients with short-term, or potentially reversible, contraindications to anticoagulation, current guidance states that retrievable IVC filters should be used in preference to permanent placement [2].
Retrievable IVC filters can be deployed for the period of time that a patient is at risk for PE but can then be removed to avoid the potential long-term complications [3]. The development of retrievable filters has expanded the use of IVC filters and led to an increase in the implantation of IVC filters in patients with a wider range of prophylactic indications [4]. All retrievable IVC filters can function as permanent filters if they are not removed. Several studies have indicated that only a small percentage of retrievable IVC filters (2–20 %) are removed and device related complications have been reported [4–8]. Recently the U.S. Food and Drug Administration issued a medical alert to address these considerations and emphasized filter removal as soon as protection from PE is no longer necessary [9]. Similarly, the Medicines and Healthcare products Regulatory Agency (MHRA) issued a warning that there had been a number of serious (but unspecified) complications associated with the attempted removal of filters left in situ for 3–18 months [10].
The decision to undertake a registry of IVC filter practice arose from concerns among British Society of Interventional Radiology (BSIR) members about the risks associated with filters coupled with a lack of knowledge of the fate of filters deployed with the intention of subsequent retrieval. The primary purpose of the BSIR IVC Filter Registry was to record and evaluate current practice in the United Kingdom. A secondary goal was to examine outcomes for patients, in particular complications associated with the insertion procedure, complications whilst the filter is in place, and the success of retrieval.
Patients and Materials
The Inferior Vena Cava Filter Registry, a web-based registry, was launched by the BSIR on behalf of its membership in October 2007. This report is mostly based on prospectively collected data from October 2007 to March 2011, although a small number of individuals inputted data retrospectively. All interventionalists, regardless of membership of BSIR, were invited to participate and complete the online dataset (electronic supplementary material) for all IVC filter placements and retrievals. Demographic, filter type, technical success and retrieval success, and complications were recorded. A separate form to record any follow-up visits that the patient may have undergone after the procedure was available. Two months before data analysis, all contributors were asked via email to complete any outstanding data.
This report contains analysis of data on 1,434 IVC filter placements and 400 attempted retrievals performed at 68 United Kingdom (UK) centers.
The intention of the registry was to capture follow-up data on all cases of at least 1 year. At least one follow-up record was available in 69 %. The registry was funded by the BSIR on behalf of its members.
Statistical Analysis
Statistical analysis was performed using SPSS version 16.0 (SPSS Inc., Chicago, IL). Multivariate regression analysis, χ2, and two-sided t tests were performed. The level of statistical significance was set at p ≤ 0.05.
Results
The mean age at placement was 63 (range 20–107) years. The peak in age distribution, irrespective of gender, was 70–74 years. There was no statistically significant difference in age distributions between the genders. The proportion of female patients is highest in the younger than 40-year-old age group. There are relatively more men than women in the 55–64-year-old age group and a preponderance of women in the very oldest age groups, which is a reflection of the greater longevity of women. IVC filter usage and inputting of data into the registry increased over the lifespan of the registry with approximately 10 patients per month being added in 2007, 25 per month in 2008, 35 per month in 2009, 55 per month in 2010, and approximately and 70 per month in 2011.
Indication for Placement
The vast majority of IVC filter placements were undertaken for recognized indications in accordance with CIRSE guidelines (see electronic supplementary material). The most commonly recorded indications were:
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Preoperatively for acute deep vein thrombosis (DVT)/pulmonary embolus (PE) (31 %)
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PE with contraindications to anticoagulation (24 %)
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Prophylaxis in high-risk patients (21 %)
Of the 95 patient entries with an “other” indication, only 34 have this as their sole indication and most of these can be accommodated in the recognized list of indications. A limited number of placements (n = 12) did not conform to guidelines; the most frequently cited was”DVT associated with malignancy but without associated PE or surgery” (n = 11/12) with “progression of DVT despite anticoagulation” comprising the remainder (n = 1).
Placement Intention
Over the life-span of the registry, there was a trend for increasing use of temporary filter placements (χ2 analysis of trend over time; p = 0.014; Fig. 1); 91 % of placements in the 20–29-year-old age group were intended to be temporary compared with 19 % in the 80–89-year-old age group. Those with presumed lifelong risk were more likely to have a permanent filter. All filters placed during pregnancy were intended for removal. Likewise, where there was clearly a short-term risk, such as preoperative patients with acute DVT/PE, the intention was for short-term filter placement in the majority of cases.
Filter Types
The majority of IVC filters deployed were of a retrievable type; this was even the case when the IVC filter was placed with the intention of leaving it permanently. The Cook Gunther Tulip filter was the most commonly placed IVC filter (39 %). The Cook Celect filter was the second most commonly placed device (25 %). Together, these two filters accounted for 64 % of all the IVC filter placements recorded (Fig. 2). Bard G2, Recovery filters, Cordis Trapease, and OptEase accounted for the majority of the rest (31 %). There was a statistically significant trend for a proportionate increase in the use of the Celect filter over the lifetime of the registry (p = 0.003).
Procedure
The majority of procedures involved the use of the right femoral or right jugular approach (Fig. 3). The left jugular approach was very rarely used. Almost two-thirds of procedures were completed within 30 min. Significantly more procedures took greater than 30 min when using the left femoral versus the right jugular approach (2 × 2 contingency table; p = 0.014).
The vast majority of filters were placed in an infra-renal (92 %) or juxta-renal location (3.5 %). Of the 53 supra-renal filter placements, 27 were for IVC thrombosis and 13 for pregnancy with no clear reason for choosing a supra-renal location in 7 and data in 6. Placement and retrieval of IVC filters was in accordance with the manufacturer’s instructions for use.
Outcomes
Implantation
More than 96 % of filters deployed as intended. Failure to deploy as planned occurred in 3.3 % of cases (48/1,434). The explanation in most cases was tilting, sometimes due to unexpected anatomical variations. Failure to open properly or failure to deploy at the intended site was reported in 11 cases (9 Tulip, 2 Simon Nitinol). The procedure was abandoned in only two cases. In one case, a Cordis OptEase device was retrieved immediately after placement because of pain. In the other, deployment was abandoned due to dilated IVC.
Multivariate analysis revealed independent factors associated with a technically successful procedure were younger age (p = 0.022, odds ratio (OR) = 1.017, 95 % confidence interval (CI) = 1.002–1.031) and type of device (p < 0.001): the Bard G2 IVC filter (p = 0.002, OR = 15.311, 95 % CI = 2.627–89.224), Bard Recovery IVC filter (p = 0.017, OR = 11.11, 95 % CI = 1.544–79.951), and the Cook Celect IVC filter (p = 0.019, OR = 5.012, 95 % CI = 1.307–19.255) were the most successfully placed.
Filter Tilting at Deployment
Of the 1,434 IVC filters placed, 1,033 (72 %) were centralized, 190 (13 %) were tilted, 49 (3 %) were seen to abut the IVC wall, and 162 (12 %) were unspecified. The Cook Gunther Tulip and Celect filters were associated with tilting, or apex abutting the caval wall, in more than 20 % of placements. Tilting was less frequently reported with the Cordis TrapEase and OptEase and the Bard G 2 device. Tulip and Celect filters deployed via the left femoral approach were significantly less likely to be centralized than those deployed via the right femoral approach (p = 0.012) or via the right jugular approach (p = 0.02). These findings suggest that, if the right femoral approach is not available, a right jugular approach is probably preferable to a left femoral approach.
Dwell Time
The duration of placement for each of the various filter models recorded in the registry where retrieval was attempted differed significantly:
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Bard G 2 median dwell time 77 (range 34–154) days
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Bard Recovery median dwell time 77 (range 28–166) days
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Cook Celect median dwell time 32 (range 18–66) days
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Cook Gunther Tulip median dwell time 39.5 (range 22–101) days
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Cordis OptEase median dwell time 12 (range 2–45) days
The duration of placement was significantly shorter for the Cordis OptEase filter (p ≤ 0.001) compared with any of the other filters, in keeping with differences in the Instructions for Use.
Retrieval
Of 721 filters placed with the intention of retrieval, there was no retrieval information on 207 (29 %). Of the remaining 514, retrieval was attempted in 415 (81 %) and was technically successful in 83 %. The reasons for not retrieving the remaining 99 (19 %) included clinical deterioration and caval thrombosis. Many of the failed to retrieve filters failed to be retrieved within the dwell time suggested by the manufacturer (Table 1). Follow-up data indicate that this group has poor long-term survival reflecting significant clinical deterioration. Retrieval success diminished with duration of implantation. Filters that had been deployed for more than 9 weeks (>62 days) were significantly less likely to be successfully retrieved compared with those with a shorter duration of implantation (p = 0.001). This is most likely to be due to incorporation of the device in the caval wall, IVC thrombosis, and penetration of the caval wall by the filter legs (p < 0.001). There was no significant difference in retrieval success of different filter types; Bard IVC filters achieved the highest success rates, despite the longest median dwell time of 77 days. For the filters where there was no initial decision on the intended duration of filter placement, 34 % were retrieved. Retrieval was usually a quick procedure; 68 % took less than 30 min. Retrieval was associated with a limited number of minor complications and no serious complications. In the 25 pregnant women reported in the registry, there was no recorded attempt at retrieval in 2 patients, failure to retrieve in 6, and successful retrieval was recorded in only 12 patients; the retrieval data were missing for the other 5 entries, suggesting that, in this subgroup, the overall retrieval rate was less than 50 %. Significant tilting, to the extent that the filter head was abutting the caval wall, was a frequently indicated cause of failure to retrieve the filter.
Multivariate analysis revealed that independent factors associated with no attempt at IVC filter retrieval were older age (p < 0.001, OR = 0.967, 95 % CI = 0.958–0.975), DVT/PE and limited cardiopulmonary function (p = 0.009, OR = 2.787, 95 % CI = 1.296–5.992), evidence of preoperative PE (p ≤ 0.001, OR = 4.531, 95 % CI = 3.144–6.529), and in the group “prophylaxis in high-risk groups” (p < 0.001, OR = 3.817, 95 % CI = 2.548–5.719).
A total of 190 (13 %) filters were tilted post deployment and 49 (3 %) were seen to abut the IVC wall. There was no significant difference between these and centralized IVC filters and a successful retrieval (p = 0.643).
Retrieval Complications
Reported complication rates are in the range 0.0–16.7 % on a device-by-device basis; on review of the detailed description data on the recorded filter complications, it transpires that the majority of these were not true retrieval complications. There were three caval tears reported, which were not associated with adverse clinical consequences and one dissection of the internal jugular vein. There were three mechanical/structural failures of the retrieval device of the Cook Gunther Tulip filter with no significant clinical sequelae, and retrieval was successfully achieved using a modified technique. The majority of the “other” reported complications were attributed to tilting of the filter, strut perforation, or thrombosis. Multivariate analysis revealed that independent factors associated with retrieval complications were: older age (p = 0.024, OR = 0.975, 95 % CI = 0.953–0.997) and anticoagulation use (p = 0.046, OR = 0.385, 95 % CI = 0.151–0.982).
Postdeployment Complications
In general, filter complication rates were low, with an average complication rate of 3.5 %. There were, however, two reported major complications involving surgical removal of the filter. Pain associated with caval perforation led to surgical removal of a Cook Celect filter in one case. A further filter (Cook Gunther Tulip) required surgical removal following penetration through the caval wall during insertion. A third filter was removed at laparotomy performed for other reasons: penetration of the caval wall was noted at surgery.
Funnel plot analysis of overall postprocedure complications and filter-specific complications identified the rates associated with the Bard G 2 filter as lying outside 99.9 % control limits (average rate = 6.4 %). The outcomes for all other filter types fell within both 99.9 % control limits of the funnel plot (Fig. 4).
Filter Structural Failure
No instances of fracture or significant structural failure were reported.
Other Postdeployment Complications
The 27 filter complications described as “other” (18 patients) comprised 6 cases of IVC thrombosis, 7 of DVT, 3 possible puncture site complications and 11 apparently unrelated complications. No filter complications were reported with any of the permanent devices.
DVT is a known risk of IVC filter placement. The rate identified in this series was low <1 % (14/1,434), which may reflect under-reporting of this complication. There are differences between the postprocedure rates of DVT for Cook Celect versus Cordis OptEase (2-sided Fisher’s exact test; p = 0.004) and for Cook Gunther Tulip versus Cordis OptEase (2-sided Fisher’s exact test; p = 0.002), indicating a higher rate of thrombosis associated with the Cordis OptEase filter. Inexperience (performing <25 filter deployments) was statistically related to more complications (p < 0.001).
Multivariate analysis revealed independent factors associated with complications were a left internal jugular vein approach (p < 0.001, OR = 3.742, 95 % CI = 1.912–7.373), anticoagulation (p = 0.037, OR = 0.62, 95 % CI = 0.396–0.973), and inexperience (operator grade: <10 previous deployments (p ≤ 0.001, OR = 0.255, 95 % CI = 0.099–0.551) and 10–25 previous deployments (p ≤ 0.001, OR = 0.073, 95 % CI = 0.019–0.273)).
Long-term Complications
Filter Perforation of the Caval Wall
Perforation was more commonly reported with the Bard Recovery and G 2 filters than with other devices. Perforation was the reason for failure to retrieve the filter in five cases. In one case, a filter leg was noted to be located within the aortic wall. It was retrieved without adverse consequences. No instances of symptomatic penetration of adjacent organs were recorded in the registry. No perforations were seen with the Cordis filters. Perforation associated with each filter type was:
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Bard G2 14 %
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Bard Recovery 10 %
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Cook Gunther Tulip 2 %
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All others <0.3 %
Filter Migration
Contributors were asked to report migrations of >10 mm. A total of nine migrations were reported: four with Bard G 2 filter, three with the Cook Celect filter, and one each with the Bard Recovery and Cordis OptEase filters. Six episodes of migration occurred immediately postdeployment. In one case, caudal migration was associated with failure to retrieve the filter. One filter (Celect) deployed in a suprarenal location, migrated to the intrahepatic IVC, close to the right atrium and was retrieved. Migrations were noted in both cranial and caudal directions. There were no cases of embolization of IVC filters to the heart or pulmonary arteries.
Pulmonary Embolism and IVC or Lower Limb Thrombosis
Pulmonary embolism (PE) was reported in 16 cases during the follow-up period, and although this was reported to be the cause of death in 6, this was not supported by objective evidence in most instances following telephone consultation. Multivariate analysis revealed only one independent variable associated with recurrent PE, which was location: suprarenal (p = 0.041, OR = 373.636, 95 % CI = 1.265–519.241).
New lower limb DVT and/or IVC thrombosis was reported in 88 cases in total. Although immediate outcomes following filter placement showed some differences in DVT rates between devices, there were no statistically significant differences in the incidence of DVT between devices during the 3 years of follow-up (Fig. 5). Multivariate analysis revealed independent factors associated with recurrence of DVT were older age (p = 0.046, OR = 0.980, 95 % CI = 0.961–1.000) and placement intention – permanent (p = 0.013, OR = 1.222, 95 % CI = 1.001–1.411). When a filter was removed, there was no greater risk of pulmonary embolus than in those patients in whom the filter had been left in situ.
Multivariate analysis revealed complications at 12 months after insertion were related to older age (>75 years; p = 0.02, OR = 0.981, 95 % CI = 0.969–0.993), temporary IVC filter not removed at 1 year (p = 0.002, OR = 0.407, 95 % CI = 0.234–0.711) and juxtarenal location (p = 0.02, OR = 0.333, 95 % CI = 0.132–0.838). The use of the Cordis TrapEase IVC filter (p = 0.008, OR = 8.216, 95 % CI = 1.720–39.244) was associated with increased complications.
Mortality
The large group of patients who had a filter placed with the intention that it would be a permanent filter appear to have an elevated in-hospital mortality rate compared with those who had a filter inserted with the intention that it would be temporary (12.3 % vs. 4.3 % respectively; Table 2). However, the difference of mortality, both in-hospital and at 30 days, between temporary and permanent placements was probably due to difference in severity of the underlying disease.
The high mortality (257/1,434; 18 %) at 1 year where no retrieval was attempted was probably due to deterioration in the patient’s underlying clinical condition. There was no significant difference in mortality between patients who had failed versus successful retrieval.
Discussion
The BSIR IVC Filter Registry has provided a substantial body of information with regard to the current status of IVC filter usage in the UK. These data provide useful information to improve current practice and allow us to take steps to improve patient care.
IVC filters can broadly be divided into two groups: retrievable and permanent. Instructions for use state that retrievable IVC filters can be left in place permanently if desired. As a consequence, even where the intention was to leave the filter in place permanently, a retrievable filter was utilized in the majority of cases (73 %). This indicates that operators have confidence in the permanent deployment of retrievable filters. Convertible filters were recently introduced and can be changed from a filter configuration to a stent, once the filtering capability is no longer required. Following the introduction of convertible filters to the UK, contributors were given the opportunity to record this as an intention. In the event, no convertible filters were used.
The data indicated a significant learning curve associated with IVC filter insertion. Operators with experience of <25 IVC filter insertions were statistically more likely to have a complication. Although these were mostly minor, it is important for interventional radiologists to be aware of these and to receive appropriate training when using a new device. Furthermore, results suggest that, if the right femoral approach is not available, a right jugular approach is probably preferable to a left femoral approach and should be adopted in most instances.
The registry demonstrated an increased use of temporary IVC filters over the time of the registry, which may indicate an increasing reluctance to leave filters permanently or an increasing confidence in the retrievable devices for permanent or temporary use. The high proportion of temporary IVC filters (inserted with an intention that they would be temporary) in young patients reflects clinicians’ reluctance to leave foreign materials permanently in younger patients. Less than 50 % of filters inserted into pregnant women were confirmed to be removed. In some cases, retrieval may be impossible due to marked tilting of the filter in late pregnancy or during labor. Other cases may have been lost to follow-up. No attempt at retrieval for this group of patients should be considered inacceptable practice. The decision to implant a permanent IVC filter was related to the severity of the underlying condition and/or significant comorbidities. Those patients with severe underlying comorbidities and/or a poor prognosis were more likely to be considered for a permanent filter, presumably to limit the number of repeated interventions and hospital admissions in the later stages of their disease. Furthermore, the high mortality in patients considered for a permanent IVC filter suggests that a rapid decline in a patient’s health is related to inserting a permanent filter.
Most filters are intended to be located so that the apex lies centrally within the vena cava and some have design features to promote centring. The VenaTech Braun LGM filter has a number of parallel struts that lie along the caval wall to ensure centring. No tilting was observed with this filter in the few deployments that were reported. The Cordis filters also have parallel struts, but these are less rigid, so distortion and tilting can occur. Tilting was more frequently observed with the Cook filters, which have a conical shape. Tilting may occur at the moment of release of the filter from the delivery system if the delivery system is angulated in relation to the axis of the cava. It also may occur during detachment of the apical hook from the delivery system after jugular deployment of the Cook filters, especially with inexperienced hands and from a left IJV approach. Although one would expect centralized filters to be associated with a higher rate of successful retrieval, this effect has not reached statistical significance in the registry. Contrary to expectation, retrieval success of the Cook Celect and Tulip filters was unrelated to filter tilting at deployment, with success rates of approximately 80 % for all orientations. It is likely that tilting did not occur at the time of deployment, but it occurred at a later date. For the other filters in this registry, tilting was associated with a lower success rate of filter retrieval (p = 0.004).
There was a relationship between the rate of successful retrieval and the number of retrievals attempted. High-volume centers tended to achieve a better than average success rate. Older patients (>80 years) and the presence of significant comorbidity has been shown to be associated with a significantly reduced probability for attempted retrieval [11]. Retrieval was statistically more successful in our cohort if attempted <9 weeks (<62 days) from insertion. A time interval of >90 days between implantation and attempted retrieval also was associated with greater retrieval failure (OR 19.8, p = 0.009) in another recent study [11]. Interestingly, in those cases where there was retrieval failure a high proportion were within the time period defined by the manufacturers for retrieval, i.e., with the Bard G2 (100 %), Cook Celect (97 %), Cordis Optease (83 %), and Pyramed ALN (87.5 %; Table 1). This suggests that regardless of suggested dwell times IVC filters should be removed as soon as practically possible to reduce not only associated complications but also to reduce failure of retrieval rate.
The mechanism of filter retrieval varies between manufacturers. The Bard devices rely on trapping the apex of the filter in a cone. The Cook and Cordis filters require snaring of a small hook located on the apex (Cook) or base (Cordis) of the filter. Snaring the hook is difficult if the filter is tilted or the hook is embedded in the caval wall. Nonstandard retrieval techniques, such as using intra-arterial forceps, balloons to displace the apex, or wire loops passed through the filter, were employed in isolated cases when the apex could not be snared. With the exception of ALN, for which numbers were very small, the Bard filters combined had the highest rate of retrieval success, despite having the longest in-dwell times, but individually this did not reach statistical significance.
The use of IVC filters has grown steadily over the lifespan of the registry and is predicted to continue to increase. Generally, the most common indication for IVC filter insertion is PE with a contraindication to anticoagulation. However, we found that the most common reason for IVC filter insertion was preoperatively for DVT/PE, suggesting a better appreciation of clinicians for prophylactic IVC filter insertion. Furthermore, the prophylactic use of filters in patients affected by trauma has increased recently, especially with the availability of retrievable filters [3, 12]. However, in many series, the rate of retrieval of these filters has been low (30 %) [13]. Of 721 filters in the registry placed with the intention of retrieval, there was no retrieval information on 207. We do not know whether or not these filters were removed as intended. It is probable that some filters were placed with the intention of retrieval, but the patients were not referred back to the radiology department for this procedure and the filters were unintentionally left in place permanently. We believe that it is important that the radiologist who places a filter with the intention of retrieving it takes responsibility for ensuring that the patient is recalled for retrieval at a suitable interval. This is probably most easily achieved by prospectively arranging for patients to return for retrieval on the local hospital Radiology Management Systems (RMS). A recent study by Lee et al. [14] employing a radiologist-led retrieval algorithm encouraging clinicians to request IVC filter removal postinsertion did not find any statistical improvement in numbers of filter removed [14]. However, they noted that the radiology-led approach improved follow-up and documentation, ensuring that a clinical decision was made about how long the IVC filter was required and whether retrieval should be attempted, thus ensuring that patients were not lost to follow-up [14]. Another group has demonstrated improved IVC filter removal rates employing a mailing system to contact patients when it is time to remove their filter [15].
One of the concerns that the registry sought to address was whether retrievable filters inserted for permanent placement were as safe as filters specifically designed for permanent placement. A lower rate of filter-specific complications was observed with permanent than with retrievable filters, but overall complications were not statistically significantly different, indicating that the current UK practice of using temporary filters as permanent filters is safe. Furthermore, using temporary retrievable filters as permanent filters may allow removal if a complication arises at a later date.
The commonest filter complications consist of filter migration and caval wall perforation, which may have no clinical consequences. However, filter struts that penetrate the caval wall may occasionally cause symptoms due to penetration of adjacent organs. Caval wall penetration by IVC filter struts has been shown by another group to be correlated with retrieval failure, and this group also found that the Filter hook/IVC orientation was significantly related to successful retrieval [16]. Overall perforation rates were low in our series, but in the absence of systematic CT follow-up, perforation is likely to have been underreported. It is likely that asymptomatic perforation of the caval wall occurs with several filter types, and in the absence of a CT scan this is not easy to quantify. Durack et al. demonstrated that strut penetration of the caval wall is the rule rather than the exception and also that complications associated with it can be significant [17].
PE appears to be a rare event following IVC filter placement; however, the possibility of underreporting should be borne in mind. We found that when a filter was removed, there was no greater risk of PE than in those patients in whom the filter had been left in situ. This finding has been demonstrated by others who showed that new or recurrent PE was rare after retrieval of an IVC filter but was most likely to occur in patients who had severe DVT during filter implantation and/or in patients with a DVT that remained at the time of filter retrieval [18]. Recurrent DVT is a known risk factor following IVC filter placement. The proportion of these that can be attributed to the presence of the filter is speculative. A large thrombus in the filter might indicate successful trapping of a potentially fatal thrombus and, therefore, could be an indication that the filter has been effective. Following the PREPIC study, there is a known increased risk of DVT following the placement of IVC filters [19]. This is probably due to local trauma at the insertion site and/or change in flow dynamics in the IVC following filter placement. Alternatively, the filter itself may be a nidus for thrombus formation. Indeed, in some cases, thrombus was identified on the cranial side of the filter. There was no statistically significant difference in DVT rates found in this registry between those patients who had successful filter retrieval compared with those who had their filters left in place (p = 0.632).
The average in-hospital mortality rate following IVC filter placement is 8.1 %, indicating that this patient population is overall a high-risk group of individuals with most probably their mortality risk from underlying existing conditions.
One-year follow-up data was considered to be a very important aspect of this registry, and registrants were encouraged to complete the follow-up forms by regular email reminders. Despite this, 1-year follow-up data were missing in a substantial number of registered cases. Forty percent of patients who were discharged alive from the hospital following filter placement had no follow-up recorded in the registry.
Overall, the numerous contributors to this registry are to be congratulated on helping to produce the largest prospective collection of data on the practice of IVC filters placement in the world, which will help to direct future practice in the United Kingdom. There are several caveats, however, that we feel are important to discuss. First, not all UK centers participated in data collection and the proportion of cases registered by participating centers is not known. There was no independent external data monitoring and verification performed, and there were some instances of differences in interpretation of certain data items between participants. There was no systematic clinical or imaging protocol follow-up regime employed; thus, data on long-term filter integrity, migration, and caval wall perforation is derived from clinically driven investigations. These points detract from the quality of some of the data analysis and limit our confidence in some of the conclusions.
Conclusions
IVC filter use in the UK in the vast majority of patients follows accepted guidelines (CIRSE). IVC filter placement is normally a low-risk procedure, with a low major complication rate of <0.5 %. This report provides interventional radiologists with an improved understanding of the technical and clinical aspects of IVC filter placement and will help to improve practice and reduce the potential negative consequences of IVC filter placement so that we are better able to advise patients and referrers.
Recommendations
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If right femoral access is not available for the placement of an IVC filter, a right internal jugular vein approach should be used when possible.
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When an IVC filter has been placed with the intention of removal, procedures should be put in place to avoid the patient being lost to follow-up. This could be done by simply booking an appointment on the Radiology Information System to have the IVC filter removed.
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Filter retrieval is most successful before 9 weeks following deployment and patients should be booked for removal within this timeframe if clinically appropriate.
Contributors
- Addenbrooke’s Hospital, Cambridge:
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Andrew Winterbottom
- Aintree University Hospital, Liverpool:
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Aldo Camenzuli
- University Hospital Aintree:
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Elizabeth O’Grady
- Altnagelvin Area Hospital:
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Deirdre Campbell
- Ayr Hospital:
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Jean-Pierre Charon
- Barts & the Royal London:
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Deborah Low
- Barts and the Royal London Hos:
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Matthew Matson
- Bradford Teaching Hospitals Foundation Trust:
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Carolyn Jackson
- Churchill Hospital, Oxford:
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Philip Boardman
- City Hospital, Birmingham:
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Mark Moss
- Colchester General Hospital:
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Arun Joachim Sebastian
- Cumberland Infirmary, Carlisle:
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John Michael Harry Edge
- Cumberland Infirmary:
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Jonathan Poels
- Derriford Hospital, Plymouth:
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Patrick Sparrow
- Diana Princess of Wales Hospital, Grimsby:
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Ayman Elsayed
- Diana, Princess of Wales Hospital,:
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Richard W J Harries
- East Sussex Hospitals NHS Trust:
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Neil Barlow
- Freeman Hospital, Newcastle-upon-Tyne:
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Ralph Jackson
- Frimley Park Hospital, Surrey:
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Andrew Hatrick
- Gartnavel General Hospital, Glasgow:
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Sivanathan Chandramohan
- Gartnavel General Hospital:
-
Richard D Edwards
- Gartnavel General Hospital:
-
Christopher Hay
- Gartnavel General Hospital:
-
Ram Kasthuri
- Gartnavel General Hospital:
-
Jon Moss
- Gartnavel General Hospital:
-
Iain Robertson
- Gartnavel General Hospital:
-
Reddi Yadavali
- Glan Clwyd Hospital, Rhyl:
-
Charles McConnell
- Glan Clwyd Hospital - North Wales:
-
Elaine Moss
- Hairmyres Hospital, East Kilbride:
-
Samuel Millar
- Hairmyres Hospital:
-
Cliff Murch
- Harrogate Health Care NHS Trust:
-
David Scullion
- Hull Royal Infirmary:
-
Duncan Ettles
- Hull Royal Infirmary:
-
Raghuram Lakshminarayan
- Hull Royal Infirmary:
-
Graham John Robinson
- Hull Royal Infirmary:
-
Paul Scott
- Hull Royal Infirmary:
-
Vivek Shrivastava
- Ipswich Hospital:
-
Gary Picken
- Ispwich Hospital:
-
Patrick Whitear
- John Radcliffe Hospital, Oxford:
-
Susan Anthony
- John Radcliffe Hospital, Oxford:
-
Mark Bratby
- John Radcliffe Hospital:
-
Raman Uberoi
- Kingston Hospital NHS Trust:
-
Colin Eric Campbell Todd
- Leeds Teaching Hospital:
-
Chris Hammond
- Leeds Teaching Hospitals Trust:
-
David Kessel
- Leeds Teaching Hospitals Trust:
-
Tony Nicholson
- Leeds Teaching Hospitals Trust:
-
Jai Patel
- Leeds Teaching Hospitals Trust:
-
Simon McPherson
- Leeds Teaching Hospitals Trust:
-
Gillian Procter
- Leeds Teaching Hospitals:
-
Sapna Puppala
- Leicester Royal Infirmary:
-
Keith Blanshard
- Lister Hospital, Stevenage:
-
Christopher M P King
- Manchester Royal Infirmary:
-
Nicholas Chalmers
- Manchester Royal Infirmary:
-
Gerard Joachim Murphy
- Medway Maritime Hospital, Gillingham:
-
Zeljko Bosanac
- Mid Yorkshire Hospitals NHS Trust:
-
James Lenton
- Mid Staffordshire NHS Foundation Trust:
-
David Wells
- New Cross Hospital, Wolverhampton:
-
Jules Dyer
- Norfolk & Norwich Hospital:
-
Simon Girling
- North Bristol NHS Trust:
-
Lyn Jones
- Northampton General Hospital:
-
Ramita Dey
- Northampton General Hospital:
-
Davis Thomas
- Northern General Hospital, Sheffield:
-
Steven Thomas
- Papworth Hospital:
-
Deepa Gopalan
- Pinderfields Hospital, Wakefield:
-
Kanwar Gill
- Pinderfield:
-
Rishya Ranalingam
- Princess Royal University Hospital, Orpington:
-
Richard Carver
- Queen Alexandra Hospital, Portsmouth:
-
John Langham Brown
- Queen Alexandra Portsmouth:
-
Simon Coles
- Queen Elizabeth Hospital, Gateshead:
-
Colin Nice
- Queen Elizabeth, Gateshead:
-
Grace Timmons
- Rotherham NHS Foundation Trust:
-
Paul Spencer
- Royal Berkshire NHS Foundation Trust:
-
Farhan Ahmad
- Royal Berkshire NHS Foundation Trust:
-
Matthew Gibson
- Royal Bolton Hospital:
-
James Lay
- Royal Bournemouth Hospital:
-
Terry Stephen Creasy
- Royal Bournemouth Hospital:
-
John Oakes
- Royal Bournemouth Hospital:
-
David F C Shepherd
- Royal Cornwall Hospital, Truro:
-
John Hancock
- Royal Derby Hospital:
-
Peter Bungay
- Derbyshire Royal Infirmary:
-
Mario De Nunzio
- Derbyshire Royal Infirmary:
-
Graham Pollock
- Royal Gwent Hospital, Newport:
-
Christopher Chick
- Royal Gwent Hospital:
-
Brian Anthony Sullivan
- Royal Liverpool University Hospital:
-
Richard G McWilliams
- Royal Oldham Hospital:
-
Mahesh Kumar
- Royal Preston Hospital:
-
Elaine Hewitt
- Royal Surrey County Hospital, Guildford:
-
Fuad F Hussain
- Royal Victoria Hospital, Belfast:
-
Anton Collins
- Sheffield Teaching Hospital:
-
Peter Ellis
- Sheffield Teaching Hospital:
-
Peter Kennedy
- Sheffield Teaching Hospital:
-
John Bottomley
- Sheffield Teaching Hospitals:
-
Trevor Cleveland
- Sheffield Teaching Hospital:
-
Peter Gaines
- Sheffield Teaching Hospital:
-
Douglas Turner
- Shrewsbury & Telford Hospital NHS Trust:
-
David Hinwood
- South Manchester University Hospital NHS Foundation Trust:
-
Raymond Joel Ashleigh
- Southampton General Hospital:
-
David Thompson
- Southend Hospital:
-
Andrew Tanqueray
- Southern General Hospital, Glasgow:
-
Keith Osborne
- St George’s Hospital, London:
-
Anna-Maria Belli
- St Richard’s Hospital, Chichester:
-
Briony Burns
- St Richards Hospital:
-
Christopher Young
- Stirling Royal Infirmary:
-
Nikolas Arestis
- Stirling Royal Infirmary:
-
Emma Beveridge
- Torbay Hospital:
-
Peter Kember
- Torbay Hospital:
-
Richard Seymour
- University Hospital Wales, Cardiff:
-
Andrew Wood
- University Hospital, Birmingham Jonathan:
-
David Hopkins
- University Hospitals of Leicester NHS Trust:
-
Keith Blanshard
- Victoria Infirmary, Glasgow:
-
Andrew Downie
- West Suffolk NHS Trust:
-
Vinod Shenoy
- Wexham Park Hospital, Slough:
-
Mark Charig
- Wythenshawe Hospital, South Manchester:
-
Jonathan Tuck
- York Hospital:
-
Niall Warnock
Contributing Centres and Numbers of Patients Enrolled
Frequency | |
---|---|
Addenbrookes Hospital | 11 |
Aintree Hospital | 39 |
Altnagelvin | 1 |
Ayr Hospital | 6 |
Barts and the Royal London Hospital | 9 |
Bradford Teaching Hospitals Foundation Trust | 1 |
Churchill Hospital, Oxford | 19 |
City Hospital, Birmingham | 5 |
Colchester General Hospital | 4 |
Cumberland Infirmary | 33 |
Derbyshire Royal Infirmary | 98 |
Derriford Hospital Plymouth | 6 |
Diana, Princess of Wales Hospital, | 19 |
East Sussex Hospitals NHS Trust | 3 |
Freeman, Newcastle Upon Tyne Hospitals NHS Trust | 3 |
Frimley Park Hospital | 1 |
Gartnavel General Hospital | 56 |
Glan Clwyd Hospital—North Wales | 10 |
Hairmyres Hospital | 6 |
Harrogate Health Care NHS Trust | 8 |
Hull Royal Infirmary | 82 |
Ispwich Hospital | 48 |
John Radcliffe Hospital, Oxford | 33 |
Kingston Hospital NHS Trust | 17 |
Leeds Teaching Hospitals Trust | 105 |
Leicester Royal Infirmary Hospital | 2 |
Lister Hospital, Stevenage | 9 |
Manchester Royal Infirmary | 83 |
Medway Maritime Hospital | 1 |
Mid Yorkshire Trust | 11 |
Midstaffs NHS Foundation Trust | 15 |
New Cross Hospital, Wolverhampton | 8 |
Norfolk and Norwich | 13 |
North Bristol Hospitals | 1 |
Northampton General Hospital | 20 |
Northern General Hospital | 31 |
Papworth Hospital | 2 |
Princess Royal University Hospital | 6 |
Queen Alexandra, Portsmouth | 13 |
Queen Elizabeth, Gateshead | 55 |
Royal Berkshire NHS Foundation Trust | 29 |
Royal Bolton Hospital | 4 |
Royal Bournemouth Hospital | 32 |
Royal Cornwall Hospital Trust | 30 |
Royal Gwent Hospital | 19 |
Royal Liverpool University Hospital | 13 |
Royal Oldham Hospital | 10 |
Royal Preston Hospital | 6 |
Royal Surrey y Hospital | 3 |
Royal Victoria Hospital, Belfast | 103 |
Sheffield Teaching Hospital | 97 |
Shrewsbury and Telford Hospital NHS Trust | 7 |
South Manchester University Hospital NHS Foundation | 3 |
Southampton General Hospital | 3 |
Southend Hospital | 12 |
Southern General Hospital | 2 |
St Georges Hospital, London | 51 |
St Richards Hospital, Chichester | 20 |
Stirling Royal Infirmary | 5 |
Tameside Hospitals Foundation NHS Trust | 1 |
The Rotherham NHS Foundation Trust | 22 |
Torbay Hospital | 9 |
UHW Cardiff | 1 |
University Hospital, Birmingham | 13 |
University Hospitals of Leicester - NHS Trust | 1 |
Victoria Infirmary, Glasgow | 12 |
West Suffolk NHS Trust | 8 |
Wexham Park Hospital | 4 |
Wirral Hospital Trust | 2 |
Wythenshawe Hospital | 5 |
York Hospital | 13 |
Grand total | 1433 |
Change history
28 December 2017
On page 1553, the caption on Table 1 should read: Retrieval of filter by filter make/model and % retrievals within the manufacturer timescale.
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A correction to this article is available online at https://doi.org/10.1007/s00270-017-1865-0.
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Uberoi, R., Tapping, C.R., Chalmers, N. et al. British Society of Interventional Radiology (BSIR) Inferior Vena Cava (IVC) Filter Registry. Cardiovasc Intervent Radiol 36, 1548–1561 (2013). https://doi.org/10.1007/s00270-013-0606-2
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DOI: https://doi.org/10.1007/s00270-013-0606-2