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Initial Experience in Humans with a New Retrievable Inferior Vena Cava Filter¹

¹ From the Department of Medical Imaging, Mount Sinai Hospital/University Health Network, 600 University Ave, Suite 564, Toronto, Ontario, Canada M5G 1X5. From the 2001 RSNA scientific assembly. Received November 14, 2001; revision requested January 29, 2002; revision received March 12; accepted June 26. Supported in part by NMT Medical and C. R. Bard. Address correspondence to the author (e-mail: masch@mtsinai.on.ca).

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
PURPOSE: To evaluate preliminary clinical experience in humans with the Recovery nitinol filter (RNF) for the inferior vena cava, especially the efficacy of the device and safety of its retrieval.

MATERIALS AND METHODS: Thirty-two patients were followed up to assess for filter efficacy and for ability to remove the filter.

RESULTS: Sixteen men and 16 women aged 18–83 years (mean, 53 years) underwent treatment with the RNF. Indications for placement were recent pulmonary embolism (n = 16), recent deep venous thrombosis (n = 20), and/or prophylaxis (n = 2). Four patients had contraindications to anticoagulant therapy, and four had complications from anticoagulant therapy. The filter was successfully placed in 32 patients. In 24 (100%) of 24 patients, the filter was successfully retrieved with a jugular approach. The mean implantation period was 53 days (range, 5–134 days). Trapped thrombus was seen within the filter in seven cases. In one patient with a large trapped thrombus, the filter was noted to have migrated 4 cm cephalad. There were no episodes of pulmonary embolism or insertion-site thrombosis.

CONCLUSION: This preliminary experience in humans confirms the efficacy of the RNF. It also demonstrates the feasibility and safety of retrieval up to 134 days after implantation.

© RSNA, 2002

Index terms: Embolism, pulmonary, 60.72 • Venae cavae, filters, 982.1267 • Venae cavae, interventional procedures, 982.1267

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Anticoagulation is the accepted standard therapy in patients with venous thromboembolic disease. When contraindications to anticoagulant therapy are present, interruption of the inferior vena cava (IVC) can be performed to prevent the passage of large life-threatening emboli to the lungs. With the introduction of the Greenfield filter in 1973, placement of IVC filters has become accepted as the most common treatment alternative (1). Since the advent of devices that can be placed percutaneously, the number of filters inserted on a yearly basis has increased markedly (2,3). It has been specifically noted that there has been an increase in the implantation rate in young patients (2). Coincidentally, follow-up studies have revealed a 2%–19% incidence of late complications, often arising many years after filter placement (4,5). As the prevalence of patients with IVC filters has increased, so too have reports of guide wire entrapment with subsequent displacement of filters to the heart (6,7). Concerns about the long-term safety of IVC filters have resulted in the suggestion that permanent filters be avoided, especially in patients with a long life expectancy (8).

In many patients, the period of risk from anticoagulant therapy is relatively short. Other than the treatment of patients with widespread malignancy, there are few clinical situations that require placement of a lifelong IVC filter. Several studies have revealed that up to 30% of patients receive anticoagulant therapy following placement of an IVC filter (4,9). Decousus et al (10) demonstrated a reduction in the incidence of pulmonary embolism (PE) in patients with filters compared with patients treated with anticoagulant therapy at the 12-day mark, and no difference in outcome between patients with filters and those treated with standard anticoagulant therapy at 2 years. These researchers also observed an increased risk of recurrent deep venous thrombosis (DVT) in the patients treated with filter placement compared with those treated with anticoagulants alone (10). These data support the use of nonpermanent IVC filters.

There are two varieties of nonpermanent filters—temporary and retrievable. Temporary filters are attached to some form of tether, such as a guide wire or catheter, and thus must be removed (11). The anchoring mechanism of temporary filters often results in some degree of patient immobility and may also serve as a nidus for infection. If filter thrombosis occurs, a new, permanent filter must be placed. Retrievable filters may be left in place permanently or they may be retrieved, depending on what is appropriate for each individual clinical situation. Currently, the only retrievable device approved for use in Canada is the Gunther Tulip filter (Cook Canada, Stouffville, Ontario) (12,13). In their review of data from a multicenter registry, Lorch et al (14) state that filters that can be retrieved or left in place at the option of the physician would be an appropriate kind of temporary filter to use as long as the retrieval procedure was technically easy and had a low complication rate.

Although there are many differences between temporary and retrievable filters, all currently approved devices share a common limitation—length of residence prior to removal. Current instructions for use for most nonpermanent filters state that the filter must be removed within 10–14 days of placement. The predominant concern is the development of endothelialization, which would make subsequent removal impossible. Endothelialization has been shown to lead to explantation problems after as short a period as 12 days (15).

The Recovery nitinol filter (RNF) (NMT Medical, Boston, Mass), a retrievable IVC filter, is a new device (Fig 1). It is composed of 12 0.13-inch nitinol wires that extend from a nitinol sleeve. It has six arms and six legs. The resting diameter of each of the arms is 30.5 mm; the resting diameter of each of the legs is 32 mm. The filter measures 4 cm in height. It has undergone benchtop and animal testing since 1998. On the basis of the evidence that the filter is safe, effective, and retrievable up to 22 weeks after insertion, the purpose of this study was to evaluate our preliminary clinical experience with the efficacy of this filter and the safety of its retrieval in humans.

View larger version (137K): [in this window] [in a new window] [Download PPT slide]   Figure 1. RNF retrievable IVC filter. (Original magnification, x3.) The device is manufactured from nitinol wire of 0.013 inch in diameter. It is 4 cm in height, and the base can accommodate a vena cava up to 28 mm in diameter. There is dual-level filtration from both the arms and the legs.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The filters were placed at multiple sites of a multiinstitutional medical imaging department by a single staff vascular and interventional radiologist (M.R.A.). The timing of filter removal was coordinated with the referring physician and/or with special referral to a hematologist. The decision regarding return to anticoagulant therapy was usually made by the referring physician on the basis of his or her assessment of the risk of bleeding versus concern regarding propagation of lower-extremity DVT. All 32 patients who received filters (two patients were found to have anatomic conditions unfavorable for filter placement) had the decision to return to anticoagulant therapy made for them in this fashion. In cases in which it was deemed that filter removal had to be postponed beyond 12 weeks for a medical indication, specific approval from both the ethics department and the Health Protection Branch was sought and granted.

All procedures were performed with standard sterile technique. Conscious sedation was achieved with midazolam (Versed; Sabex, Boucherville, Quebec, Canada) and fentanyl citrate (Sublimaze; Faulding, Dorval, Quebec, Canada), which were simultaneously administered at the patient’s request. All devices were placed via the femoral vein on the side contralateral to the side of venous thrombosis, if present. Access was obtained with real-time ultrasonographic (US) control and a 19-gauge single-wall puncture needle (Cook Canada) after local anesthetic with 1% xylocaine (Lidocaine; AstraZeneca, Mississauga, Ontario, Canada) had been applied to the puncture site. A 5-F pigtail catheter (Cook Canada) was subsequently advanced over a 0.035-inch standard J-tip guide wire (Cook Canada), and digital subtraction angiography of the IVC was performed in frontal and lateral projections with hand injection only. The IVC was measured in both planes with a ruler, a dime, or a calibrated catheter and was assessed for duplication and thrombosis. The number and position of the renal veins were also noted. Selective renal vein catheterization was not performed. The filter was not placed if the corrected diameter of the vena cava exceeded 28 mm.

In a single instance, the filter was placed by means of a portable C arm in the intensive care unit as a result of concern that this ventilated patient could not tolerate transfer to the interventional suite. In this case, right-sided access was impossible because of the presence of a previously unsuspected iliac venous thrombosis. There was an indwelling left femoral venous line, so a new, separate left femoral puncture was performed. This patient was already undergoing prophylactic broad-spectrum antibiotic therapy for his underlying condition, and he did not subsequently develop signs of sepsis secondary to the procedure.

Following placement of the 6-F introducer sheath, the filter was advanced and deployed with a technique similar to that used with the Simon nitinol filter (NMT Medical). The sheath and filter reservoirs were primed with a standard heparin and saline flush prior to placement. Neither a drip infusion nor iced saline was used. The filter was released by maintaining the position of the pusher while retracting the sheath at the target site. This filter does not shorten when it opens; this allows for accurate deployment at the target. Follow-up digital subtraction angiography of the IVC was performed in both frontal and lateral projections to assess for filter alignment with the caval axis and to confirm the position of the filter with respect to the renal veins (Fig 2). The sheath was then removed, and hemostasis was achieved. Subsequent anticoagulant therapy was commenced at the discretion of the referring physician.

View larger version (96K): [in this window] [in a new window] [Download PPT slide]   Figure 2a. Vena cavograms depict filter placement. (a) Frontal scout view obtained just before the postinsertion vena cavogram shows the highly visible nitinol RNF filter with its tip at the L1-2 interspace (black arrow). Note the radiopaque marker band on the tip of the insertion sheath (white arrow). (b) Frontal postinsertion vena cavogram demonstrates that the filter is aligned with the caval axis, with its tip approximately 1 cm caudal to the right renal vein (arrow). (c) Lateral vena cavogram demonstrates alignment in this plane as well.

View larger version (112K): [in this window] [in a new window] [Download PPT slide]   Figure 2b. Vena cavograms depict filter placement. (a) Frontal scout view obtained just before the postinsertion vena cavogram shows the highly visible nitinol RNF filter with its tip at the L1-2 interspace (black arrow). Note the radiopaque marker band on the tip of the insertion sheath (white arrow). (b) Frontal postinsertion vena cavogram demonstrates that the filter is aligned with the caval axis, with its tip approximately 1 cm caudal to the right renal vein (arrow). (c) Lateral vena cavogram demonstrates alignment in this plane as well.

View larger version (107K): [in this window] [in a new window] [Download PPT slide]   Figure 2c. Vena cavograms depict filter placement. (a) Frontal scout view obtained just before the postinsertion vena cavogram shows the highly visible nitinol RNF filter with its tip at the L1-2 interspace (black arrow). Note the radiopaque marker band on the tip of the insertion sheath (white arrow). (b) Frontal postinsertion vena cavogram demonstrates that the filter is aligned with the caval axis, with its tip approximately 1 cm caudal to the right renal vein (arrow). (c) Lateral vena cavogram demonstrates alignment in this plane as well.

Removals were performed with standard aseptic technique and conscious sedation protocols similar to those used in filter insertion. All procedures were performed via the right jugular vein with real-time US control. Initially, a 5-F pigtail or multipurpose catheter, advanced over a guide wire, was placed in a location below the filter so that digital subtraction angiography of the vena cava could be performed in both frontal and lateral projections. The angiograms were assessed for filter position and tilt with respect to the caval axis and to identify trapped thrombus. Following insertion of a 0.035-inch Amplatz extrastiff straight guide wire (Boston Scientific, Mississauga, Ontario, Canada), the 10-F retrieval sheath was placed. It was occasionally necessary to predilate the tract with a 10-F Coons dilator (Cook Canada). The retrieval cone (Fig 3) was then advanced through the sheath and docked with the filter tip so that the filter could be retracted into the sheath and removed.

View larger version (104K): [in this window] [in a new window] [Download PPT slide]   Figure 3. Retrieval cone, which is constructed with nine metal claws covered by a urethane cover. The open diameter of the cone is 15 mm. A central lumen allows for over-the-wire placement. The cone is inserted via the jugular vein through a 10-F profile catheter with a radiopaque band on its end.

Following removal, a repeat vena cavogram was obtained to assess for procedural trauma or any other complication related to filter residence. The filters were examined for trapped thrombus, endothelium formation, and mechanical damage. The sheath was then removed and hemostasis was achieved. Anticoagulant therapy was restarted under the direction of the referring physician or attending hematologist. The filters were returned to the manufacturer (NMT Medical) so that a complete assessment of device integrity could be performed.

Follow-up
Abdominal radiography 1 and 7 days after placement, then yearly, was recommended per our protocol for follow-up after placement of permanent IVC filters. No other routine follow-up imaging studies were performed because this device was placed on a compassionate basis, not under the confines of a scientific study protocol. However, in any patient in whom an adverse event was clinically suspected, appropriate imaging studies were performed (Fig 4). In patient 10 and all subsequent patients, routine follow-up abdominal radiographs were obtained to assess for possible filter migration. This change in protocol was instituted after identification of an episode of asymptomatic migration of the filter in patient 9. It was specifically requested that these radiographs be sent directly to the author to enable direct comparison of the position of the filter on subsequent radiographs with its position on radiographs obtained at the time of placement.

View larger version (121K): [in this window] [in a new window] [Download PPT slide]   Figure 4. Follow-up transverse contrast material-enhanced spiral computed tomographic (CT) scan obtained as part of this patient’s routine medical care 2 weeks after placement of an RNF shows the filter to be in good position, with no associated complication.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Placement of a temporary filter was requested in a total of 34 patients. In one patient, the corrected caval diameter measured 33 mm on the vena cavogram. The referring physician did not want placement of a permanent filter, so no filter was placed in that individual. In one patient with DVT who was scheduled for orthopedic surgery, there was congenital interruption of the vena cava with hemiazygous continuation, so no filter was placed. In all other instances, patients consented and received the RNF (Table 1). Mean patient age was 53 years (range, 18–83 years). There were 16 male and 16 female patients. A diagnosis of DVT was confirmed with color Doppler US in 23 patients; 18 patients had right-sided DVT, and five patients had left-sided DVT. A diagnosis of PE was confirmed in 15 patients at CT angiography.

Sixteen patients had been given an underlying diagnosis of malignant neoplasm. Patients were referred from the departments of orthopedic surgery (n = 9), surgical oncology (n = 6), general surgery (n = 3), respirology (n = 3), intensive care (n = 2), internal medicine (n = 4), nephrology (n = 2), cardiology (n = 1), neurosurgery (n = 1), and medical oncology (n = 1) (Table 2). Fifteen patients (47%) received concomitant anticoagulant therapy for some period of time while the filter was in place.

In the placement of 17 (74%) of the first 23 filters, there was some difficulty in releasing the filter legs from the splines of the stabilizer arm. This was overcome by moving the introducer sheath in a gentle twisting motion. This problem had not been encountered in animal testing. Investigation by employees of NMT Medical revealed that the polishing process during manufacturing resulted in a "rolling over" of the edges of the splines, which caused the filter legs to tend to catch when the device was angulated at the time of attempted release. After the tumbling process was changed, the release problem did not recur.

Tilt of the filter with respect to the caval axis (defined as tilt > 15°) was encountered in two (6%) of 32 deployments. The tilt was 20° and toward the side contralateral to the venous puncture in both cases. Each instance of tilt occurred in the first 23 placements, with associated difficulty in release from the splines.

Complications and Filter Removal
No patient developed a substantial puncture-site hematoma or any other complication related to filter insertion or removal. No patient developed symptomatic PE or insertion-site DVT following filter placement or removal (Table 3). One patient with a preoperatively placed filter experienced left-sided hemiplegia 10 hours after surgical revision of a fractured hip prosthesis. Her symptoms completely resolved, and a thorough neurologic evaluation revealed that she had had a transient ischemic attack unrelated to the filter. The filter in this patient was found to contain a small thrombus at the time of an abdominal CT examination.

View larger version (116K): [in this window] [in a new window] [Download PPT slide]   Figure 5a. Thrombus removal. (a) Vena cavogram obtained with a 5-F multipurpose catheter inserted via the right internal jugular vein at the time of filter removal (10 days after placement) reveals a small trapped embolus within the filter (arrow). (b) Gross specimen obtained after removal of filter and embolus with a standard 10-F sheath. Note embolus trapped by filter legs.

View larger version (130K): [in this window] [in a new window] [Download PPT slide]   Figure 5b. Thrombus removal. (a) Vena cavogram obtained with a 5-F multipurpose catheter inserted via the right internal jugular vein at the time of filter removal (10 days after placement) reveals a small trapped embolus within the filter (arrow). (b) Gross specimen obtained after removal of filter and embolus with a standard 10-F sheath. Note embolus trapped by filter legs.

View larger version (140K): [in this window] [in a new window] [Download PPT slide]   Figure 6a. Filter migration and clot capture. (a) Abdominal radiograph obtained 1 day after filter placement shows that the filter tip is at the level of the pedicle of L1 (arrow). The surgical clips are from vascular repair after coronary artery stent placement, which was performed prior to filter placement. (b) Routine abdominal radiograph obtained 5 days after filter placement shows that the filter tip is now at the level of the pedicle of T12 (arrow). (c) Vena cavogram obtained at the time of planned filter removal 17 days after placement shows a large embolus within the filter (arrow). Note flow defect from left renal vein. (d) Frontal image shows that the 10-F removal sheath (curved arrow) has been advanced over an Amplatz wire and inserted through a 20-F vascular sheath (straight arrow) for filter retrieval. (e) Gross specimen of filter and trapped clot. The filter deformity occurred at the time of removal from the sheath.

View larger version (145K): [in this window] [in a new window] [Download PPT slide]   Figure 6b. Filter migration and clot capture. (a) Abdominal radiograph obtained 1 day after filter placement shows that the filter tip is at the level of the pedicle of L1 (arrow). The surgical clips are from vascular repair after coronary artery stent placement, which was performed prior to filter placement. (b) Routine abdominal radiograph obtained 5 days after filter placement shows that the filter tip is now at the level of the pedicle of T12 (arrow). (c) Vena cavogram obtained at the time of planned filter removal 17 days after placement shows a large embolus within the filter (arrow). Note flow defect from left renal vein. (d) Frontal image shows that the 10-F removal sheath (curved arrow) has been advanced over an Amplatz wire and inserted through a 20-F vascular sheath (straight arrow) for filter retrieval. (e) Gross specimen of filter and trapped clot. The filter deformity occurred at the time of removal from the sheath.

View larger version (107K): [in this window] [in a new window] [Download PPT slide]   Figure 6c. Filter migration and clot capture. (a) Abdominal radiograph obtained 1 day after filter placement shows that the filter tip is at the level of the pedicle of L1 (arrow). The surgical clips are from vascular repair after coronary artery stent placement, which was performed prior to filter placement. (b) Routine abdominal radiograph obtained 5 days after filter placement shows that the filter tip is now at the level of the pedicle of T12 (arrow). (c) Vena cavogram obtained at the time of planned filter removal 17 days after placement shows a large embolus within the filter (arrow). Note flow defect from left renal vein. (d) Frontal image shows that the 10-F removal sheath (curved arrow) has been advanced over an Amplatz wire and inserted through a 20-F vascular sheath (straight arrow) for filter retrieval. (e) Gross specimen of filter and trapped clot. The filter deformity occurred at the time of removal from the sheath.

View larger version (99K): [in this window] [in a new window] [Download PPT slide]   Figure 6d. Filter migration and clot capture. (a) Abdominal radiograph obtained 1 day after filter placement shows that the filter tip is at the level of the pedicle of L1 (arrow). The surgical clips are from vascular repair after coronary artery stent placement, which was performed prior to filter placement. (b) Routine abdominal radiograph obtained 5 days after filter placement shows that the filter tip is now at the level of the pedicle of T12 (arrow). (c) Vena cavogram obtained at the time of planned filter removal 17 days after placement shows a large embolus within the filter (arrow). Note flow defect from left renal vein. (d) Frontal image shows that the 10-F removal sheath (curved arrow) has been advanced over an Amplatz wire and inserted through a 20-F vascular sheath (straight arrow) for filter retrieval. (e) Gross specimen of filter and trapped clot. The filter deformity occurred at the time of removal from the sheath.

View larger version (143K): [in this window] [in a new window] [Download PPT slide]   Figure 6e. Filter migration and clot capture. (a) Abdominal radiograph obtained 1 day after filter placement shows that the filter tip is at the level of the pedicle of L1 (arrow). The surgical clips are from vascular repair after coronary artery stent placement, which was performed prior to filter placement. (b) Routine abdominal radiograph obtained 5 days after filter placement shows that the filter tip is now at the level of the pedicle of T12 (arrow). (c) Vena cavogram obtained at the time of planned filter removal 17 days after placement shows a large embolus within the filter (arrow). Note flow defect from left renal vein. (d) Frontal image shows that the 10-F removal sheath (curved arrow) has been advanced over an Amplatz wire and inserted through a 20-F vascular sheath (straight arrow) for filter retrieval. (e) Gross specimen of filter and trapped clot. The filter deformity occurred at the time of removal from the sheath.

Three patients died of their underlying disease with the filter in place 15 to 59 days (average, 38 days) after placement without clinical evidence of PE. Autopsy information was not available for any of these patients. One filter was removed intraoperatively as a result of a surgical mishap during attempted resection of a large retroperitoneal sarcoma. Twenty-four filters were removed 5–134 days (mean, 53 days) after insertion; as of this writing, four remain in place for planned removal. All attempted filter removals were successful (Fig 7). Once the sheath was in place, filter retrieval always took less than 2 minutes. Several patients noted momentary mild epigastric or back pain at the time the filter was removed. Otherwise, the majority felt only some manipulation of the jugular venous sheath.

View larger version (99K): [in this window] [in a new window] [Download PPT slide]   Figure 7a. Sequence of vena cavograms illustrates the technique of removing a filter with a wire. (a) The retrieval cone is advanced over a wire, (b) the filter arms are engaged, and (c) the filter is retrieved.

View larger version (98K): [in this window] [in a new window] [Download PPT slide]   Figure 7b. Sequence of vena cavograms illustrates the technique of removing a filter with a wire. (a) The retrieval cone is advanced over a wire, (b) the filter arms are engaged, and (c) the filter is retrieved.

View larger version (95K): [in this window] [in a new window] [Download PPT slide]   Figure 7c. Sequence of vena cavograms illustrates the technique of removing a filter with a wire. (a) The retrieval cone is advanced over a wire, (b) the filter arms are engaged, and (c) the filter is retrieved.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
The RNF IVC filter is manufactured by NMT Medical. Constructed of nitinol, this filter is modeled after the dual-level structure of the Simon nitinol filter, which NMT Medical also manufactures. Several designs of a temporary retrievable filter were investigated before the current design for the RNF was conceived in 1998. One of the key features of the RNF that allows for retrieval many months after implantation is the hook design. The hooks of this filter were specifically designed, modeled, and tested to resist filter migration. The RNF underwent extensive benchtop and animal evaluation before it was first placed in a human patient (16).

Interest in a retrievable IVC filter has intensified since the first reported successful retrieval of an Amplatz filter (William Cook Europe, Bjaeverskov, Denmark) by Darcey et al in 1986 (17). However, this device was withdrawn from sale as a result of a high rate of vena caval thrombosis (18). There are currently a variety of tethered removable filters available in North America; however, they are not commonly placed as a result of their intrinsic design limitations.

The medical need for a retrievable filter design is demonstrated by the off-label use of currently approved permanent filters. Cope et al (19) described partial deployment of a Bird’s Nest filter (Cook, Bloomington, Ind) during thrombolysis of iliocaval thrombus. The filter was safely removed 6.5 hours later (19). More recently, Nutting and Coldwell (20) completely deployed a TrapEase filter (Cordis, Miami, Fla), also for temporary protection during thrombolysis. Nutting and Coldwell described using a combined jugular and femoral venous approach to retrieve the filter after the procedure (20).

Although these maneuvers have proven to be successful in these case reports, they clearly contravene the manufacturer’s instructions for use and place the patient at risk for a complication or failure of removal. A more common indication for filter removal is filter migration, either occurring at the time of implantation or seen at follow-up (21–23). Perhaps less common as an indication for removal is filter infection. Millward et al (24) reported a death attributed to an infected filter (Vena Tech; B Braun, Mississauga, Ontario, Canada). More recently, Lin et al (25) reported the successful removal of an infected Gunther Tulip filter 14 days after implantation. Another indication well suited for a retrievable IVC filter is that of trauma (26,27).

The Gunther Tulip filter was approved for both permanent placement and retrieval in Canada in March 1998. In the United States, it is approved for permanent use. Although the instructions for use state that the filter should be removed by 10 days, Millward et al (28) have reported removal up to 25 days after implantation. However, in an earlier animal study, one of 21 Gunther Tulip filters could not be retrieved 14 days after insertion as a result of adherence to the caval wall (29). Recently published data from the registry of the Canadian Interventional Radiology Association regarding the placement of 91 Gunther Tulip filters currently represent the most extensive experience with that device (28). In that series, one filter could not be retrieved because the hook could not be engaged by the snare. Fifty-two filters were successfully removed at a mean of 9 days after placement. Of the 37 patients who were followed up, four required reinsertion of a permanent filter at a mean of 78 days after removal. Filters were not removed from 17 patients as a result of ongoing contraindications to anticoagulant therapy (28). These results support the need for a filter that can be removed well beyond a 10–15-day window.

The perfect temporary IVC filter would be one that has high clot-trapping efficacy but a low incidence of caval thrombosis. It would have to be nonmigratory yet be able to be retrieved at a time distant from the time of insertion. Finally, there should be no external tether to limit patient mobility or serve as a nidus for infection. While intimal hyperplasia is expected to occur with any implanted device, there are filter design factors that would limit the associated adverse effects. It is the author’s hypothesis that the ability to retrieve a filter without concern for the amount of hyperplasia requires a filter to have little metal in contact with the caval wall.

Filter design is also important. If one looks at the design of the Gunther Tulip filter or the TrapEase filter, it becomes evident that the complex metal matrix would serve to anchor the filter in place when hyperplasia occurs. On the other hand, the design of the RNF allows for the filter arms to slide out of any potential sleeve once the elastic leg hooks have been removed from the caval wall. The animal data demonstrating the ability to remove an RNF at 22 weeks, coupled with the fact that one was removed from a human at 134 days, suggest that there is no upper limit to the time of retrieval with the current design. In contrast, studies of virtually all other filter designs included cases in which the filter could not be removed 2 weeks after insertion (15,29). Given that intimal hyperplasia stabilizes at approximately 3–6 weeks, one would expect that beyond that time filter fixation is not an issue.

The simple fact that a retrievable device is available is of limited clinical importance if that device must be removed by 10–15 days after placement. In the ideal situation, a patient could safely undergo anticoagulant therapy after surgery. However, even from this relatively small series, it is clear that many patients have more complex situations and require a much longer period of time before they can be maintained on uninterrupted therapeutic doses of anticoagulants. Several of the patients referred from orthopedics who underwent routine surgery to install a joint prosthesis had not resumed full ambulation even at 90 days after filter placement. Patients referred from general surgery often require follow-up procedures (such as percutaneous abscess drainage or a second surgical procedure) after surgery.

Although the most common device used for percutaneous removal of foreign bodies is some type of snare, techniques used with this device are not always successful. In the series of Millward et al (28), there was one failed retrieval as a result of the position of a Gunther Tulip filter hook with respect to the caval wall. In spite of moderate angulation in several cases in this series, all filters were easily and successfully retrieved. The urethane-covered claws modeled into a cone shape enabled the efficient engagement and retrieval of the RNF. The ability to pass a 0.035-inch wire through the central lumen of the cone greatly facilitated the docking procedure when there was no straight-line access to the filter tip. As our experience grew, changes in technique occurred. During the final four retrievals, the catheter was intentionally manipulated toward the side of filter tilt and the cone was always advanced over a wire. In this way, no additional maneuvers were required to engage the filter and cone.

There was a single occurrence (3%) of asymptomatic filter migration in this series of 32 patients. Migration is typically defined in the literature as movement greater than 2 cm. The reported incidence has been shown to vary between less than 1% and 13% and typically includes spontaneous migration to the heart (4,24,30,31). In our study patient, the filter was seen to be in a position several centimeters cranial to the insertion position on the radiograph obtained 5 days after insertion. However, the typed radiology report simply stated "An IVC filter is in place." At the time of planned removal at 17 days, the filter was seen to have migrated an additional 2 cm craniad. The vena cavogram obtained before removal revealed a large trapped embolus. It was possible to remove this filter and trapped embolus with the standard retrieval cone introduced through a 20-F sheath. That event was reported to the Health Protection Branch and to our institutional review board, and the consent form was subsequently modified to include information on it.

As a precaution, all subsequent patients underwent follow-up abdominal radiography to assess for filter migration. This fact was emphasized to both the referring physician and the patient. It was requested that all radiographs be sent directly to the author so that he did not have to rely on the dictated report. No other instance of filter migration was encountered. In one patient, several filter arms were seen to lie outside of the vena cava (at venography and CT). However, this patient was asymptomatic, and the filter was easily removed (at 134 days). This patient had undergone an abdominal surgical procedure 2 days after filter placement. Filter penetration of the caval wall has been reported to occur with an incidence of 9% (4).

Although in the present study, filters were placed on a compassionate basis—outside a formal scientific trial—patients were followed up prospectively. Given that this study represents the initial human use of a new medical device, patients were also promptly and thoroughly examined for any questionable complication. A number of patients underwent CT examination of the abdomen after filter placement and removal to assess for local complications; none was encountered.

In this series of 32 patients, filter efficacy was demonstrated by the fact that there were no episodes of PE and that trapped embolus was seen within the filter in seven cases. Complications such as caval occlusion or insertion-site thrombosis did not occur. The filter was successfully removed in all patients, even when a large trapped thrombus was present. The average time to filter removal in our experience (53 days) is well beyond the residence period for other removable/retrievable filters. The complexity of the clinical situation in these patients is shown by the need to maintain the filter in place for more than 100 days in two of our patients. The ability to remove this filter after such lengthy residence will likely prove to be important and will allow the majority of patients to receive a temporary filter instead of the permanent device used as part of the current standard of treatment. A large multicenter scientific study is warranted to further substantiate the role and value of this retrievable filter.

In conclusion, this preliminary, special-access use of the RNF, a retrievable IVC filter, suggests that the filter can easily be delivered via a femoral vein. It can be removed percutaneously up to 134 days after insertion without difficulty. No substantial complications were encountered in this series. Specifically, there were no documented incidents of PE, caval thrombosis, or insertion-site DVT with the filters in place. Retrieval via the jugular vein allows for removal of filters with small-to-large trapped thrombi.

	ACKNOWLEDGMENTS

 
The author gratefully acknowledges Rob Carr, BSc, Paul Stagg, BA, and Monica Coutanche, RN, for ongoing assistance during the study. Special thanks also to John Kaufman, MD, and Rob Carr for manuscript review.

	FOOTNOTES

 
Abbreviations: DVT = deep venous thrombosis, IVC = inferior vena cava, PE = pulmonary embolism

Author contribution: Guarantor of integrity of entire study, M.R.A.

	REFERENCES

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 

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