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Inferior Vena Cava Filters in Pregnancy: A Systematic Review
REVIEW ARTICLE
Inferior Vena Cava Filters in Pregnancy: A Systematic Review Sally A. Harris, MBChB, BSc, Rahul Velineni, BSc, MBBS, MRCS, and Alun H. Davies, MA, DM, DSc, FRCS, FEBVS, FACPH
ABSTRACT During pregnancy, patients have an increased risk of venous thromboembolism (VTE). This is an important cause of maternal mortality. Inferior vena cava (IVC) filters can be used to prevent pulmonary embolism in complicated cases of VTE during pregnancy. The present systematic review includes all patients reported in the literature who had an IVC filter placed during pregnancy. The indications for IVC filters are discussed, along with practical considerations for placement during pregnancy, filter effectiveness, and maternal and fetal mortality and morbidity. IVC filters can be used safely when appropriate during pregnancy, with complication rates similar to those in nonpregnant patients.
ABBREVIATIONS DVT = deep vein thrombosis, IVC = inferior vena cava, MeSH = Medical Subject Heading, PE = pulmonary embolism, VTE = venous thromboembolism
During pregnancy, patients are more predisposed to thromboembolic events because of hypercoagulability caused by adaptations in the hemostatic system in preparation for the hemostatic challenge of delivery, venous stasis caused in part by the pressure effect of the enlarging uterus, and vascular endothelial damage caused by distension or surgical injury. Venous thromboembolism (VTE) is the third most common direct cause of maternal mortality in the United Kingdom, occurring in 0.79 per 100,00 maternities in 2005–2008 (1). The standard treatment is anticoagulation with low molecular weight heparin until at least 6 weeks postpartum (2). Warfarin is avoided in pregnancy because it can cross the placental barrier and lead to fetal complications, including malformations and death (3). There are now increasing numbers of reported use of inferior vena cava (IVC) filters during pregnancy.
From the Department of Academic Surgery (S.A.H., R.V., A.H.D.), and Section of Vascular Surgery (R.V., A.H.D.), Imperial College London, Charing Cross Hospital, Fulham Palace Road, London W6 8RF, United Kingdom. Received July 27, 2015; final revision received October 31, 2015; accepted November 1, 2015. Address correspondence to A.H.D.; E-mail: [email protected] Table E1 is available online at www.jvir.org. None of the authors have identified a conflict of interest. & SIR, 2015 J Vasc Interv Radiol 2015; XX:]]]–]]] http://dx.doi.org/10.1016/j.jvir.2015.11.024
The first reported IVC filter placed in a pregnant patient occurred in 1981 (4). Initially, permanent filters were used. However, in pregnancy, the patient normally has a long life expectancy and the increased risk of VTE is generally temporary, so removable filters are attractive (5). The present systematic review will collate the information on the use of IVC filters during pregnancy.
MATERIALS AND METHODS This systematic review was performed in accordance to the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (6). The focus of the review was pregnant patients who had an IVC filter placed during pregnancy, excluding those who had an IVC filter before conception or in the postpartum period. Outcome measures included maternal and fetal morbidity and mortality. PubMed, Cochrane database, Embase and Ovid Medline databases were searched using a search strategy developed to identify all papers about IVF filter placement in pregnancy regardless of study design as follows: (filter, inferior vena cava [Medical Subject Heading (MeSH) Terms]) AND (pregnancy [MeSH Terms]) OR (obstetrics [MeSH Terms]). The search included all articles published through December 2014. The titles and abstracts of the resulting articles were reviewed and screened for relevance. Duplicate publications, articles not published in English, and abstracts from conferences were removed. All references of included
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manuscripts were manually searched to identify related articles that had not been identified. Data were extracted to compile a database of all reported pregnancies in which an IVC filter was placed. When possible, patient age, parity, indication for IVC filter placement, IVC filter position, gestation at insertion, filter type, time of retrieval, mode of delivery, fetal outcome, and maternal morbidity and mortality were recorded.
RESULTS The database search located 332 publications. After screening, 52 publications were located. After review of their references, a further three were found. Full texts were then examined for eligibility. This resulted in 11 exclusions: conference abstracts, reports of postpartum IVC filter insertion and superior vena cava filter insertion, and inability to identify the pregnant patients in a series. The remaining 44 articles were case reports or case series from a particular institution. There were no randomized controlled trials, and consequently no studies were amenable to pooling for meta-analysis. From these manuscripts, 135 pregnancies in which an IVC filter was inserted were identified. However, a case series of 18 patients (7) overlapped with and included all 11 patients in an earlier series (8). Therefore, the present review includes a total of 124 pregnancies (Table E1, available online at www.jvir.org) (4,5,7–48).
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risk of PE is particularly high (51). This is not acknowledged as a relative indication specifically by SIR but could be considered an extension of “high risk of complication of anticoagulation” (49). Other publications referred to the relative indications of unstable, floating, large DVTs near the time of delivery (4,7,8,15,32,33,36–43) or threatened preterm labor (16) and those with clots in or extending into the IVC (44). More recently, IVC filters have been inserted as protection against PE during endovascular procedures (45–47) or thrombolysis (48) carried out during pregnancy. No prophylactic indications have been reported, but one group (17) suggested that, in patients with high-risk thrombophilias, prophylactic placement of a temporary IVC filter could be performed before labor; however, we are aware of no studies that support this. The British Society for Haematology IVC filter guidelines (52) state that “insertion may be considered in pregnant patients who have contraindications to anticoagulation and develop extensive VTE shortly before delivery (within 2 weeks).” This does not encompass the range of indications seen in the present review. The Royal Society of Obstetricians and Gynaecologists VTE guidelines (2) recommend to “consider use of a temporary IVC filter in the peripartum period for patients with iliac vein VTE or in patients with proven DVT and who have recurrent PE despite adequate anticoagulation,” which is more reflective of the current literature.
Indications
Placement
The Society of Interventional Radiology (SIR) recognizes absolute and relative indications for filter placement in confirmed VTE in addition to prophylactic indications (49). In the cases identified, the rationale for IVC filter placement is not always clear, but the most common indications were selected and considered in these categories. As in nonpregnant patients, IVC filters were inserted for the absolute indications of failure of medical therapy for VTE despite adequate anticoagulation (5,8,10–23) and complications of anticoagulation, including heparininduced thrombocytopenia (7,15,23,24), heparin allergy (25), significant bleeding during anticoagulation (7,8,20, 23,26), and contraindication to anticoagulation as a result of recent neurosurgery (27). In some articles, the only stated reason for IVC filter placement was extensive deep vein thrombosis (DVT) during pregnancy with concerns about the risk of pulmonary embolism (PE) during delivery, when anticoagulation was to be stopped (13,26,28–35). This was particularly true when the clot was ileofemoral and delivery was in the following 2–3 weeks (7). This centers on the need to discontinue anticoagulation medication during vaginal and caesarean delivery to reduce the risk of bleeding and epidural hematoma (50) at a time when the
IVC filters have been placed in primigravid and multigravid women with success, and patients with filters left in situ have gone on to have successful pregnancies (16). IVC filters have been placed in all trimesters of pregnancy, ranging from 7 weeks’ (20) to 41 weeks’ gestation (34), and even during the latent stage of labor (39). The gravid uterus has not been found to prevent accurate IVC filter placement via the jugular (5) or femoral route (36). A patient in latent labor at 39 weeks’ gestation had an IVC angiogram demonstrating complete effacement of the infrarenal IVC by the gravid uterus; however, with the patient positioned in the left lateral decubitus position, the infrarenal IVC was decompressed and the filter was successfully deployed infrarenally with no filter complications (39). In one patient, the planned infrarenal placement was not possible because of IVC compression by the gravid uterus (12). For a number of reasons, it is often thought that suprarenal placement is preferred in pregnancy and in young women who have the potential to become pregnant. Below the level of the renal veins, the IVC can be compressed by the gravid uterus, which could displace the filter particularly when contracting, leading to migration or fracture of the filter or damage to the IVC wall (32).
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Suprarenal placement also provides additional protection from thrombus that has developed in the dilated ovarian veins (32). Additionally, with the volume of renal blood flow, there is the added advantage of accelerated venous flow, which should promote lysis of trapped thrombi (27). Of the patients included in the present review, 69 (55.6%) had IVC filters placed in the suprarenal position and 32 (25.8%) had filters placed in the infrarenal position; placement was in an unknown position in 23 cases (18.5%). There was no reported renal dysfunction, in line with larger studies in the nonpregnant population (53).
Effectiveness No fatal PE occurred after filter placement in the publications reviewed. One patient who had a Greenfield filter required a second filter as a result of a recurrent symptomatic pulmonary embolus (25). In this case, a venogram showed a large thrombus extending from the filter. No other cases of symptomatic pulmonary emboli were reported after filter placement, for a 0.81% rate of symptomatic PE after filter insertion. There have been no randomized controlled trials to investigate the effectiveness of IVC filter placement in pregnant women. It is possible to detect thrombus in the filter on imaging, and, with the advent of retrievable filters, it is possible to see the trapped thrombus and evaluate it when the filter has been removed (12,45). However, it cannot be known whether these thrombi would have caused a clinically significant event. One retrospective observational study (8) compared a group of patients whose pregnancy was complicated with a DVT of the lower extremity and had permanent IVC filters placed with a lower dose of heparin versus patients who received only full-dose heparin over the same time period. This study showed no immediate major complications in the 11 patients with a filter but, among the 15 patients without filters, there were two cases of PE and a retroperitoneal hematoma. However, there was no randomization, and, although the investigators reported both groups being comparable regarding age and VTE risk factors, filters were placed at the discretion of the treating physician. Additionally, this study was conducted in a very small pool of patients.
Fetal Morbidity and Mortality There was no recorded fetal morbidity or mortality, and, when reported, all neonates were healthy except for two with mild respiratory distress (23). There is limited information on long-term outcomes in the children. The placement of an IVC filter requires radiation exposure, which can cause multiple effects in a developing fetus depending on the dose and the stage of fetal development. The International Commission on Radiological Protection has recommended that no “deterministic effects of practical significance” would be expected in
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the developing human fetus at doses lower than 100 mGy (54). In the publications that documented the amount of total radiation, doses of 12 Gy (19) and 0.05 rad (equivalent to 0.5 Gy) (34) were reported. Techniques employed to minimize the amount of radiation exposure to the fetus include the use of a lead abdominal shield (16) and ultrasound (US) imaging for the diagnosis of DVT in pregnancy (34). IVC filters have been placed with the use of intravascular US guidance (55) and, because it eliminates the need for fluoroscopy, it has been proposed as a potential method in pregnant patients (34). However, we are aware of no reports of this technique in pregnant patients to demonstrate feasibility, filter placement has always been in an infrarenal location, and the enlarged uterus will complicate visualization.
Maternal Morbidity and Mortality One maternal death was identified in the included publications. In 1990, a patient who was 2 months pregnant experienced an air embolism during insertion of a Greenfield filter into the internal jugular vein through a cutdown approach (10). However, percutaneous techniques are now in use with smaller sheaths, the femoral insertion route is more commonly used, and this specific filter is no longer in use. There was no comment on whether the early pregnancy had any impact on the occurrence (10). Two mothers had threatened preterm labor immediately subsequent to IVC filter placement at 30 weeks’ gestation and 26 weeks’ gestation and required tocolysis, which was successful in both cases (4,24). Another patient had varying uterine activity in the 48 hours following insertion, but this resolved spontaneously (21). There were also reports of leg pain and swelling after filter insertion, but this was transient and required no further intervention (9), so it was not considered significant. Other reported cases of maternal morbidity not directly attributable to the IVC filter included a wound hematoma after caesarean section (37) and diarrhea with fever (31). One patient had a retroperitoneal hematoma leading to paralytic ileus following IVC filter placement, but this was thought to have resulted from excessive heparinization (4). Of expressed concern was the risk of infection of the filter at delivery as a result of prolonged rupture of the membranes or other sources of sepsis (9), but we are aware of no reports of this in the available literature. One patient in the series did have premature rupture of membranes at 31 weeks (26), but there was no evidence of IVC filter infection. The Table (13–16,18,25,28,34,43) details complications directly related to the IVC filter itself. Of the 124 patients included in the review, 11 had a complication related to their filter, for a complication rate of 8.87%. If the reported maternal mortality and cases of threatened
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Gestation: Insertion/ Study, Year
Delivery
Complication
Filter (Type)
Delivery (wk)
Method
Placement
Arbogast et al (25), 1994
Cephalad propagation of large thrombus from filter required second filter placed
Greenfield (permanent)
14 and 32/36
Caesarean
Suprarenal
Kelly and Boyd (28),
Migration of filter into right atrium after tethering
Tempofilter* (temporary)
34/34
Caesarean
Suprarenal
1999 Cheung et al (13),
catheter buckled, removed after 5 d in situ Caudal migration of filter and filter fracture, partially
Recovery nitinol
37/38
Vaginal
Infrarenal
Recovery* (retrievable)
26/37
Caesarean
Suprarenal
ALN vena cava filter
40/41
Vaginal
Suprarenal
2005 Ganguli et al (14), 2006 Sendon et al (15), 2006 Gupta et al (16), 2008
Sparrow (18), 2009
retrieved, one leg hook retained (patient asymptomatic at 18-mo follow-up) Fracture of one strut and migration of filter led to
(retrievable)
Review: Inferior Vena Cava Filters in Pregnancy
Table . Filter-Related Complications in Previous Publications (13–16,18,25,28,34,43)
failed retrieval at 167 d, no problems reported at 3mo follow-up Filter migration to right renal vein led to failed retrieval, patient remained asymptomatic
(retrievable)
Failed retrieval: inability to snare
Günther Tulip (retrievable)
34/38
Caesarean
Unknown
Failed retrieval: inability to snare
Günther Tulip
30/34
Caesarean
Unknown
Failed retrieval after 73 d in situ, despite successfully
(retrievable) Günther Tulip
30/40
Vaginal
Suprarenal
snaring retrieval hook, struts would not collapse,
(retrievable)
thought due to adherence of retaining hooks to IVC wall McConville et al (43), 2009 Liu et al (34), 2012
Failed retrieval 28 d after insertion due to filter tilt
OptEase (retrievable)
38/39
Vaginal
Suprarenal
causing hook to become embedded in IVC Failed retrieval 28 d after insertion due to filter tilt
OptEase (retrievable)
38/39
Caesarean
Suprarenal
Occlusion of filter with thrombus that could not be
OptEase (retrievable)
37/37
Caesarean
Suprarenal
eliminated by thrombolytic therapy IVC ¼ inferior vena cava. *Indicates a filter no longer in use in the United Kingdom. Harris et al ’
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premature labor requiring tocolysis are included, a complication arose in 14 patients (11.3%). In the present series, 80 patients received a retrievable filter. Eight had a failed attempted retrieval (14– 16,18,34,43) and one had a filter only partially retrieved (13), yielding a failure-to-retrieve rate of 11.25%. The retrieval failures resulted from a combination of inability to snare the filter, filter fracture, filter migration, filter tilt, and large trapped thrombi. This rate is comparable to those reported in nonpregnant populations, with a 12.1% unsuccessful retrieval rate in 223 attempted retrievals reported in a recent study (56). There was one additional patient who did not have a retrievable filter removed as planned, but this was not related to the filter itself and was a result of extensive DVT still present 9 days after full heparin anticoagulation (38). One patient had a large thrombus that failed to dissolve with thrombolysis, and the retrievable filter was replaced with a permanent filter (32). An additional patient had a retrievable filter replaced with a permanent one after it was decided not to lyse a large trapped thrombus (17), meaning 15% of the 80 patients with retrievable filters were left with a filter in situ postpartum. It has been generally recommended that filters are removed as soon as possible or within 14 days after delivery to avoid incorporation into the caval wall (16,34). In a group of eight patients from one center (42), three had minor filter tilt between 51 and 171, but all filters were successfully retrieved, and these cases were not included as complications, with the greatest tilt requiring only a longer duration of fluoroscopy (42). There are limited long-term follow-up data for this patient group. The longest follow-up is from a series of 18 patients with permanent Greenfield filters (7), with a mean of 78 months of follow-up (range, 10–142 mo). There was no reported PE or filter-related complications, but four patients had significant leg swelling as a result of partial resolution of DVT, which was treated conservatively in all cases (7).
Method of Delivery In one case series, the delivery method was based on obstetric factors alone (16), but others recommended caesarean section for those with IVC filters (34). The reasons given for elective caesarean section include a shorter time without anticoagulation and difficulties in vaginal delivery as a result of swelling of the lower extremities (34). It is not clear if contractions experienced during a trial of labor are more likely to cause filter complications such as migration, tilt, or fracture, but some groups have speculated this (14). Of the eight patients who had a failed filter removal (excluding the patient whose filter was not removed as a result of clot in the filter), four had vaginal deliveries and four had caesarean sections, two of which were elective, which does mean that 75% of patients with such
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filter complications experienced labor. It is not possible to state that these complications are more common with a trial of labor, as not all studies indicated whether this occurred. Indeed, tilting of the filter was seen in one center in a patient with an induced vaginal birth and another with an elective caesarean section (43). This is a potential area for further research.
DISCUSSION Since the first occurrence in 1981, considerable experience has been amassed with the placement of IVC filters in pregnancy. Permanent and retrievable filters have been used successfully and safely in pregnancy, but, in recent years, the majority of filters placed have been retrievable, reflecting the temporarily increased risk of VTE in pregnancy. The indications for use appear similar to the current absolute and relative indications in the general population, although it may be that a relative indication to consider, unique to pregnant women, is the challenge of labor. Retrieval and complication rates appear comparable to those in the general population, but some groups have theorized that it may be more difficult to snare retrievable filters in patients with the anatomic and physiologic changes of pregnancy such as pressure from the uterus causing angulation or distortion of the IVC filter (16). As complications arose in suprarenal and infrarenal placement, this theory may be purely hypothetical. It has been postulated that excess neointimization and adherence of retaining hooks to the IVC wall could be exacerbated by increased abdominal and intracaval pressures associated with labor at vaginal delivery (18). Although frequently cited as a possible factor, it is unclear whether venous dilatation or exertion during labor contributes to filter migration and fracture, which can also lead to failed retrieval (14). It has been theorized that anatomic changes in the configuration of the IVC during pregnancy can lead to tilting, with the IVC being displaced laterally by the gravid uterus so that, when it returns to its normal position after delivery, the filter is tilted (43). This could be compounded by the increase in intravascular volume during pregnancy causing an increase in IVC diameter that returns to normal after delivery (43). There is great variance in the types of filters inserted, and technology is rapidly progressing. Consequently, better IVC filters may be developed for use in clinical practice, which may mean the conclusions drawn from the present review are less relevant and applicable. This review considered a very heterogeneous group of IVC filters collectively as a result of the small numbers of cases, and may not appreciate the individual features that may contribute to complications, as it is known that reported adverse events differ among filter brands (57). Another weakness in the present review is that not all
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cases of IVC filter use in pregnancy are reported, and it is possible that cases in which something went wrong are more likely to be published in the medical literature, perhaps yielding an overestimation of adverse events. Additionally, because of the nature of studying VTE in pregnancy, there are no randomized controlled trials as a result of ethical and practical difficulties. Although one group (8) attempted to compare their experience with filters versus a cohort of patients without filters, it is not possible to draw any meaningful conclusions from this. There is also a lack of long-term follow-up data. It is therefore not known what long-term impact having an IVC filter has, particularly at a young age. This is an especially important consideration because as many as 11.25% of patients with retrievable filters placed had a failed retrieval, and recent randomized control trial data (58) suggest that, at 8 years, IVC filters placed in male and female patients with proximal DVT are associated with an increased rate of DVT and no effect on survival.
Conclusions IVC filters can be used effectively in pregnancy to prevent PE. The use of retrievable filters is particularly attractive because of the transient increase in VTE risk in a young patient. However, there is currently not enough evidence to suggest that IVC filters should be routinely used in pregnancy in patients with DVT, and, until further studies are carried out, their use should be considered for the same absolute indications as in the nonpregnant population or in individuals in whom there are concerns surrounding delivery. Rates of complications in pregnant patients are comparable to those in the nonpregnant population, and there is no significant fetal morbidity or mortality. Suprarenal and infrarenal positioning can be used, although there are more theoretical benefits to suprarenal placement. There may be an advantage to patients having an elective caesarean section, as contractions during labor may contribute to filter complications, but this requires further investigation. There is limited long-term follow-up information, but it does appear that IVC filters can be used safely, when appropriate, during pregnancy.
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30. Reddy K, Reginald PW, Charig MJ. Insertion of an inferior venocaval filter in a pregnant woman at risk for pulmonary embolism–a challenging management. J Obstet Gynaecol 2003; 23:198. 31. Ioakeimidou C, Aziz AI. To filter or not to filter the inferior vena cava in pregnancy? Case report. J Obstet Gynaecol 2005; 25:310. 32. Kawamata K, Chiba Y, Tanaka R, Higashi M, Nishigami K. Experience of temporary inferior vena cava filters inserted in the perinatal period to prevent pulmonary embolism in pregnant women with deep vein thrombosis. J Vasc Surg 2005; 41:652–656. 33. Milford W, Chadha Y, Lust K. Use of a retrievable inferior vena cava filter in term pregnancy: Case report and review of literature. Aust N Z J Obstet Gynaecol 2009; 49:331–333. 34. Liu Y, Sun Y, Zhang S, Jin X. Placement of a retrievable inferior vena cava filter for deep venous thrombosis in term pregnancy. J Vasc Surg 2012; 55:1042–1047. 35. Nakajima Y, Masaoka N, Tsuzuki Y, Morooka M, Sakai M. May-Thurner syndrome resulting in acute iliofemoral deep vein thrombosis during the second trimester of pregnancy. J Obstet Gynaecol Res 2012; 38: 1106–1110. 36. Narayan H, Cullimore J, Krarup K, Thurston H, Macvicar J, Bolia A. Experience with the Cardial inferior vena cava filter as prophylaxis against pulmonary embolism in pregnant women with extensive deep venous thrombosis. Br J Obstet Gynaecol 1992; 99:637–640. 37. Owen RJ, Krarup KC. Case report: the successful use and removal of the Gunther Tulip inferior vena caval filter in pregnancy. Clin Radiol 1997; 52:241–243. 38. Adams E, Maguire N, Richmond D, Rowlands P. Retrievable inferior vena cava filter for thrombolic disease in pregnancy. Br J Obstet Gynaecol 1998; 105:1039. 39. Clark SL, Blatter DD, Jackson GM. Placement of a temporary vena cava filter during labor. Am J Obstet Gynecol 2005; 193:1746–1747. 40. Jamjute P, Reed N, Hinwood D. Use of inferior vena cava filters in thromboembolic disease during labor: case report with a literature review. J Matern Fetal Neonatal Med 2006; 19:741–744. 41. Opara E, Gile J, Zaidi J. Inferior vena cava filter thrombo-prophylaxis in high-risk twin pregnancy. Int J Gynaecol Obstet 2007; 98:62–63. 42. Köcher M, Krcova V, Cerna M, Prochazka M. Retrievable Günther Tulip Vena Cava Filter in the prevention of pulmonary embolism in patients with acute deep venous thrombosis in perinatal period. Eur J Radiol 2009; 70:165–169. 43. McConville RM, Kennedy PT, Collins AJ, Ellis PK. Failed retrieval of an inferior vena cava filter during pregnancy because of filter tilt: report of two cases. Cardiovasc Intervent Radiol 2009; 32:174–177. 44. Brenner C, Molloy M, McEniff N. Use of inferior vena cava filters in thromboembolic disease two case reports with a literature review. Ir Med J 2001; 94:267–268.
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45. Neri E, Civeli L, Benvenuti A, et al. protected iliofemoral venous thrombectomy: in a pregnant woman with pulmonary embolism and ischemic venous thrombosis. Tex Heart Inst J 2002; 29:130–132. 46. Yamagami T, Yoshimatsu R, Okubo T. Symptomatic deep venous thrombosis of the lower extremity in a pregnant woman successfully treated with endovascular procedures. J Obstet Gynaecol Res 2013; 39: 1059–1064. 47. DeStephano CC, Werner EF, Holly BP, Lessne ML. Diagnosis and management of iliac vein thrombosis in pregnancy resulting from MayThurner Syndrome. J Perinatol 2014; 34:566–568. 48. Lonjaret L, Lairez O, Galinier M, Minville V. Thrombolysis by recombinant tissue plasminogen activator during pregnancy: a case of massive pulmonary embolism. Am J Emerg Med 2011; 29:694.e1-e2. 49. Kaufman JA, Kinney TB, Streiff MB, et al. Guidelines for the use of retrievable and convertible vena cava filters: report from the Society of Interventional Radiology multidisciplinary consensus conference. J Vasc Interv Radiol 2006; 17:449–459. 50. Royal College of Obstetricians and Gynaecologists. Reducing the risk of thrombosis and embolism during pregnancy and the puerperium. Green-top guideline no 37a. 2009. Available at: https://www. rcog.org.uk/globalassets/documents/guidelines/gtg-37a.pdf. Accessed December 17, 2015. 51. Sultan AA, West J, Tata LJ, Fleming KM, Nelson-Piercy C, Grainge MJ. Risk of first venous thromboembolism in and around pregnancy: a population-based cohort study. Br J Haematol 2012; 156:366–373. 52. Baglin TP, Brush J, Streiff M. Guidelines on use of vena cava filters. Br J Haematol 2006; 134:590–595. 53. Greenfield LJ, Proctor MC. Suprarenal filter placement. J Vasc Surg 1998; 28:432–438, discussion 438. 54. International Commission on Radiological Protection. The 2007 recommendations of the International Commission on Radiological Protection. ICRP Publication 103. Ann ICRP 2007; 37:1–332. 55. Hodgkiss-Harlow K, Back MR, Brumberg R, et al. Technical factors affecting the accuracy of bedside IVC filter placement using intravascular ultrasound. Vasc Endovascular Surg 2012; 46:293–299. 56. Cohoon KP, McBride J, Friese JL, McPhail IR. Retrievable inferior vena cava filters can be placed and removed with a high degree of success: initial experience. Catheter Cardiovasc Interv 2014. 57. Andreoli JM, Lewandowski RJ, Vogelzang RL, Ryu RK. Comparison of complication rates associated with permanent and retrievable inferior vena cava filters: a review of the MAUDE database. J Vasc Interv Radiol 2014; 25:1181–1185. 58. PREPIC Study Group. Eight-year follow-up of patients with permanent vena cava filters in the prevention of pulmonary embolism: the PREPIC (Prevention du Risque d’Embolie Pulmonaire par Interruption Cave) randomized study. Circulation 2005; 112:416–422.
7.e1
Table E1 . Details of All Patients with an IVC Filter Placed during Pregnancy (4,5,7–48)
Indication
Location
G2P0
Left IF DVT
Unstable clot
Infrarenal
Jugular
Permanent Greenfield
26
–
36
Vaginal
Threatened preterm labor requiring tocolysis at 26 wk, retroperitoneal hematoma, and ileus
Twins, alive
Barnes et al (9), 1981 2 38
G6P5
PE
PE, patient concerned about risk of heparin
Infrarenal
Jugular
Permanent Greenfield
13
–
40
Vaginal
Pain and swelling in left leg for 2 wk after placement
Alive (8,9)
Hux et al (23), 1986 3 22
G2P1
Bilateral DVT and thrombi in vena cava
Heparin induced thrombocytopenia
Suprarenal
Jugular
Permanent Greenfield
33
–
35
Vaginal
None at 7 mo after delivery
Alive with mild respiratory distress
4
41
G6P4
Left thigh DVT
PE on therapeutic anticoagulation (heparin)
Unknown
Femoral
Permanent Greenfield
26
–
Term
Vaginal
None at 4-y follow-up
Alive
5
33
G3P2
Bilateral DVT and thrombi in vena cava
Significant bleeding on heparin (gastrointestinal)
Unknown
Jugular
Permanent Greenfield
22
–
35
Caesarean
None at 2.5-y followup
Alive with mild respiratory distress
6
25
G2P1
Left IF DVT
PE on therapeutic anticoagulation (heparin)
Unknown
Jugular
Permanent Greenfield
32
–
Term
Caesarean
None at 2-y follow-up
Alive
7
32
G6P5
Bilateral DVT
PE on therapeutic anticoagulation (heparin)
Unknown
Jugular
Permanent Greenfield
25
–
Term
Vaginal
None at 3-y follow-up
Alive
Left IF DVT
PE on therapeutic anticoagulation (heparin)
Unknown
Jugular
Permanent Greenfield
30 þ 2
–
38
Vaginal
None
Alive
Right DVT calf and thigh
PE on therapeutic anticoagulation (heparin)
Unknown
Jugular
Permanent Greenfield
9*
–
NA
NA
Narayan et al (36), 1992 10 26 G1P0
Left IF DVT
Unstable clot
Infrarenal
Femoral
Permanent Cardial
24
–
Miscarriage
NA
Miscarriage before filter insertion, edema of left leg slow to resolve
Twin fetuses died before filter at 23/ 40 wk
11
22
G1P0
Left IF DVT
Extensive thrombus
Infrarenal
Femoral
Permanent Cardial
39
–
40 þ 6
Vaginal
None
Alive
12
25
G1P0
Left IF DVT
Extensive thrombus
Infrarenal
Femoral
Permanent Cardial
37 þ 3
–
42
Vaginal
None
Alive
Banfield et al (21), 1990 8 28 G1P0
Eagle and Davies (10), 1990 9 35 Unknown
Filter Type
Delivery Gestation
Delivery Mode
Maternal Complications
Review: Inferior Vena Cava Filters in Pregnancy
VTE
Age (y)
Time in Situ (d)
’
GP
Scurr et al (4), 1981 1 30
Pt. No.
Insertion Gestation (wk)
Fetal Outcome (Apgar score 1 min, 5 min)
Insertion Route
Death of air embolus Maternal death in at filter placement first trimester
Harris et al ’
JVIR
(Continued)
Indication
Location
Left IF DVT
Extensive thrombus
Infrarenal
Femoral
Permanent Cardial
32
–
NA
Delivery Mode NA
None: not delivered at time of report
Not delivered at time of report
Left CF and right popliteal to IVC DVT
Heparin-induced thrombocytopenia
Unknown
Jugular
Permanent Bird’s nest
30
–
37
Vaginal
Threatened preterm labor requiring tocolysis at 30 wk
Alive (9,10)
PE
PE on therapeutic anticoagulation (heparin), heparin allergy
Suprarenal
Femoral and jugular
Permanent Greenfield
14 and 32
–
36
Caesarean
Cephalad propagation of large thrombus from filter, second filter placed, further symptomatic PE leading to delivery
Alive
Right IF and left iliac DVT
After neurosurgery, anticoagulation contraindicated
Suprarenal
Jugular
Permanent Greenfield
33
–
36
Vaginal
None at 6-mo followup
Alive
Thomas et al (20), 1997 17 26 G3P1
Unknown
Recurrent DVT, PE, and thrombophlebitis on heparin
Unknown
Unknown
Permanent Greenfield
31
–
38
Caesarean
None
Alive
18
29
G5P4
Unknown
DVT PE on heparin
Unknown
Unknown
33
–
36
Vaginal
None
Alive
19
34
G12P9
Unknown
Recurrent DVT, heparin failure and bleeding
Unknown
Unknown
Permanent Greenfield Permanent Greenfield
11
–
38
Vaginal
None
Alive
20
29
G2P1
Unknown
PE during pregnancy, possibility for recurrence
Unknown
Unknown
Permanent Greenfield
11
–
37
Vaginal
None
Alive
21
28
G2P1
Unknown
DVT with multiple PEs
Unknown
Unknown
24
–
38
Caesarean
None
Alive
22
21
G4P3
Unknown
DVT
Unknown
Unknown
11
–
38
Vaginal
None
Alive
23
30
G5P4
Unknown
DVT and PE
Unknown
Unknown
Permanent Greenfield Permanent Greenfield Permanent Greenfield
7
–
34
Vaginal
None
Alive
Neill et al (5), 1997 24 18
G1P0
Left IF DVT
PE on heparin
Infrarenal
Femoral
Retrievable Günther Tulip
37 þ 3
8
38
Caesarean
None
Alive
Geary et al (11), 1997 25 33
G1P0
Left IF DVT
Unstable clot extending during anticoagulation
Unknown
Jugular
Temporary filter
34 þ 6
6
34 þ 6
Caesarean
None
Alive
Owen and Krarup (37), 1997 26 37 G1P0
Left IF DVT
Recent extensive thrombosis and imminent delivery
Infrarenal
Femoral
Retrievable Günther Tulip
37 þ 3
12
37 þ 3
Caesarean
Wound hematoma
Alive
Number X
VTE
G1P0
Quayle et al (24), 1994 14 21 G1P0
Delivery Gestation
’
GP
28
Filter Type
Time in Situ (d)
Fetal Outcome (Apgar score 1 min, 5 min)
Age (y)
Pt. No. 13
Insertion Gestation (wk)
Maternal Complications
Insertion Route
Volume XX
Table E1. Details of All Patients with an IVC Filter Placed during Pregnancy (4,5,7–48) (continued )
’ ’
2015
Ricciotti et al (27), 1995 16 31 G3P1
Month
Arbogast et al (25), 1994 15 25 G1P0
(Continued)
7.e2
7.e3
Table E1. Details of All Patients with an IVC Filter Placed during Pregnancy (4,5,7–48) (continued )
Left IF DVT
Extensive unstable clot
Infrarenal
Jugular
Retrievable Günther Tulip
25
Not removed
37
Vaginal
Filter not removed, extensive clot still present after 9 d full anticoagulation
Alive
Left IFP DVT
Extension into iliac veins, perceived high risk of PE
Suprarenal
Jugular
Temporary Tempofilter
34
5
34
Caesarean
Migration of filter having buckled
Alive
Jugular
Permanent Greenfield
Unknown
–
Unknown
Unknown
None at long-term follow-up (mean, 78 mo) apart from 4 patients with significant leg swelling due to partial resolution of DVT, treated conservatively
Alive
30
Jugular
31
Jugular
32
Jugular
33
Jugular
34
Jugular
35
Jugular
36
Jugular
37
Jugular
38
Jugular
39
Jugular
40
Jugular
41
Jugular
42
Jugular
43
Jugular
44
Jugular
Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield
Kelly and Boyd (28), 1999 28 24 Unknown
Aburahma et al (7,8), 1999 and 2001 29 Mean, 25 Unknown 14 IFP, 4 femoro(range, popliteal (left, n = 19–31) 13; right, n = 5)
PE during therapeutic Infrarenal (n = antico10), suprarenal agulation (n = 3), (n = 8) significant bleeding during anticoagulation (n = 2), freefloating iliofemoral DVT (n = 4), heparin-induced thrombocytopenia (n = 2), iliofemoral popliteal DVT 1–3 wk before labor (n = 7)
Filter Type
Delivery Mode
Maternal Complications
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
Harris et al
Location
GP
Delivery Gestation
Review: Inferior Vena Cava Filters in Pregnancy
Indication
Age (y)
Time in Situ (d)
’
VTE
Pt. No.
Adams et al (38), 1998 27 20 G1P0
Insertion Gestation (wk)
Fetal Outcome (Apgar score 1 min, 5 min)
Insertion Route
’
JVIR
(Continued)
Pt. No.
Age (y)
GP
VTE
Indication
Location
Insertion Route
46
Jugular
Brenner et al (44), 2001 47 29 Unknown
Delivery Mode
Maternal Complications
Fetal Outcome (Apgar score 1 min, 5 min)
–
Alive
–
Alive
PE and IVC thrombus
IVC thrombus posing high risk of PE during labor
Suprarenal
Femoral
Retrievable Günther Tulip
33
8
33 þ 1
Vaginal
None
Alive
Unknown
DVT resistant to anticoagulation with heparin, high peripartum PE risk
Suprarenal
Jugular
Temporary Tempofilter
31–37
21⫾ 6
14–18 d after insertion
Caesarean
None
Alive
Temporary Tempofilter Temporary Tempofilter Temporary Tempofilter
Caesarean
None
Alive
Caesarean
None
Alive
Caesarean
None
Alive
Jugular
50
Unknown
Infrarenal
Jugular
51
Unknown
Infrarenal
Jugular
Neri et al (45), 2002 52 22
Unknown
Left ischemic VTE and possible PE
Ischemic venous thrombosis and possible PE before surgical thrombectomy
Unknown
Jugular
Retrievable Prolyser
11
2
Term
Vaginal
None at 18-mo follow-up
Alive
PE
PE and thrombophilia, prophylactic
Infrarenal
Subclavian
Permanent Bird’s Nest
26
–
31
Caesarean
Premature rupture of membranes
Alive
Unknown
Left IF DVT
Failure of anticoagulation
Suprarenal
Subclavian
Retrievable Günther Tulip
35
19*
37
Vaginal
None
Alive
Ishikawa et al (29), 2003 55 29 Unknown
Left IF DVT
Occlusive DVT, high risk of PE
Infrarenal
Subclavian
Temporary Neuhaus Protect
32 þ 3
15
32 þ 3
Caesarean
Edematous leg at 15mo follow-up
Alive
Right FP DVT
Persistent symptoms despite anticoagulation and imminent labor
Unknown
Jugular
Retrievable Günther Tulip
35 þ 3
14
36
Caesarean
None
Alive
Deep veins of both legs
Growing clot and symptomatic of PE on therapy
Suprarenal
Not stated
Removable Zontik filter
33
5
33 þ 3
Caesarean
None
Alive
IF DVT (unilateral)
Extensive DVT near time of labor
Infrarenal
Jugular
Removable Tulip
39*
2
39
Vaginal
None
Alive
Hynek et al (26), 2002 53 36 Unknown
54
30
Reddy et al (30), 2003 56 17
G1P0
Burov and Kapranov (22), 2005 57 40 G3P0
Clark et al (39), 2005 58 21
G1P0
7.e4
(Continued)
2015
Infrarenal
’
Unknown
Month
49
’
Ferraro et al (12), 2001 48 Mean 29 ⫾ Unknown 8 (SD)
Filter Type Permanent Greenfield Permanent Greenfield
Delivery Gestation
Number X
Jugular
Time in Situ (d)
’
45
Insertion Gestation (wk)
Volume XX
Table E1. Details of All Patients with an IVC Filter Placed during Pregnancy (4,5,7–48) (continued )
7.e5
Table E1. Details of All Patients with an IVC Filter Placed during Pregnancy (4,5,7–48) (continued )
GP
Kawamata et al (32), 2005 60 27 G1P0
VTE
Indication
Location
Left CF, great saphenous and popliteal
Extensive DVT
Infrarenal
Jugular
Retrievable Günther Tulip
38 þ 1
19
38 þ 2
Caesarean
Feverish diarrhea (treated with erythromycin)
Alive
Right EI DVT
DVT developed during pregnancy History of DVT, on anticoagulation when not pregnant DVT developed during pregnancy DVT developed during pregnancy
Suprarenal
Jugular
Antheor rIVC
Unknown
9
36
Caesarean
None
Alive
Suprarenal
Unknown
Antheor rIVC
11
37
Vaginal
None
Alive
Suprarenal
Cubital
Antheor rIVC
7
38
Vaginal
None
Alive
Suprarenal
Cubital
Antheor rIVC
14
33
Caesarean
Alive
Suprarenal
Cubital
Antheor rIVC
3
40
Vaginal
Large thrombus captured in filter not dissolved by thrombolysis, temporary filter changed and permanent filter placed None
Alive
Suprarenal Suprarenal
Cubital Cubital
Antheor rIVC Antheor rIVC
4 6
38 39
Vaginal Vaginal
None None
Alive Alive
Suprarenal
Cubital
Antheor rIVC
8
37
Vaginal
None
Alive
Suprarenal
Jugular
4
37
Vaginal
None
Alive
Suprarenal
Jugular
Neuhaus protect rIVC Antheor rIVC
7
37
Vaginal
None
Alive
Suprarenal
Jugular
Antheor rIVC
5
37
Vaginal
None
Alive
Infrarenal
Jugular
40 þ 2
10
40 þ 3
Vaginal
None
Alive
Infrarenal
Femoral
Günther temporary Recovery nitinol IVC filter
37
75
38
Vaginal
Filter migration and fracture; leg hook retained at removal, patient remained asymptomatic
Alive
Unknown
Jugular
Retrievable
36
13
36
Vaginal
None
Alive
26
Attempt at 167
37
Caesarean
Failed retrieval, inferior migration, two struts in right renal vein, tilting, fractured strut in right hepatic lobe
61
32
G3P3
Left EI DVT
62
30
G0P0
Left CI DVT
63
32
G1P1
Left CI DVT
64
33
G2P2
Left CI DVT
65 66
24 39
G1P1 G0P0
Right EI DVT Right femoral DVT
67
27
G1P0
IVC
68
28
G2P1
IVC
69
33
G0P0
Left CI DVT
70
34
G2P2
Left EI DVT
Cheung et al (13), 2005 71 30 G1P0 72
29
Left femoral DVT
G2P1
Left IF DVT
Jamjute et al (40), 2006 73 34 G1P0
Left IF DVT
DVT developed during pregnancy Floating thrombi DVT developed during pregnancy DVT developed during pregnancy Floating thrombi DVT developed during pregnancy History of DVT, on anticoagulation when not pregnant Occlusive DVT (concern of labor and delivery) Extension of occlusive DVT despite anticoagulation
Extensive DVT and onset of labor 24 h after presentation
Filter Type
Delivery Gestation
Delivery Mode
Maternal Complications
Review: Inferior Vena Cava Filters in Pregnancy
Age (y)
Time in Situ (d)
’
Pt. No.
Ioakeimidou and Aziz (31), 2005 59 18 G1P0
Insertion Gestation (wk)
Fetal Outcome (Apgar score 1 min, 5 min)
Insertion Route
OptEase Ganguli et al (14), 2006 74 40 G1P0
PE
Suprarenal
Femoral
Recovery
Harris et al
Recurrent PE on therapeutic anticoagulation
’
JVIR
(Continued)
GP
VTE
Indication
Location
G1P0
Bilateral femoral DVT
Extensive mobile clot
Infrarenal
Jugular
Delivery Mode
Fetal Outcome (Apgar score 1 min, 5 min)
38 þ 5
Vaginal
None
Alive twins
6
38
Vaginal
None
Alive
Number X
Age (y)
Maternal Complications
’
Pt. No.
Opara et al (41), 2006 85 29
Insertion Route
40
3
40
Caesarean
None
Alive
ALN
37
3
37
Caesarean
None
Alive
ALN
36
3
37
Vaginal
None
Alive
ALN
38
9
38
Caesarean
None
Alive
ALN
39
6
39
Caesarean
None
Alive
ALN
40
–
41
Vaginal
Failed retrieval
Alive
ALN
36
30
39
Vaginal
None
Alive
ALN
36
22
39
Vaginal
None
Alive
ALN
37
5
37
Vaginal
None
Alive
Attempt at 6 or 38 d
38
Caesarean
Alive (9,9)
34
Caesarean
Filter Type
Insertion Gestation (wk)
Time in Situ (d)
Delivery Gestation
Retrievable
37 þ 5
14
ALN
38
ALN
Günther Tulip Sendon et al (15), 2008 75 Unknown Unknown
Unknown
77
VTE near time of labor
Suprarenal
Jugular
78
Suprarenal
Jugular
Suprarenal
Jugular
80
Failed medical treatment Heparin-induced thrombocytopenia VTE near time of labor
Suprarenal
Jugular
81
VTE near time of labor
Suprarenal
Jugular
82
Failed medical treatment Failed medical treatment VTE near time of labor
Suprarenal
Jugular
Suprarenal
Jugular
Suprarenal
Jugular
79
83 84 Gupta et al (16), 2008 86 25
P0
IF DVT
DVT, threatened preterm labor
Unknown
Jugular
Retrievable
34
87
22
P1
PE
Massive PE
Unknown
Jugular
Retrievable
30
88
23
P0
DVT
Unknown
Jugular
Permanent
11
NA
37
Caesarean
89
35
P0
IF DVT
DVT recurrent during anticoagulation DVT, threatened preterm labor
Threatened preterm labor requiring tocolysis at 34 wk; failed retrieval, inability to snare filter Failed retrieval, inability to snare filter None
Unknown
Jugular
Permanent
35
NA
41
Vaginal
None
Alive (9, 9)
Hidaka et al (17), 2008 90 35
GP0
Left FP DVT
VTE on anticoagulation
Infrarenal
Jugular
Retrievable Neuhaus Protect
37 þ 0
12
37 þ 5
Vaginal
Large trapped embolus not lysed, temporary filter exchanged for permanent filter
Alive (8, 9)
Sparrow (18), 2009 91 27
P1G0
Left IF DVT
Possible PE (refused CT) on LMWH
Suprarenal
Unknown
Retrievable Günther Tulip
30
Attempt at 73
40
Vaginal
Failed retrieval
Alive
IF DVT
Main criterion for filter insertion was fresh nonorganized or floating thrombus in iliac veins or IVC at time of delivery
Suprarenal
Jugular
Retrievable Günther Tulip
Unknown
Mean, 11 (range, 9–12)
Unknown
Caesarean
None (three had minor tilt of 51–171, all successfully retrieved)
Alive
Köcher et al (42), 2009 92 Mean 27.4 Unknown (range 20-42)
2015
Jugular
’
Suprarenal
Retrievable filter Retrievable filter Retrievable filter Retrievable filter Retrievable filter Retrievable filter Retrievable filter Retrievable filter Retrievable filter Retrievable filter
Month
Jugular
’
Suprarenal
76
Failed medical treatment VTE near time of labor
Volume XX
Table E1. Details of All Patients with an IVC Filter Placed during Pregnancy (4,5,7–48) (continued )
Alive (5,10) Alive (9,9)
7.e6
(Continued)
7.e7
Table E1. Details of All Patients with an IVC Filter Placed during Pregnancy (4,5,7–48) (continued )
IF DVT
Suprarenal
Jugular
94
IF DVT
Suprarenal
Jugular
95
IF DVT
Suprarenal
Jugular
96
IF DVT
Suprarenal
Jugular
97
IF DVT
Suprarenal
Jugular
98
IF DVT
Suprarenal
Jugular
99
IF DVT
Suprarenal
Jugular
Pt. No.
Age (y)
Milford et al (33), 2009 100 31
GP
G2
McConville et al (43), 2009 101 34 G1P0
102
32
G2P1
Lonjaret et al (48), 2011 103 33 G3P1
VTE
Indication
Filter Type
Time in Situ (d)
Delivery Gestation
Retrievable Günther Tulip Retrievable Günther Tulip Retrievable Günther Tulip Retrievable Günther Tulip Retrievable Günther Tulip Retrievable Günther Tulip Retrievable Günther Tulip
Delivery Mode
Maternal Complications
Fetal Outcome (Apgar score 1 min, 5 min)
Caesarean
Alive
Caesarean
Alive
Caesarean
Alive
Caesarean
Alive
Caesarean
Alive
Caesarean
Alive
Caesarean
Alive
Suprarenal
Jugular
Retrievable Cook Celect
39 þ 5
7
40 þ 0
Vaginal
None
Alive
Bilateral
Extensive floating thrombus
Suprarenal
Unknown
Retrievable OptEase
38 þ 2
Attempt at 28
39
Vaginal
Failed retrieval, filter tilt
Alive
Left IF DVT
Free-floating thrombus
Suprarenal
Unknown
Retrievable OptEase
38
Attempt at 28
39
Caesarean
Failed retrieval, filter tilt
Alive
PE and left IF DVT
Massive PE requiring thrombolysis
Unknown
Jugular
Retrievable
31 þ 0
Unknown
38
Vaginal
None (minor epistaxis)
Alive
Retrievable OptEase Retrievable OptEase Retrievable OptEase Retrievable OptEase
39
13
39
Caesarean
None at 12 mo
Alive
39
15
39
Caesarean
None at 12 mo
Alive
38
12
38
Caesarean
None at 12 mo
Alive
40
14
40
Caesarean
Alive
Retrievable OptEase Retrievable OptEase Retrievable OptEase
39
12
39
Caesarean
Unilateral leg swelling with partial resolution of DVT at 3 mo, nothing else at 48 mo None at 12 mo
Alive
38
14
38
Caesarean
None at 12 mo
Alive
41
14
41
Caesarean
Unilateral leg swelling with partial resolution of DVT at 3 mo, nothing else at 28 mo
Alive
Liu et al (34), 2012 104 26
G1P0
Left IFP DVT
Extensive DVT
Suprarenal
Jugular
105
29
G1P1
Left IFP DVT
Extensive DVT
Suprarenal
Jugular
106
20
G1P0
Left PF DVT
Extensive DVT
Suprarenal
Jugular
107
31
G1P0
Left IFP DVT
Extensive DVT
Suprarenal
Jugular
108
28
G1P0
Right IFP DVT
Extensive DVT
Suprarenal
Jugular
109
27
G1P0
Left PF DVT
Extensive DVT
Suprarenal
Jugular
110
33
G1P1
Left IFP DVT
Extensive DVT
Suprarenal
Jugular
’
Extensive DVT
Harris et al
Left IF DVT
Review: Inferior Vena Cava Filters in Pregnancy
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Insertion Gestation (wk)
’
Location
Insertion Route
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(Continued)
Delivery Mode
Maternal Complications
Fetal Outcome (Apgar score 1 min, 5 min)
Caesarean
None at 12 mo
Alive
39
Caesarean
None at 12 mo
Alive
12
38
Caesarean
None at 12 mo
Alive
37
NA
37
Caesarean
Alive
Retrievable OptEase Retrievable OptEase Retrievable OptEase Retrievable OptEase
39
14
39
Caesarean
Device not retrieved as device occluded with thrombus, unilateral leg swelling with partial resolution of DVT at 3 mo, nothing else at 18 mo None at 12 mo
Alive
39
12
39
Caesarean
None at 12 mo
Alive
41
13
41
Caesarean
None at 9 mo
Alive
40
14
40
Caesarean
None at 6 mo
Alive
GP
VTE
Indication
Location
111
31
G1P0
Left IFP DVT
Extensive DVT
Suprarenal
Jugular
112
25
G1P0
Left PF DVT
Extensive DVT
Suprarenal
Jugular
113
28
G1P0
Right IFP DVT
Extensive DVT
Suprarenal
Jugular
114
41
G1P1
Left gastrocnemius vein DVT
Extensive DVT
Suprarenal
Jugular
115
35
G1P1
Left IFP DVT
Extensive DVT
Suprarenal
Jugular
116
26
G1P0
Left IFP DVT
Extensive DVT
Suprarenal
Jugular
117
32
G1P0
Left PF DVT
Extensive DVT
Suprarenal
Jugular
118
29
G1P0
Left PF DVT
Extensive DVT
Suprarenal
Jugular
Nakajima et al (35), 2012 119 27 G1P0
Left IF DVT
Extensive thrombosis, risk of PE at delivery
Infrarenal
Jugular
Temporary filter
36
19
37þ5
Vaginal
None at 12 mo (patient had MTS)
Alive (8, 9)
Right EI to intramuscular veins of gastrocnemius DVT
Phlebothrombosis, extensive DVT on anticoagulation
Infrarenal
Unknown
Permanent TrapEase
30þ0
NA
37þ0
Vaginal
None
Alive
Left calf vein to left CI DVT
Extensive DVT and planned endovascular procedures
Suprarenal
Jugular
Retrievable Günther Tulip
34 þ 0
30
35 þ 1
Caesarean
IVC filter exchanged twice postpartum while endovascular DVT treatment was carried out (successfully removed)
Alive
Left calf vein to left CI DVT/PE (asymptomatic, seen on CT) Left calf vein to left CI DVT
Percutaneous PMT for ongoing pain/risk for PTS
Suprarenal
Unknown
Retrievable
18 þ 2
64
39 þ 3
Caesarean
None (patient had MTS)
Alive (8, 9)
Percutaneous PMT for ongoing pain/risk for PTS
Suprarenal
Unknown
Retrievable
30 þ 5
Unknown
37 þ 6
Vaginal
Alive (9, 9)
Percutaneous PMT for ongoing pain/risk for PTS
Suprarenal
Unknown
Retrievable
35 þ 1
66
38 þ 4
Vaginal
None related to IVC filter (partial rethrombosis of DVT and pain, patient had MTS) None (patient had MTS)
Pt. No.
G1P0
124
18
G1P0
Left IFP DVT/PE (asymptomatic, seen on CT)
14
39
39
9
38
2015
30
39
Filter Type
’
123
Retrievable OptEase Retrievable OptEase Retrievable OptEase Retrievable OptEase
Month
DeStephano et al (47), 2014 122 28 G6P0
Delivery Gestation
’
Yamagami et al (46), 2013 121 24 Unknown
Time in Situ (d)
Number X
Valadares et al (19), 2013 120 27 G2P1
Insertion Gestation (wk)
’
Age (y)
Insertion Route
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Table E1. Details of All Patients with an IVC Filter Placed during Pregnancy (4,5,7–48) (continued )
Alive (9, 9)
CF ¼ common femoral; CI ¼ common iliac; CIV ¼ common iliac vein; DVT ¼ deep vein thrombosis; EI ¼ external iliac; GP ¼ gravidity/parity; IF ¼ ileofemoral; IFP ¼ ileofemoropopliteal; IVC ¼ inferior vena cava; LMWH ¼ low molecular weight heparin; NA ¼ not applicable; PE ¼ pulmonary embolism; PF ¼ popliteal–femoral; MTS ¼ May–Thurner syndrome; PMT ¼ pharmacomechanical thrombectomy; PTS ¼ postthrombotic syndrome; VTE ¼ venous thromboembolism. n
Approximate.
7.e8
Inferior Vena Cava Filters in Pregnancy: A Systematic Review Sally A. Harris, MBChB, BSc, Rahul Velineni, BSc, MBBS, MRCS, and Alun H. Davies, MA, DM, DSc, FRCS, FEBVS, FACPH
ABSTRACT During pregnancy, patients have an increased risk of venous thromboembolism (VTE). This is an important cause of maternal mortality. Inferior vena cava (IVC) filters can be used to prevent pulmonary embolism in complicated cases of VTE during pregnancy. The present systematic review includes all patients reported in the literature who had an IVC filter placed during pregnancy. The indications for IVC filters are discussed, along with practical considerations for placement during pregnancy, filter effectiveness, and maternal and fetal mortality and morbidity. IVC filters can be used safely when appropriate during pregnancy, with complication rates similar to those in nonpregnant patients.
ABBREVIATIONS DVT = deep vein thrombosis, IVC = inferior vena cava, MeSH = Medical Subject Heading, PE = pulmonary embolism, VTE = venous thromboembolism
During pregnancy, patients are more predisposed to thromboembolic events because of hypercoagulability caused by adaptations in the hemostatic system in preparation for the hemostatic challenge of delivery, venous stasis caused in part by the pressure effect of the enlarging uterus, and vascular endothelial damage caused by distension or surgical injury. Venous thromboembolism (VTE) is the third most common direct cause of maternal mortality in the United Kingdom, occurring in 0.79 per 100,00 maternities in 2005–2008 (1). The standard treatment is anticoagulation with low molecular weight heparin until at least 6 weeks postpartum (2). Warfarin is avoided in pregnancy because it can cross the placental barrier and lead to fetal complications, including malformations and death (3). There are now increasing numbers of reported use of inferior vena cava (IVC) filters during pregnancy.
From the Department of Academic Surgery (S.A.H., R.V., A.H.D.), and Section of Vascular Surgery (R.V., A.H.D.), Imperial College London, Charing Cross Hospital, Fulham Palace Road, London W6 8RF, United Kingdom. Received July 27, 2015; final revision received October 31, 2015; accepted November 1, 2015. Address correspondence to A.H.D.; E-mail: [email protected] Table E1 is available online at www.jvir.org. None of the authors have identified a conflict of interest. & SIR, 2015 J Vasc Interv Radiol 2015; XX:]]]–]]] http://dx.doi.org/10.1016/j.jvir.2015.11.024
The first reported IVC filter placed in a pregnant patient occurred in 1981 (4). Initially, permanent filters were used. However, in pregnancy, the patient normally has a long life expectancy and the increased risk of VTE is generally temporary, so removable filters are attractive (5). The present systematic review will collate the information on the use of IVC filters during pregnancy.
MATERIALS AND METHODS This systematic review was performed in accordance to the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (6). The focus of the review was pregnant patients who had an IVC filter placed during pregnancy, excluding those who had an IVC filter before conception or in the postpartum period. Outcome measures included maternal and fetal morbidity and mortality. PubMed, Cochrane database, Embase and Ovid Medline databases were searched using a search strategy developed to identify all papers about IVF filter placement in pregnancy regardless of study design as follows: (filter, inferior vena cava [Medical Subject Heading (MeSH) Terms]) AND (pregnancy [MeSH Terms]) OR (obstetrics [MeSH Terms]). The search included all articles published through December 2014. The titles and abstracts of the resulting articles were reviewed and screened for relevance. Duplicate publications, articles not published in English, and abstracts from conferences were removed. All references of included
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manuscripts were manually searched to identify related articles that had not been identified. Data were extracted to compile a database of all reported pregnancies in which an IVC filter was placed. When possible, patient age, parity, indication for IVC filter placement, IVC filter position, gestation at insertion, filter type, time of retrieval, mode of delivery, fetal outcome, and maternal morbidity and mortality were recorded.
RESULTS The database search located 332 publications. After screening, 52 publications were located. After review of their references, a further three were found. Full texts were then examined for eligibility. This resulted in 11 exclusions: conference abstracts, reports of postpartum IVC filter insertion and superior vena cava filter insertion, and inability to identify the pregnant patients in a series. The remaining 44 articles were case reports or case series from a particular institution. There were no randomized controlled trials, and consequently no studies were amenable to pooling for meta-analysis. From these manuscripts, 135 pregnancies in which an IVC filter was inserted were identified. However, a case series of 18 patients (7) overlapped with and included all 11 patients in an earlier series (8). Therefore, the present review includes a total of 124 pregnancies (Table E1, available online at www.jvir.org) (4,5,7–48).
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risk of PE is particularly high (51). This is not acknowledged as a relative indication specifically by SIR but could be considered an extension of “high risk of complication of anticoagulation” (49). Other publications referred to the relative indications of unstable, floating, large DVTs near the time of delivery (4,7,8,15,32,33,36–43) or threatened preterm labor (16) and those with clots in or extending into the IVC (44). More recently, IVC filters have been inserted as protection against PE during endovascular procedures (45–47) or thrombolysis (48) carried out during pregnancy. No prophylactic indications have been reported, but one group (17) suggested that, in patients with high-risk thrombophilias, prophylactic placement of a temporary IVC filter could be performed before labor; however, we are aware of no studies that support this. The British Society for Haematology IVC filter guidelines (52) state that “insertion may be considered in pregnant patients who have contraindications to anticoagulation and develop extensive VTE shortly before delivery (within 2 weeks).” This does not encompass the range of indications seen in the present review. The Royal Society of Obstetricians and Gynaecologists VTE guidelines (2) recommend to “consider use of a temporary IVC filter in the peripartum period for patients with iliac vein VTE or in patients with proven DVT and who have recurrent PE despite adequate anticoagulation,” which is more reflective of the current literature.
Indications
Placement
The Society of Interventional Radiology (SIR) recognizes absolute and relative indications for filter placement in confirmed VTE in addition to prophylactic indications (49). In the cases identified, the rationale for IVC filter placement is not always clear, but the most common indications were selected and considered in these categories. As in nonpregnant patients, IVC filters were inserted for the absolute indications of failure of medical therapy for VTE despite adequate anticoagulation (5,8,10–23) and complications of anticoagulation, including heparininduced thrombocytopenia (7,15,23,24), heparin allergy (25), significant bleeding during anticoagulation (7,8,20, 23,26), and contraindication to anticoagulation as a result of recent neurosurgery (27). In some articles, the only stated reason for IVC filter placement was extensive deep vein thrombosis (DVT) during pregnancy with concerns about the risk of pulmonary embolism (PE) during delivery, when anticoagulation was to be stopped (13,26,28–35). This was particularly true when the clot was ileofemoral and delivery was in the following 2–3 weeks (7). This centers on the need to discontinue anticoagulation medication during vaginal and caesarean delivery to reduce the risk of bleeding and epidural hematoma (50) at a time when the
IVC filters have been placed in primigravid and multigravid women with success, and patients with filters left in situ have gone on to have successful pregnancies (16). IVC filters have been placed in all trimesters of pregnancy, ranging from 7 weeks’ (20) to 41 weeks’ gestation (34), and even during the latent stage of labor (39). The gravid uterus has not been found to prevent accurate IVC filter placement via the jugular (5) or femoral route (36). A patient in latent labor at 39 weeks’ gestation had an IVC angiogram demonstrating complete effacement of the infrarenal IVC by the gravid uterus; however, with the patient positioned in the left lateral decubitus position, the infrarenal IVC was decompressed and the filter was successfully deployed infrarenally with no filter complications (39). In one patient, the planned infrarenal placement was not possible because of IVC compression by the gravid uterus (12). For a number of reasons, it is often thought that suprarenal placement is preferred in pregnancy and in young women who have the potential to become pregnant. Below the level of the renal veins, the IVC can be compressed by the gravid uterus, which could displace the filter particularly when contracting, leading to migration or fracture of the filter or damage to the IVC wall (32).
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Suprarenal placement also provides additional protection from thrombus that has developed in the dilated ovarian veins (32). Additionally, with the volume of renal blood flow, there is the added advantage of accelerated venous flow, which should promote lysis of trapped thrombi (27). Of the patients included in the present review, 69 (55.6%) had IVC filters placed in the suprarenal position and 32 (25.8%) had filters placed in the infrarenal position; placement was in an unknown position in 23 cases (18.5%). There was no reported renal dysfunction, in line with larger studies in the nonpregnant population (53).
Effectiveness No fatal PE occurred after filter placement in the publications reviewed. One patient who had a Greenfield filter required a second filter as a result of a recurrent symptomatic pulmonary embolus (25). In this case, a venogram showed a large thrombus extending from the filter. No other cases of symptomatic pulmonary emboli were reported after filter placement, for a 0.81% rate of symptomatic PE after filter insertion. There have been no randomized controlled trials to investigate the effectiveness of IVC filter placement in pregnant women. It is possible to detect thrombus in the filter on imaging, and, with the advent of retrievable filters, it is possible to see the trapped thrombus and evaluate it when the filter has been removed (12,45). However, it cannot be known whether these thrombi would have caused a clinically significant event. One retrospective observational study (8) compared a group of patients whose pregnancy was complicated with a DVT of the lower extremity and had permanent IVC filters placed with a lower dose of heparin versus patients who received only full-dose heparin over the same time period. This study showed no immediate major complications in the 11 patients with a filter but, among the 15 patients without filters, there were two cases of PE and a retroperitoneal hematoma. However, there was no randomization, and, although the investigators reported both groups being comparable regarding age and VTE risk factors, filters were placed at the discretion of the treating physician. Additionally, this study was conducted in a very small pool of patients.
Fetal Morbidity and Mortality There was no recorded fetal morbidity or mortality, and, when reported, all neonates were healthy except for two with mild respiratory distress (23). There is limited information on long-term outcomes in the children. The placement of an IVC filter requires radiation exposure, which can cause multiple effects in a developing fetus depending on the dose and the stage of fetal development. The International Commission on Radiological Protection has recommended that no “deterministic effects of practical significance” would be expected in
3
the developing human fetus at doses lower than 100 mGy (54). In the publications that documented the amount of total radiation, doses of 12 Gy (19) and 0.05 rad (equivalent to 0.5 Gy) (34) were reported. Techniques employed to minimize the amount of radiation exposure to the fetus include the use of a lead abdominal shield (16) and ultrasound (US) imaging for the diagnosis of DVT in pregnancy (34). IVC filters have been placed with the use of intravascular US guidance (55) and, because it eliminates the need for fluoroscopy, it has been proposed as a potential method in pregnant patients (34). However, we are aware of no reports of this technique in pregnant patients to demonstrate feasibility, filter placement has always been in an infrarenal location, and the enlarged uterus will complicate visualization.
Maternal Morbidity and Mortality One maternal death was identified in the included publications. In 1990, a patient who was 2 months pregnant experienced an air embolism during insertion of a Greenfield filter into the internal jugular vein through a cutdown approach (10). However, percutaneous techniques are now in use with smaller sheaths, the femoral insertion route is more commonly used, and this specific filter is no longer in use. There was no comment on whether the early pregnancy had any impact on the occurrence (10). Two mothers had threatened preterm labor immediately subsequent to IVC filter placement at 30 weeks’ gestation and 26 weeks’ gestation and required tocolysis, which was successful in both cases (4,24). Another patient had varying uterine activity in the 48 hours following insertion, but this resolved spontaneously (21). There were also reports of leg pain and swelling after filter insertion, but this was transient and required no further intervention (9), so it was not considered significant. Other reported cases of maternal morbidity not directly attributable to the IVC filter included a wound hematoma after caesarean section (37) and diarrhea with fever (31). One patient had a retroperitoneal hematoma leading to paralytic ileus following IVC filter placement, but this was thought to have resulted from excessive heparinization (4). Of expressed concern was the risk of infection of the filter at delivery as a result of prolonged rupture of the membranes or other sources of sepsis (9), but we are aware of no reports of this in the available literature. One patient in the series did have premature rupture of membranes at 31 weeks (26), but there was no evidence of IVC filter infection. The Table (13–16,18,25,28,34,43) details complications directly related to the IVC filter itself. Of the 124 patients included in the review, 11 had a complication related to their filter, for a complication rate of 8.87%. If the reported maternal mortality and cases of threatened
4 ’
Gestation: Insertion/ Study, Year
Delivery
Complication
Filter (Type)
Delivery (wk)
Method
Placement
Arbogast et al (25), 1994
Cephalad propagation of large thrombus from filter required second filter placed
Greenfield (permanent)
14 and 32/36
Caesarean
Suprarenal
Kelly and Boyd (28),
Migration of filter into right atrium after tethering
Tempofilter* (temporary)
34/34
Caesarean
Suprarenal
1999 Cheung et al (13),
catheter buckled, removed after 5 d in situ Caudal migration of filter and filter fracture, partially
Recovery nitinol
37/38
Vaginal
Infrarenal
Recovery* (retrievable)
26/37
Caesarean
Suprarenal
ALN vena cava filter
40/41
Vaginal
Suprarenal
2005 Ganguli et al (14), 2006 Sendon et al (15), 2006 Gupta et al (16), 2008
Sparrow (18), 2009
retrieved, one leg hook retained (patient asymptomatic at 18-mo follow-up) Fracture of one strut and migration of filter led to
(retrievable)
Review: Inferior Vena Cava Filters in Pregnancy
Table . Filter-Related Complications in Previous Publications (13–16,18,25,28,34,43)
failed retrieval at 167 d, no problems reported at 3mo follow-up Filter migration to right renal vein led to failed retrieval, patient remained asymptomatic
(retrievable)
Failed retrieval: inability to snare
Günther Tulip (retrievable)
34/38
Caesarean
Unknown
Failed retrieval: inability to snare
Günther Tulip
30/34
Caesarean
Unknown
Failed retrieval after 73 d in situ, despite successfully
(retrievable) Günther Tulip
30/40
Vaginal
Suprarenal
snaring retrieval hook, struts would not collapse,
(retrievable)
thought due to adherence of retaining hooks to IVC wall McConville et al (43), 2009 Liu et al (34), 2012
Failed retrieval 28 d after insertion due to filter tilt
OptEase (retrievable)
38/39
Vaginal
Suprarenal
causing hook to become embedded in IVC Failed retrieval 28 d after insertion due to filter tilt
OptEase (retrievable)
38/39
Caesarean
Suprarenal
Occlusion of filter with thrombus that could not be
OptEase (retrievable)
37/37
Caesarean
Suprarenal
eliminated by thrombolytic therapy IVC ¼ inferior vena cava. *Indicates a filter no longer in use in the United Kingdom. Harris et al ’
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premature labor requiring tocolysis are included, a complication arose in 14 patients (11.3%). In the present series, 80 patients received a retrievable filter. Eight had a failed attempted retrieval (14– 16,18,34,43) and one had a filter only partially retrieved (13), yielding a failure-to-retrieve rate of 11.25%. The retrieval failures resulted from a combination of inability to snare the filter, filter fracture, filter migration, filter tilt, and large trapped thrombi. This rate is comparable to those reported in nonpregnant populations, with a 12.1% unsuccessful retrieval rate in 223 attempted retrievals reported in a recent study (56). There was one additional patient who did not have a retrievable filter removed as planned, but this was not related to the filter itself and was a result of extensive DVT still present 9 days after full heparin anticoagulation (38). One patient had a large thrombus that failed to dissolve with thrombolysis, and the retrievable filter was replaced with a permanent filter (32). An additional patient had a retrievable filter replaced with a permanent one after it was decided not to lyse a large trapped thrombus (17), meaning 15% of the 80 patients with retrievable filters were left with a filter in situ postpartum. It has been generally recommended that filters are removed as soon as possible or within 14 days after delivery to avoid incorporation into the caval wall (16,34). In a group of eight patients from one center (42), three had minor filter tilt between 51 and 171, but all filters were successfully retrieved, and these cases were not included as complications, with the greatest tilt requiring only a longer duration of fluoroscopy (42). There are limited long-term follow-up data for this patient group. The longest follow-up is from a series of 18 patients with permanent Greenfield filters (7), with a mean of 78 months of follow-up (range, 10–142 mo). There was no reported PE or filter-related complications, but four patients had significant leg swelling as a result of partial resolution of DVT, which was treated conservatively in all cases (7).
Method of Delivery In one case series, the delivery method was based on obstetric factors alone (16), but others recommended caesarean section for those with IVC filters (34). The reasons given for elective caesarean section include a shorter time without anticoagulation and difficulties in vaginal delivery as a result of swelling of the lower extremities (34). It is not clear if contractions experienced during a trial of labor are more likely to cause filter complications such as migration, tilt, or fracture, but some groups have speculated this (14). Of the eight patients who had a failed filter removal (excluding the patient whose filter was not removed as a result of clot in the filter), four had vaginal deliveries and four had caesarean sections, two of which were elective, which does mean that 75% of patients with such
5
filter complications experienced labor. It is not possible to state that these complications are more common with a trial of labor, as not all studies indicated whether this occurred. Indeed, tilting of the filter was seen in one center in a patient with an induced vaginal birth and another with an elective caesarean section (43). This is a potential area for further research.
DISCUSSION Since the first occurrence in 1981, considerable experience has been amassed with the placement of IVC filters in pregnancy. Permanent and retrievable filters have been used successfully and safely in pregnancy, but, in recent years, the majority of filters placed have been retrievable, reflecting the temporarily increased risk of VTE in pregnancy. The indications for use appear similar to the current absolute and relative indications in the general population, although it may be that a relative indication to consider, unique to pregnant women, is the challenge of labor. Retrieval and complication rates appear comparable to those in the general population, but some groups have theorized that it may be more difficult to snare retrievable filters in patients with the anatomic and physiologic changes of pregnancy such as pressure from the uterus causing angulation or distortion of the IVC filter (16). As complications arose in suprarenal and infrarenal placement, this theory may be purely hypothetical. It has been postulated that excess neointimization and adherence of retaining hooks to the IVC wall could be exacerbated by increased abdominal and intracaval pressures associated with labor at vaginal delivery (18). Although frequently cited as a possible factor, it is unclear whether venous dilatation or exertion during labor contributes to filter migration and fracture, which can also lead to failed retrieval (14). It has been theorized that anatomic changes in the configuration of the IVC during pregnancy can lead to tilting, with the IVC being displaced laterally by the gravid uterus so that, when it returns to its normal position after delivery, the filter is tilted (43). This could be compounded by the increase in intravascular volume during pregnancy causing an increase in IVC diameter that returns to normal after delivery (43). There is great variance in the types of filters inserted, and technology is rapidly progressing. Consequently, better IVC filters may be developed for use in clinical practice, which may mean the conclusions drawn from the present review are less relevant and applicable. This review considered a very heterogeneous group of IVC filters collectively as a result of the small numbers of cases, and may not appreciate the individual features that may contribute to complications, as it is known that reported adverse events differ among filter brands (57). Another weakness in the present review is that not all
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Review: Inferior Vena Cava Filters in Pregnancy
cases of IVC filter use in pregnancy are reported, and it is possible that cases in which something went wrong are more likely to be published in the medical literature, perhaps yielding an overestimation of adverse events. Additionally, because of the nature of studying VTE in pregnancy, there are no randomized controlled trials as a result of ethical and practical difficulties. Although one group (8) attempted to compare their experience with filters versus a cohort of patients without filters, it is not possible to draw any meaningful conclusions from this. There is also a lack of long-term follow-up data. It is therefore not known what long-term impact having an IVC filter has, particularly at a young age. This is an especially important consideration because as many as 11.25% of patients with retrievable filters placed had a failed retrieval, and recent randomized control trial data (58) suggest that, at 8 years, IVC filters placed in male and female patients with proximal DVT are associated with an increased rate of DVT and no effect on survival.
Conclusions IVC filters can be used effectively in pregnancy to prevent PE. The use of retrievable filters is particularly attractive because of the transient increase in VTE risk in a young patient. However, there is currently not enough evidence to suggest that IVC filters should be routinely used in pregnancy in patients with DVT, and, until further studies are carried out, their use should be considered for the same absolute indications as in the nonpregnant population or in individuals in whom there are concerns surrounding delivery. Rates of complications in pregnant patients are comparable to those in the nonpregnant population, and there is no significant fetal morbidity or mortality. Suprarenal and infrarenal positioning can be used, although there are more theoretical benefits to suprarenal placement. There may be an advantage to patients having an elective caesarean section, as contractions during labor may contribute to filter complications, but this requires further investigation. There is limited long-term follow-up information, but it does appear that IVC filters can be used safely, when appropriate, during pregnancy.
REFERENCES 1. Cantwell R, Clutton-Brock T, Cooper G, et al. Saving mothers’ lives: Reviewing maternal deaths to make motherhood safer: 2006-2008. The eighth report of the confidential enquiries into maternal deaths in the United Kingdom. BJOG 2011; 118(Supp 1):1–203. 2. Royal College of Obstetricians and Gynaecologists. Thromboembolic disease in pregnancy and the puerperium: acute management. Green-top guideline no 37b. 2015, Available at: https://www.rcog.org.uk/ globalassets/documents/guidelines/gtg-37b.pdf. Accessed December 17, 2015. 3. Hall JG, Pauli RM, Wilson KM. Maternal and fetal sequelae of anticoagulation during pregnancy. Am J Med 1980; 68:122–140. 4. Scurr J, Stannard P, Wright J. Extensive thrombo-embolic disease in pregnancy treated with a Kimray Greenfield vena cava filter. Case report. Br J Obstet Gynaecol 1981; 88:778–780.
Harris et al
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5. Neill AM, Appleton DS, Richards P. Retrievable inferior vena caval filter for thromboembolic disease in pregnancy. Br J Obstet Gynaecol 1997; 104:1416–1418. 6. Liberati A, Altman DG, Tetzlaff J, et al. The PRISMA statement for reporting systematic reviews and meta-analyses of studies that evaluate healthcare interventions: explanation and elaboration. BMJ 2009; 339: b2700. 7. Aburahma AF, Mullins DA. Endovascular caval interruption in pregnant patients with deep vein thrombosis of the lower extremity. J Vasc Surg 2001; 33:375–378. 8. Aburahma AF, Boland JP. Management of deep vein thrombosis of the lower extremity in pregnancy: a challenging dilemma. Am Surg 1999; 65: 164–167. 9. Barnes AB, Kanarek DJ, Greenfield AJ Jr, Brewster DC. Vena caval filter placement during pregnancy. Am J Obstet Gynecol 1981; 140: 707–708. 10. Eagle CJ, Davies JM. Lethal air embolism during placement of a Kimray-Greenfield filter. J Cardiothorac Anesth 1990; 4:616–620. 11. Geary M, Gibson P, Wilkins R, Lamont R. Novel treatment of extensive thrombo-embolic disease in pregnancy with a temporary vena cava filter. J Obstet Gynaecol 1997; 17:282–283. 12. Ferraro F, D'Ignazio N, Matarazzo A, Rusciano G, Iannuzzi M, Belluomo Anello C. Thromboembolism in pregnancy: a new temporary caval filter. Minerva Anestesiol 2001; 67:381–385. 13. Cheung MC, Asch MR, Gandhi S, Kingdom JCP. Temporary inferior vena caval filter use in pregnancy. J Thromb Haemost 2005; 3: 1096–1097. 14. Ganguli S, Tham JC, Komlos F, Rabkin DJ. Fracture and migration of a suprarenal inferior vena cava filter in a pregnant patient. J Vasc Interv Radiol 2006; 17:1707–1711. 15. Sendon S, Dalmas A, Lions C, Legrand A, Deruelle P. Use of temporary inferior vena cava filter placement in pregnant women near term. Eur J Obstet Gynecol Reprod Biol 2008; 140:143–144. 16. Gupta S, Ettles DF, Robinson GJ, Lindow SW. Inferior vena cava filter use in pregnancy: preliminary experience. BJOG 2008; 115:785–788. 17. Hidaka N, Hachisuga M, Tsukimori K, Onohara T, Maehara Y, Wake N. Intrapartum placement of an inferior vena cava filter for a woman with hereditary antithrombin III deficiency: its role in the prevention of fatal pulmonary embolism. J Obstet Gynaecol Res 2008; 34: 95–99. 18. Sparrow P. Response to “Failed retrieval of an inferior vena cava filter during pregnancy because of filter tilt: report of two cases”. Cardiovasc Intervent Radiol 2009; 32:388–389. 19. Valadares S, Serrano F, Torres R, Borges A. Inferior vena cava filter placement during pregnancy: an adjuvant option when medical therapy fails. Case Rep Obstet Gynecol 2013; 2013:821635. 20. Thomas LA, Summers RR, Cardwell MS. Use of Greenfield filters in pregnant women at risk for pulmonary embolism. South Med J 1997; 90:215–217. 21. Banfield PJ, Pittam M, Marwood R. Recurrent pulmonary embolism in pregnancy managed with the Greenfield vena caval filter. Int J Gynaecol Obstet 1990; 33:275–278. 22. Burov VP, Kapranov SA. Temporary placement of the cava filter to the suprarenal segment of the inferior vena cava. Angiol Sosud Khir 2005; 11: 45–47. 23. Hux CH, Wapner RJ, Chayen B, Rattan P, Jarrell B, Greenfield L. Use of the Greenfield filter for thromboembolic disease in pregnancy. Am J Obstet Gynecol 1986; 155:734–737. 24. Quayle S, Germain M, Wolf E, Miller R. Case report of placement of a bird’s nest filter during pregnancy. J Matern Fetal Med 1994; 3:187–189. 25. Arbogast JD, Blessed WB, Lacoste H, Gross WS, Gonda RL Jr, Welch RA. Use of two Greenfield caval filters to prevent recurrent pulmonary embolism in a heparin-allergic gravida. Obstet Gynecol 1994; 84: 652–654. 26. Hynek K, Spalova I, Spatenka J, Mates M. Possibilities of using vena cava filters in pregnant women with venous thromboembolism. Case reports. Sb Lek 2002; 103:451–454. 27. Ricciotti HA, Wong GP, Ludmir J. Deep venous thrombosis treated with an inferior vena cava filter in a pregnant woman after recent neurosurgery. A case report. J Reprod Med 1995; 40:404–406. 28. Kelly IM, Boyd CS. Buckling of the tethering catheter causes migration of a temporary caval filter to the right atrium. Clin Radiol 1999; 54: 398–401. 29. Ishikawa T, Okabe T, Ogawa K, et al. Usefulness of a second temporary vena cava filter for preventing acute pulmonary thromboembolism. Circ J 2003; 67:718–720.
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30. Reddy K, Reginald PW, Charig MJ. Insertion of an inferior venocaval filter in a pregnant woman at risk for pulmonary embolism–a challenging management. J Obstet Gynaecol 2003; 23:198. 31. Ioakeimidou C, Aziz AI. To filter or not to filter the inferior vena cava in pregnancy? Case report. J Obstet Gynaecol 2005; 25:310. 32. Kawamata K, Chiba Y, Tanaka R, Higashi M, Nishigami K. Experience of temporary inferior vena cava filters inserted in the perinatal period to prevent pulmonary embolism in pregnant women with deep vein thrombosis. J Vasc Surg 2005; 41:652–656. 33. Milford W, Chadha Y, Lust K. Use of a retrievable inferior vena cava filter in term pregnancy: Case report and review of literature. Aust N Z J Obstet Gynaecol 2009; 49:331–333. 34. Liu Y, Sun Y, Zhang S, Jin X. Placement of a retrievable inferior vena cava filter for deep venous thrombosis in term pregnancy. J Vasc Surg 2012; 55:1042–1047. 35. Nakajima Y, Masaoka N, Tsuzuki Y, Morooka M, Sakai M. May-Thurner syndrome resulting in acute iliofemoral deep vein thrombosis during the second trimester of pregnancy. J Obstet Gynaecol Res 2012; 38: 1106–1110. 36. Narayan H, Cullimore J, Krarup K, Thurston H, Macvicar J, Bolia A. Experience with the Cardial inferior vena cava filter as prophylaxis against pulmonary embolism in pregnant women with extensive deep venous thrombosis. Br J Obstet Gynaecol 1992; 99:637–640. 37. Owen RJ, Krarup KC. Case report: the successful use and removal of the Gunther Tulip inferior vena caval filter in pregnancy. Clin Radiol 1997; 52:241–243. 38. Adams E, Maguire N, Richmond D, Rowlands P. Retrievable inferior vena cava filter for thrombolic disease in pregnancy. Br J Obstet Gynaecol 1998; 105:1039. 39. Clark SL, Blatter DD, Jackson GM. Placement of a temporary vena cava filter during labor. Am J Obstet Gynecol 2005; 193:1746–1747. 40. Jamjute P, Reed N, Hinwood D. Use of inferior vena cava filters in thromboembolic disease during labor: case report with a literature review. J Matern Fetal Neonatal Med 2006; 19:741–744. 41. Opara E, Gile J, Zaidi J. Inferior vena cava filter thrombo-prophylaxis in high-risk twin pregnancy. Int J Gynaecol Obstet 2007; 98:62–63. 42. Köcher M, Krcova V, Cerna M, Prochazka M. Retrievable Günther Tulip Vena Cava Filter in the prevention of pulmonary embolism in patients with acute deep venous thrombosis in perinatal period. Eur J Radiol 2009; 70:165–169. 43. McConville RM, Kennedy PT, Collins AJ, Ellis PK. Failed retrieval of an inferior vena cava filter during pregnancy because of filter tilt: report of two cases. Cardiovasc Intervent Radiol 2009; 32:174–177. 44. Brenner C, Molloy M, McEniff N. Use of inferior vena cava filters in thromboembolic disease two case reports with a literature review. Ir Med J 2001; 94:267–268.
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45. Neri E, Civeli L, Benvenuti A, et al. protected iliofemoral venous thrombectomy: in a pregnant woman with pulmonary embolism and ischemic venous thrombosis. Tex Heart Inst J 2002; 29:130–132. 46. Yamagami T, Yoshimatsu R, Okubo T. Symptomatic deep venous thrombosis of the lower extremity in a pregnant woman successfully treated with endovascular procedures. J Obstet Gynaecol Res 2013; 39: 1059–1064. 47. DeStephano CC, Werner EF, Holly BP, Lessne ML. Diagnosis and management of iliac vein thrombosis in pregnancy resulting from MayThurner Syndrome. J Perinatol 2014; 34:566–568. 48. Lonjaret L, Lairez O, Galinier M, Minville V. Thrombolysis by recombinant tissue plasminogen activator during pregnancy: a case of massive pulmonary embolism. Am J Emerg Med 2011; 29:694.e1-e2. 49. Kaufman JA, Kinney TB, Streiff MB, et al. Guidelines for the use of retrievable and convertible vena cava filters: report from the Society of Interventional Radiology multidisciplinary consensus conference. J Vasc Interv Radiol 2006; 17:449–459. 50. Royal College of Obstetricians and Gynaecologists. Reducing the risk of thrombosis and embolism during pregnancy and the puerperium. Green-top guideline no 37a. 2009. Available at: https://www. rcog.org.uk/globalassets/documents/guidelines/gtg-37a.pdf. Accessed December 17, 2015. 51. Sultan AA, West J, Tata LJ, Fleming KM, Nelson-Piercy C, Grainge MJ. Risk of first venous thromboembolism in and around pregnancy: a population-based cohort study. Br J Haematol 2012; 156:366–373. 52. Baglin TP, Brush J, Streiff M. Guidelines on use of vena cava filters. Br J Haematol 2006; 134:590–595. 53. Greenfield LJ, Proctor MC. Suprarenal filter placement. J Vasc Surg 1998; 28:432–438, discussion 438. 54. International Commission on Radiological Protection. The 2007 recommendations of the International Commission on Radiological Protection. ICRP Publication 103. Ann ICRP 2007; 37:1–332. 55. Hodgkiss-Harlow K, Back MR, Brumberg R, et al. Technical factors affecting the accuracy of bedside IVC filter placement using intravascular ultrasound. Vasc Endovascular Surg 2012; 46:293–299. 56. Cohoon KP, McBride J, Friese JL, McPhail IR. Retrievable inferior vena cava filters can be placed and removed with a high degree of success: initial experience. Catheter Cardiovasc Interv 2014. 57. Andreoli JM, Lewandowski RJ, Vogelzang RL, Ryu RK. Comparison of complication rates associated with permanent and retrievable inferior vena cava filters: a review of the MAUDE database. J Vasc Interv Radiol 2014; 25:1181–1185. 58. PREPIC Study Group. Eight-year follow-up of patients with permanent vena cava filters in the prevention of pulmonary embolism: the PREPIC (Prevention du Risque d’Embolie Pulmonaire par Interruption Cave) randomized study. Circulation 2005; 112:416–422.
7.e1
Table E1 . Details of All Patients with an IVC Filter Placed during Pregnancy (4,5,7–48)
Indication
Location
G2P0
Left IF DVT
Unstable clot
Infrarenal
Jugular
Permanent Greenfield
26
–
36
Vaginal
Threatened preterm labor requiring tocolysis at 26 wk, retroperitoneal hematoma, and ileus
Twins, alive
Barnes et al (9), 1981 2 38
G6P5
PE
PE, patient concerned about risk of heparin
Infrarenal
Jugular
Permanent Greenfield
13
–
40
Vaginal
Pain and swelling in left leg for 2 wk after placement
Alive (8,9)
Hux et al (23), 1986 3 22
G2P1
Bilateral DVT and thrombi in vena cava
Heparin induced thrombocytopenia
Suprarenal
Jugular
Permanent Greenfield
33
–
35
Vaginal
None at 7 mo after delivery
Alive with mild respiratory distress
4
41
G6P4
Left thigh DVT
PE on therapeutic anticoagulation (heparin)
Unknown
Femoral
Permanent Greenfield
26
–
Term
Vaginal
None at 4-y follow-up
Alive
5
33
G3P2
Bilateral DVT and thrombi in vena cava
Significant bleeding on heparin (gastrointestinal)
Unknown
Jugular
Permanent Greenfield
22
–
35
Caesarean
None at 2.5-y followup
Alive with mild respiratory distress
6
25
G2P1
Left IF DVT
PE on therapeutic anticoagulation (heparin)
Unknown
Jugular
Permanent Greenfield
32
–
Term
Caesarean
None at 2-y follow-up
Alive
7
32
G6P5
Bilateral DVT
PE on therapeutic anticoagulation (heparin)
Unknown
Jugular
Permanent Greenfield
25
–
Term
Vaginal
None at 3-y follow-up
Alive
Left IF DVT
PE on therapeutic anticoagulation (heparin)
Unknown
Jugular
Permanent Greenfield
30 þ 2
–
38
Vaginal
None
Alive
Right DVT calf and thigh
PE on therapeutic anticoagulation (heparin)
Unknown
Jugular
Permanent Greenfield
9*
–
NA
NA
Narayan et al (36), 1992 10 26 G1P0
Left IF DVT
Unstable clot
Infrarenal
Femoral
Permanent Cardial
24
–
Miscarriage
NA
Miscarriage before filter insertion, edema of left leg slow to resolve
Twin fetuses died before filter at 23/ 40 wk
11
22
G1P0
Left IF DVT
Extensive thrombus
Infrarenal
Femoral
Permanent Cardial
39
–
40 þ 6
Vaginal
None
Alive
12
25
G1P0
Left IF DVT
Extensive thrombus
Infrarenal
Femoral
Permanent Cardial
37 þ 3
–
42
Vaginal
None
Alive
Banfield et al (21), 1990 8 28 G1P0
Eagle and Davies (10), 1990 9 35 Unknown
Filter Type
Delivery Gestation
Delivery Mode
Maternal Complications
Review: Inferior Vena Cava Filters in Pregnancy
VTE
Age (y)
Time in Situ (d)
’
GP
Scurr et al (4), 1981 1 30
Pt. No.
Insertion Gestation (wk)
Fetal Outcome (Apgar score 1 min, 5 min)
Insertion Route
Death of air embolus Maternal death in at filter placement first trimester
Harris et al ’
JVIR
(Continued)
Indication
Location
Left IF DVT
Extensive thrombus
Infrarenal
Femoral
Permanent Cardial
32
–
NA
Delivery Mode NA
None: not delivered at time of report
Not delivered at time of report
Left CF and right popliteal to IVC DVT
Heparin-induced thrombocytopenia
Unknown
Jugular
Permanent Bird’s nest
30
–
37
Vaginal
Threatened preterm labor requiring tocolysis at 30 wk
Alive (9,10)
PE
PE on therapeutic anticoagulation (heparin), heparin allergy
Suprarenal
Femoral and jugular
Permanent Greenfield
14 and 32
–
36
Caesarean
Cephalad propagation of large thrombus from filter, second filter placed, further symptomatic PE leading to delivery
Alive
Right IF and left iliac DVT
After neurosurgery, anticoagulation contraindicated
Suprarenal
Jugular
Permanent Greenfield
33
–
36
Vaginal
None at 6-mo followup
Alive
Thomas et al (20), 1997 17 26 G3P1
Unknown
Recurrent DVT, PE, and thrombophlebitis on heparin
Unknown
Unknown
Permanent Greenfield
31
–
38
Caesarean
None
Alive
18
29
G5P4
Unknown
DVT PE on heparin
Unknown
Unknown
33
–
36
Vaginal
None
Alive
19
34
G12P9
Unknown
Recurrent DVT, heparin failure and bleeding
Unknown
Unknown
Permanent Greenfield Permanent Greenfield
11
–
38
Vaginal
None
Alive
20
29
G2P1
Unknown
PE during pregnancy, possibility for recurrence
Unknown
Unknown
Permanent Greenfield
11
–
37
Vaginal
None
Alive
21
28
G2P1
Unknown
DVT with multiple PEs
Unknown
Unknown
24
–
38
Caesarean
None
Alive
22
21
G4P3
Unknown
DVT
Unknown
Unknown
11
–
38
Vaginal
None
Alive
23
30
G5P4
Unknown
DVT and PE
Unknown
Unknown
Permanent Greenfield Permanent Greenfield Permanent Greenfield
7
–
34
Vaginal
None
Alive
Neill et al (5), 1997 24 18
G1P0
Left IF DVT
PE on heparin
Infrarenal
Femoral
Retrievable Günther Tulip
37 þ 3
8
38
Caesarean
None
Alive
Geary et al (11), 1997 25 33
G1P0
Left IF DVT
Unstable clot extending during anticoagulation
Unknown
Jugular
Temporary filter
34 þ 6
6
34 þ 6
Caesarean
None
Alive
Owen and Krarup (37), 1997 26 37 G1P0
Left IF DVT
Recent extensive thrombosis and imminent delivery
Infrarenal
Femoral
Retrievable Günther Tulip
37 þ 3
12
37 þ 3
Caesarean
Wound hematoma
Alive
Number X
VTE
G1P0
Quayle et al (24), 1994 14 21 G1P0
Delivery Gestation
’
GP
28
Filter Type
Time in Situ (d)
Fetal Outcome (Apgar score 1 min, 5 min)
Age (y)
Pt. No. 13
Insertion Gestation (wk)
Maternal Complications
Insertion Route
Volume XX
Table E1. Details of All Patients with an IVC Filter Placed during Pregnancy (4,5,7–48) (continued )
’ ’
2015
Ricciotti et al (27), 1995 16 31 G3P1
Month
Arbogast et al (25), 1994 15 25 G1P0
(Continued)
7.e2
7.e3
Table E1. Details of All Patients with an IVC Filter Placed during Pregnancy (4,5,7–48) (continued )
Left IF DVT
Extensive unstable clot
Infrarenal
Jugular
Retrievable Günther Tulip
25
Not removed
37
Vaginal
Filter not removed, extensive clot still present after 9 d full anticoagulation
Alive
Left IFP DVT
Extension into iliac veins, perceived high risk of PE
Suprarenal
Jugular
Temporary Tempofilter
34
5
34
Caesarean
Migration of filter having buckled
Alive
Jugular
Permanent Greenfield
Unknown
–
Unknown
Unknown
None at long-term follow-up (mean, 78 mo) apart from 4 patients with significant leg swelling due to partial resolution of DVT, treated conservatively
Alive
30
Jugular
31
Jugular
32
Jugular
33
Jugular
34
Jugular
35
Jugular
36
Jugular
37
Jugular
38
Jugular
39
Jugular
40
Jugular
41
Jugular
42
Jugular
43
Jugular
44
Jugular
Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield Permanent Greenfield
Kelly and Boyd (28), 1999 28 24 Unknown
Aburahma et al (7,8), 1999 and 2001 29 Mean, 25 Unknown 14 IFP, 4 femoro(range, popliteal (left, n = 19–31) 13; right, n = 5)
PE during therapeutic Infrarenal (n = antico10), suprarenal agulation (n = 3), (n = 8) significant bleeding during anticoagulation (n = 2), freefloating iliofemoral DVT (n = 4), heparin-induced thrombocytopenia (n = 2), iliofemoral popliteal DVT 1–3 wk before labor (n = 7)
Filter Type
Delivery Mode
Maternal Complications
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
–
Alive
Harris et al
Location
GP
Delivery Gestation
Review: Inferior Vena Cava Filters in Pregnancy
Indication
Age (y)
Time in Situ (d)
’
VTE
Pt. No.
Adams et al (38), 1998 27 20 G1P0
Insertion Gestation (wk)
Fetal Outcome (Apgar score 1 min, 5 min)
Insertion Route
’
JVIR
(Continued)
Pt. No.
Age (y)
GP
VTE
Indication
Location
Insertion Route
46
Jugular
Brenner et al (44), 2001 47 29 Unknown
Delivery Mode
Maternal Complications
Fetal Outcome (Apgar score 1 min, 5 min)
–
Alive
–
Alive
PE and IVC thrombus
IVC thrombus posing high risk of PE during labor
Suprarenal
Femoral
Retrievable Günther Tulip
33
8
33 þ 1
Vaginal
None
Alive
Unknown
DVT resistant to anticoagulation with heparin, high peripartum PE risk
Suprarenal
Jugular
Temporary Tempofilter
31–37
21⫾ 6
14–18 d after insertion
Caesarean
None
Alive
Temporary Tempofilter Temporary Tempofilter Temporary Tempofilter
Caesarean
None
Alive
Caesarean
None
Alive
Caesarean
None
Alive
Jugular
50
Unknown
Infrarenal
Jugular
51
Unknown
Infrarenal
Jugular
Neri et al (45), 2002 52 22
Unknown
Left ischemic VTE and possible PE
Ischemic venous thrombosis and possible PE before surgical thrombectomy
Unknown
Jugular
Retrievable Prolyser
11
2
Term
Vaginal
None at 18-mo follow-up
Alive
PE
PE and thrombophilia, prophylactic
Infrarenal
Subclavian
Permanent Bird’s Nest
26
–
31
Caesarean
Premature rupture of membranes
Alive
Unknown
Left IF DVT
Failure of anticoagulation
Suprarenal
Subclavian
Retrievable Günther Tulip
35
19*
37
Vaginal
None
Alive
Ishikawa et al (29), 2003 55 29 Unknown
Left IF DVT
Occlusive DVT, high risk of PE
Infrarenal
Subclavian
Temporary Neuhaus Protect
32 þ 3
15
32 þ 3
Caesarean
Edematous leg at 15mo follow-up
Alive
Right FP DVT
Persistent symptoms despite anticoagulation and imminent labor
Unknown
Jugular
Retrievable Günther Tulip
35 þ 3
14
36
Caesarean
None
Alive
Deep veins of both legs
Growing clot and symptomatic of PE on therapy
Suprarenal
Not stated
Removable Zontik filter
33
5
33 þ 3
Caesarean
None
Alive
IF DVT (unilateral)
Extensive DVT near time of labor
Infrarenal
Jugular
Removable Tulip
39*
2
39
Vaginal
None
Alive
Hynek et al (26), 2002 53 36 Unknown
54
30
Reddy et al (30), 2003 56 17
G1P0
Burov and Kapranov (22), 2005 57 40 G3P0
Clark et al (39), 2005 58 21
G1P0
7.e4
(Continued)
2015
Infrarenal
’
Unknown
Month
49
’
Ferraro et al (12), 2001 48 Mean 29 ⫾ Unknown 8 (SD)
Filter Type Permanent Greenfield Permanent Greenfield
Delivery Gestation
Number X
Jugular
Time in Situ (d)
’
45
Insertion Gestation (wk)
Volume XX
Table E1. Details of All Patients with an IVC Filter Placed during Pregnancy (4,5,7–48) (continued )
7.e5
Table E1. Details of All Patients with an IVC Filter Placed during Pregnancy (4,5,7–48) (continued )
GP
Kawamata et al (32), 2005 60 27 G1P0
VTE
Indication
Location
Left CF, great saphenous and popliteal
Extensive DVT
Infrarenal
Jugular
Retrievable Günther Tulip
38 þ 1
19
38 þ 2
Caesarean
Feverish diarrhea (treated with erythromycin)
Alive
Right EI DVT
DVT developed during pregnancy History of DVT, on anticoagulation when not pregnant DVT developed during pregnancy DVT developed during pregnancy
Suprarenal
Jugular
Antheor rIVC
Unknown
9
36
Caesarean
None
Alive
Suprarenal
Unknown
Antheor rIVC
11
37
Vaginal
None
Alive
Suprarenal
Cubital
Antheor rIVC
7
38
Vaginal
None
Alive
Suprarenal
Cubital
Antheor rIVC
14
33
Caesarean
Alive
Suprarenal
Cubital
Antheor rIVC
3
40
Vaginal
Large thrombus captured in filter not dissolved by thrombolysis, temporary filter changed and permanent filter placed None
Alive
Suprarenal Suprarenal
Cubital Cubital
Antheor rIVC Antheor rIVC
4 6
38 39
Vaginal Vaginal
None None
Alive Alive
Suprarenal
Cubital
Antheor rIVC
8
37
Vaginal
None
Alive
Suprarenal
Jugular
4
37
Vaginal
None
Alive
Suprarenal
Jugular
Neuhaus protect rIVC Antheor rIVC
7
37
Vaginal
None
Alive
Suprarenal
Jugular
Antheor rIVC
5
37
Vaginal
None
Alive
Infrarenal
Jugular
40 þ 2
10
40 þ 3
Vaginal
None
Alive
Infrarenal
Femoral
Günther temporary Recovery nitinol IVC filter
37
75
38
Vaginal
Filter migration and fracture; leg hook retained at removal, patient remained asymptomatic
Alive
Unknown
Jugular
Retrievable
36
13
36
Vaginal
None
Alive
26
Attempt at 167
37
Caesarean
Failed retrieval, inferior migration, two struts in right renal vein, tilting, fractured strut in right hepatic lobe
61
32
G3P3
Left EI DVT
62
30
G0P0
Left CI DVT
63
32
G1P1
Left CI DVT
64
33
G2P2
Left CI DVT
65 66
24 39
G1P1 G0P0
Right EI DVT Right femoral DVT
67
27
G1P0
IVC
68
28
G2P1
IVC
69
33
G0P0
Left CI DVT
70
34
G2P2
Left EI DVT
Cheung et al (13), 2005 71 30 G1P0 72
29
Left femoral DVT
G2P1
Left IF DVT
Jamjute et al (40), 2006 73 34 G1P0
Left IF DVT
DVT developed during pregnancy Floating thrombi DVT developed during pregnancy DVT developed during pregnancy Floating thrombi DVT developed during pregnancy History of DVT, on anticoagulation when not pregnant Occlusive DVT (concern of labor and delivery) Extension of occlusive DVT despite anticoagulation
Extensive DVT and onset of labor 24 h after presentation
Filter Type
Delivery Gestation
Delivery Mode
Maternal Complications
Review: Inferior Vena Cava Filters in Pregnancy
Age (y)
Time in Situ (d)
’
Pt. No.
Ioakeimidou and Aziz (31), 2005 59 18 G1P0
Insertion Gestation (wk)
Fetal Outcome (Apgar score 1 min, 5 min)
Insertion Route
OptEase Ganguli et al (14), 2006 74 40 G1P0
PE
Suprarenal
Femoral
Recovery
Harris et al
Recurrent PE on therapeutic anticoagulation
’
JVIR
(Continued)
GP
VTE
Indication
Location
G1P0
Bilateral femoral DVT
Extensive mobile clot
Infrarenal
Jugular
Delivery Mode
Fetal Outcome (Apgar score 1 min, 5 min)
38 þ 5
Vaginal
None
Alive twins
6
38
Vaginal
None
Alive
Number X
Age (y)
Maternal Complications
’
Pt. No.
Opara et al (41), 2006 85 29
Insertion Route
40
3
40
Caesarean
None
Alive
ALN
37
3
37
Caesarean
None
Alive
ALN
36
3
37
Vaginal
None
Alive
ALN
38
9
38
Caesarean
None
Alive
ALN
39
6
39
Caesarean
None
Alive
ALN
40
–
41
Vaginal
Failed retrieval
Alive
ALN
36
30
39
Vaginal
None
Alive
ALN
36
22
39
Vaginal
None
Alive
ALN
37
5
37
Vaginal
None
Alive
Attempt at 6 or 38 d
38
Caesarean
Alive (9,9)
34
Caesarean
Filter Type
Insertion Gestation (wk)
Time in Situ (d)
Delivery Gestation
Retrievable
37 þ 5
14
ALN
38
ALN
Günther Tulip Sendon et al (15), 2008 75 Unknown Unknown
Unknown
77
VTE near time of labor
Suprarenal
Jugular
78
Suprarenal
Jugular
Suprarenal
Jugular
80
Failed medical treatment Heparin-induced thrombocytopenia VTE near time of labor
Suprarenal
Jugular
81
VTE near time of labor
Suprarenal
Jugular
82
Failed medical treatment Failed medical treatment VTE near time of labor
Suprarenal
Jugular
Suprarenal
Jugular
Suprarenal
Jugular
79
83 84 Gupta et al (16), 2008 86 25
P0
IF DVT
DVT, threatened preterm labor
Unknown
Jugular
Retrievable
34
87
22
P1
PE
Massive PE
Unknown
Jugular
Retrievable
30
88
23
P0
DVT
Unknown
Jugular
Permanent
11
NA
37
Caesarean
89
35
P0
IF DVT
DVT recurrent during anticoagulation DVT, threatened preterm labor
Threatened preterm labor requiring tocolysis at 34 wk; failed retrieval, inability to snare filter Failed retrieval, inability to snare filter None
Unknown
Jugular
Permanent
35
NA
41
Vaginal
None
Alive (9, 9)
Hidaka et al (17), 2008 90 35
GP0
Left FP DVT
VTE on anticoagulation
Infrarenal
Jugular
Retrievable Neuhaus Protect
37 þ 0
12
37 þ 5
Vaginal
Large trapped embolus not lysed, temporary filter exchanged for permanent filter
Alive (8, 9)
Sparrow (18), 2009 91 27
P1G0
Left IF DVT
Possible PE (refused CT) on LMWH
Suprarenal
Unknown
Retrievable Günther Tulip
30
Attempt at 73
40
Vaginal
Failed retrieval
Alive
IF DVT
Main criterion for filter insertion was fresh nonorganized or floating thrombus in iliac veins or IVC at time of delivery
Suprarenal
Jugular
Retrievable Günther Tulip
Unknown
Mean, 11 (range, 9–12)
Unknown
Caesarean
None (three had minor tilt of 51–171, all successfully retrieved)
Alive
Köcher et al (42), 2009 92 Mean 27.4 Unknown (range 20-42)
2015
Jugular
’
Suprarenal
Retrievable filter Retrievable filter Retrievable filter Retrievable filter Retrievable filter Retrievable filter Retrievable filter Retrievable filter Retrievable filter Retrievable filter
Month
Jugular
’
Suprarenal
76
Failed medical treatment VTE near time of labor
Volume XX
Table E1. Details of All Patients with an IVC Filter Placed during Pregnancy (4,5,7–48) (continued )
Alive (5,10) Alive (9,9)
7.e6
(Continued)
7.e7
Table E1. Details of All Patients with an IVC Filter Placed during Pregnancy (4,5,7–48) (continued )
IF DVT
Suprarenal
Jugular
94
IF DVT
Suprarenal
Jugular
95
IF DVT
Suprarenal
Jugular
96
IF DVT
Suprarenal
Jugular
97
IF DVT
Suprarenal
Jugular
98
IF DVT
Suprarenal
Jugular
99
IF DVT
Suprarenal
Jugular
Pt. No.
Age (y)
Milford et al (33), 2009 100 31
GP
G2
McConville et al (43), 2009 101 34 G1P0
102
32
G2P1
Lonjaret et al (48), 2011 103 33 G3P1
VTE
Indication
Filter Type
Time in Situ (d)
Delivery Gestation
Retrievable Günther Tulip Retrievable Günther Tulip Retrievable Günther Tulip Retrievable Günther Tulip Retrievable Günther Tulip Retrievable Günther Tulip Retrievable Günther Tulip
Delivery Mode
Maternal Complications
Fetal Outcome (Apgar score 1 min, 5 min)
Caesarean
Alive
Caesarean
Alive
Caesarean
Alive
Caesarean
Alive
Caesarean
Alive
Caesarean
Alive
Caesarean
Alive
Suprarenal
Jugular
Retrievable Cook Celect
39 þ 5
7
40 þ 0
Vaginal
None
Alive
Bilateral
Extensive floating thrombus
Suprarenal
Unknown
Retrievable OptEase
38 þ 2
Attempt at 28
39
Vaginal
Failed retrieval, filter tilt
Alive
Left IF DVT
Free-floating thrombus
Suprarenal
Unknown
Retrievable OptEase
38
Attempt at 28
39
Caesarean
Failed retrieval, filter tilt
Alive
PE and left IF DVT
Massive PE requiring thrombolysis
Unknown
Jugular
Retrievable
31 þ 0
Unknown
38
Vaginal
None (minor epistaxis)
Alive
Retrievable OptEase Retrievable OptEase Retrievable OptEase Retrievable OptEase
39
13
39
Caesarean
None at 12 mo
Alive
39
15
39
Caesarean
None at 12 mo
Alive
38
12
38
Caesarean
None at 12 mo
Alive
40
14
40
Caesarean
Alive
Retrievable OptEase Retrievable OptEase Retrievable OptEase
39
12
39
Caesarean
Unilateral leg swelling with partial resolution of DVT at 3 mo, nothing else at 48 mo None at 12 mo
Alive
38
14
38
Caesarean
None at 12 mo
Alive
41
14
41
Caesarean
Unilateral leg swelling with partial resolution of DVT at 3 mo, nothing else at 28 mo
Alive
Liu et al (34), 2012 104 26
G1P0
Left IFP DVT
Extensive DVT
Suprarenal
Jugular
105
29
G1P1
Left IFP DVT
Extensive DVT
Suprarenal
Jugular
106
20
G1P0
Left PF DVT
Extensive DVT
Suprarenal
Jugular
107
31
G1P0
Left IFP DVT
Extensive DVT
Suprarenal
Jugular
108
28
G1P0
Right IFP DVT
Extensive DVT
Suprarenal
Jugular
109
27
G1P0
Left PF DVT
Extensive DVT
Suprarenal
Jugular
110
33
G1P1
Left IFP DVT
Extensive DVT
Suprarenal
Jugular
’
Extensive DVT
Harris et al
Left IF DVT
Review: Inferior Vena Cava Filters in Pregnancy
93
Insertion Gestation (wk)
’
Location
Insertion Route
JVIR
(Continued)
Delivery Mode
Maternal Complications
Fetal Outcome (Apgar score 1 min, 5 min)
Caesarean
None at 12 mo
Alive
39
Caesarean
None at 12 mo
Alive
12
38
Caesarean
None at 12 mo
Alive
37
NA
37
Caesarean
Alive
Retrievable OptEase Retrievable OptEase Retrievable OptEase Retrievable OptEase
39
14
39
Caesarean
Device not retrieved as device occluded with thrombus, unilateral leg swelling with partial resolution of DVT at 3 mo, nothing else at 18 mo None at 12 mo
Alive
39
12
39
Caesarean
None at 12 mo
Alive
41
13
41
Caesarean
None at 9 mo
Alive
40
14
40
Caesarean
None at 6 mo
Alive
GP
VTE
Indication
Location
111
31
G1P0
Left IFP DVT
Extensive DVT
Suprarenal
Jugular
112
25
G1P0
Left PF DVT
Extensive DVT
Suprarenal
Jugular
113
28
G1P0
Right IFP DVT
Extensive DVT
Suprarenal
Jugular
114
41
G1P1
Left gastrocnemius vein DVT
Extensive DVT
Suprarenal
Jugular
115
35
G1P1
Left IFP DVT
Extensive DVT
Suprarenal
Jugular
116
26
G1P0
Left IFP DVT
Extensive DVT
Suprarenal
Jugular
117
32
G1P0
Left PF DVT
Extensive DVT
Suprarenal
Jugular
118
29
G1P0
Left PF DVT
Extensive DVT
Suprarenal
Jugular
Nakajima et al (35), 2012 119 27 G1P0
Left IF DVT
Extensive thrombosis, risk of PE at delivery
Infrarenal
Jugular
Temporary filter
36
19
37þ5
Vaginal
None at 12 mo (patient had MTS)
Alive (8, 9)
Right EI to intramuscular veins of gastrocnemius DVT
Phlebothrombosis, extensive DVT on anticoagulation
Infrarenal
Unknown
Permanent TrapEase
30þ0
NA
37þ0
Vaginal
None
Alive
Left calf vein to left CI DVT
Extensive DVT and planned endovascular procedures
Suprarenal
Jugular
Retrievable Günther Tulip
34 þ 0
30
35 þ 1
Caesarean
IVC filter exchanged twice postpartum while endovascular DVT treatment was carried out (successfully removed)
Alive
Left calf vein to left CI DVT/PE (asymptomatic, seen on CT) Left calf vein to left CI DVT
Percutaneous PMT for ongoing pain/risk for PTS
Suprarenal
Unknown
Retrievable
18 þ 2
64
39 þ 3
Caesarean
None (patient had MTS)
Alive (8, 9)
Percutaneous PMT for ongoing pain/risk for PTS
Suprarenal
Unknown
Retrievable
30 þ 5
Unknown
37 þ 6
Vaginal
Alive (9, 9)
Percutaneous PMT for ongoing pain/risk for PTS
Suprarenal
Unknown
Retrievable
35 þ 1
66
38 þ 4
Vaginal
None related to IVC filter (partial rethrombosis of DVT and pain, patient had MTS) None (patient had MTS)
Pt. No.
G1P0
124
18
G1P0
Left IFP DVT/PE (asymptomatic, seen on CT)
14
39
39
9
38
2015
30
39
Filter Type
’
123
Retrievable OptEase Retrievable OptEase Retrievable OptEase Retrievable OptEase
Month
DeStephano et al (47), 2014 122 28 G6P0
Delivery Gestation
’
Yamagami et al (46), 2013 121 24 Unknown
Time in Situ (d)
Number X
Valadares et al (19), 2013 120 27 G2P1
Insertion Gestation (wk)
’
Age (y)
Insertion Route
Volume XX
Table E1. Details of All Patients with an IVC Filter Placed during Pregnancy (4,5,7–48) (continued )
Alive (9, 9)
CF ¼ common femoral; CI ¼ common iliac; CIV ¼ common iliac vein; DVT ¼ deep vein thrombosis; EI ¼ external iliac; GP ¼ gravidity/parity; IF ¼ ileofemoral; IFP ¼ ileofemoropopliteal; IVC ¼ inferior vena cava; LMWH ¼ low molecular weight heparin; NA ¼ not applicable; PE ¼ pulmonary embolism; PF ¼ popliteal–femoral; MTS ¼ May–Thurner syndrome; PMT ¼ pharmacomechanical thrombectomy; PTS ¼ postthrombotic syndrome; VTE ¼ venous thromboembolism. n
Approximate.
7.e8