The present invention relates generally to a vascular filter and more particularly to an absorbable vascular filter deployed within a vessel for temporary filtering of body fluids. A preferred embodiment is the placement of such absorbable vascular filter within the inferior vena cava (IVC) for the prevention of pulmonary embolisms for a specific duration of time determined by the absorption properties of the filter.
Between 100,000 to 300,000 Americans die annually from pulmonary embolism (PE)—more than breast cancer and AIDS combined—representing the 3rd leading cause of death in the US [1-5]. A similar incidence of PE is found in Europe with approximately 370,000 annual deaths [6]. Moreover, PE is the 3rd most common cause of death in trauma patients that survive the first 24 hours. An estimated 25% of all hospitalized patients have some form of deep vein thrombosis (DVT) which is often clinically unapparent unless PE develops [7]. On average, 33% of DVT will progress to symptomatic PE of which 10% will be fatal [6].
The US Surgeon General has recognized this alarming statistic and in 2008 issued a formal Call to Action to Prevent DVT and PE [1]. Unfortunately, DVT/PE disproportionately affects the elderly, in part due to prolonged periods of inactivity following medical treatment. The incidence is relatively low under the age of 50 (1/100,000), then accelerates exponentially reaching 1000/100,000 by the age of 85 [8]. Consequently the US Surgeon General has proclaimed that the growth in number of DVT/PE cases with an aging US population may outpace the population growth in the absence of better prevention [1].
Risk factors for PE arising from DVT follow Virchow's Triad [9]: (i) endothelial injury, (ii) hypercoaguability, and (iii) hemodynamic changes (stasis or turbulence). Hence specific risk factors include hip and knee arthroplasty, abdominal, pelvic and extremity surgeries, pelvic and long bone fractures, prolonged immobility such as prolonged hospital stays and air travel, paralysis, advanced age, prior DVT, cancer, obesity, COPD, diabetes and CHF. Orthopedic surgeons are especially concerned since their patients carry a 40%-80% risk for DVT and PE following knee and hip surgeries in the absence of prophylactic treatment [10-12].
The American Academy of Orthopaedic Surgeons (AAOS) has issued guidelines for PE prophylaxis. Basically, patients at standard risk should be considered for chemoprophylactic agents such as aspirin, low molecular weight heparin (LMWH), synthetic pentassaccharides, or warfarin, in addition to intra-operative and/or immediate postoperative mechanical prophylaxis [13].
Aspirin has a 29% relative risk reduction in symptomatic DVT and a 58% relative risk reduction in fatal PE [14]. LMWH carries a 30% risk reduction in DVT and has been proven more effective than unfractionated heparin in high risk groups such as hip and knee arthroplasty [7]. Warfarin started within 24 to 48 hours of initiating heparin with a goal of achieving international normalized ratio (INR) results between 2 and 3 as secondary thromboprophylaxis for 3 months reduces the risk of recurrent venous thromboembolism (VTE) by 90% as compared with placebo [15,16]. Mechanical prophylaxis, consisting of pneumatic compression devices that repeatedly compress the legs with an air bladder, are also utilized in conjunction with anticoagulants to reduce the occurrence of PE.
The duration of prophylaxis depends on the source of potential DVT. Current recommendations for prophylaxis consist of a minimum 7-10 days for moderate to high risk surgeries and up to 28-35 days for many orthopedic surgeries. Specifically for orthopedic trauma, DVT prophylaxis is continued until patient mobilization (32%), inpatient discharge (19%), 3 weeks postop (16%), 6 weeks postop (27%), and in rare circumstances greater than 6 weeks (7%) [17]. Studies indicate that hypercoaguability persists for at least one month after injury in 80% of trauma patients [18]. Regarding total knee and hip arthroplasty and cancer surgeries, 35 day prophylactic treatment is recommended [12, 19]. Overall, prophylactic treatment for possible VTE is often warranted for up to 6 weeks following trauma or major surgery.
Contraindications for chemoprophylaxis include active bleeding, hemorrhagic diathesis, hemorrhagic stroke, neurologic surgery, excessive trauma, hemothorax, pelvic or lower extremity fractures with intracranial bleeding, anticoagulation interruption, and recent DVT/PE patients undergoing surgery.
For patients who are contraindicated for the above-mentioned anti-coagulation prophylaxis, or where anti-coagulation therapy has failed, the AAOS, American College of Physicians, and the British Committee of Standards in Haematology all recommend the use of inferior vena cava (IVC) filters [13, 20, 21]. These intravascular metal filters are deployed via catheter into the IVC to essentially catch emboli arising from DVT before reaching the lungs resulting in PE. Furthermore, the British Committee of Standards in Hematology recommends IVC filter placement in pregnant patients who have contraindications to anticoagulation and develop extensive VTE shortly before delivery (within 2 weeks).
The Eastern Association for Surgery of Trauma further recommends prophylactic IVC filters placed in trauma patients who are at increased risk of bleeding and prolonged immobilization [22]. Such prophylactic recommendation follows studies that demonstrate a low rate of PE in patients with severe polytrauma who underwent IVC placement [23-25]. In fact the fastest growing indication of overall IVC filter usage, from 49,000 in 1999 to 167,000 in 2007 with a projected 259,000 units for 2012, is the prophylactic market utilizing retrievable IVC filters [26, 27].
Example vascular filters primarily for IVC placement are disclosed in U.S. Pat. Nos. 4,425,908; 4,655,771, 4,817,600; 5,626,605; 6,146,404; 6,217,600 B1; 6,258,026 B1; 6,497,709 B1; 6,506,205 B2; 6,517,559 B1; 6,620,183 B2; U.S. Pat. App. Pub. No. 2003/0176888; U.S. Pat. App. Pub. No. 2004/0193209; U.S. Pat. App. Pub. No. 2005/0267512; U.S. Pat. App. Pub. No. 2005/0267515; U.S. Pat. App. Pub. No. 2006/0206138 A1; U.S. Pat. App. Pub. No. 2007/0112372 A1; U.S. Pat. App. Pub. No. 2008/0027481 A1; U.S. Pat. App. Pub. No. 2009/0192543 A1; U.S. Pat. App. Pub. No. 2009/0299403 A1; U.S. Pat. App. Pub. No. 2010/0016881 A1; U.S. Pat. App. Pub. No. 2010/0042135 A1; and U.S. Pat. App. Pub. No. 2010/0174310 A1.
IVC filter efficacy has been demonstrated in several class I and II evidence studies [22, 28-30]. Most of the earlier filters installed were expected to be permanent fixtures since endothelialization occurs within 7-10 days making most models impractical to remove without irreversible vascular damage leading to life threatening bleeding, dissection of the IVC, and thrombosis. Although these permanent filters have prevented PE, they have been shown to actually increase the risk of recurrent DVT over time.
Specifically, a Cochrane review [31] on the use of IVC filters for the prevention of PE cites a level I randomized prospective clinical trial by Decousus et al. [32] wherein the incidence of DVT with the IVC filter cohort increased almost 2-fold: (i) 21% incidence of recurrent DVT in the filter cohort vs. 12% in the non-filter LMWH cohort at 2 years (p=0.02), and (ii) 36% incidence of recurrent DVT in the filter cohort vs. 15% in the non-filter group at 8 years (p=0.042) [33]. However, the filters did reduce the occurrence of PE; the filter cohort experiencing only 1% PE vs. the non-filter cohort posting 5% PE in the first 12 days (p=0.03). No statistically significant difference in mortality rate was seen in any time frame investigated. Apparently the initial benefit of reduced PE with permanent IVC filters is offset by an increase in DVT, without any difference in mortality.
In addition to increased incidence of DVT for prolonged IVC filter deployment, filter occlusion has been reported with a 6% to 30% occurrence, as well as filter migration (3% to 69%), venous insufficiency (5% to 59%), and post thrombotic syndrome (13% to 41%) [34-36]. Complications from insertion including hematoma, infection, pneumothorax, vocal cord paralysis, stroke, air embolism, misplacement, tilting arteriovenous fistula, and inadvertent carotid artery puncture have an occurrence rate of 4%-11% [37].
Temporary or retrievable IVC filters have been marketed more recently intended to be removed once the risk of PE subsides, and hence circumvent many of the deleterious complications of permanent filters. The retrievable filters feature flexible hooks, collapsing components, and unrestrained legs to ease retrieval. Unfortunately these same features have led to unwanted filter migration, fatigue failure, IVC penetration, fragment migration to hepatic veins and pulmonary arteries, filter tilt, and metallic emboli [38-43]. Since 2005, 921 adverse filter events have been reported to the FDA including 328 device migrations, 146 device detachments (metallic emboli), 70 perforations of the IVC, and 56 filter fractures [44]. Some retrievable brands post alarming failure rates such as the Bard Recovery filter with 25% fracturing over 50 months which embolized end organs. 71% of the fractures embolized to the heart caused life threatening ventricular tachycardia, tamponade, and sudden death in some cases. An alternative retrievable model, Bard G2, resulted in 12% fractures over 24 months [45]. Such prevalence of device fractures is postulated to be directionally proportional to indwell time.
These failures and others prompted the FDA in August 2010 to issue a formal communication stating that “FDA recommends that implanting physicians and clinicians responsible for the ongoing care of patients with retrievable IVC filters consider removing the filter as soon as protection from PE is not longer needed” [44]. Even though these types of retrievable filters are intended to be removed in months time, several studies indicate that approximately 70%-81% of patients with retrievable IVC filters fail to return to the hospital for filter removal, thereby exposing hundreds of thousands of patients to the life-threatening adverse events of prolonged retrievable IVC filter placement [41, 44, 46-48]. These patients are either lost to follow-up, or refuse to have the filters removed in the absence of complications.
The present invention comprises systems and methods for filtering fluids. Certain embodiments comprise a novel absorbable vascular filter that temporarily prevents pulmonary embolism by capturing and restraining emboli within a body vessel. The absorbable vascular filter, according to certain aspects of the invention, possesses various advantages over all conventional vascular filters, including permanent, temporary, and optional IVC filters. Most importantly, the absorbable vascular filter disclosed herein is slowly biodegraded within the vessel according to a planned schedule engineered by the choice of absorbable filter materials which prevents the requirement of filter removal. Moreover, the absorbable vascular filter elements are manufactured from non-metallic synthetic polymers which do not adversely impact end organs upon carefully planned degradation as exhibited by conventional metal IVC filters that migrate and often become fractionated. Also due to the relative short indwell time (months) of the absorbable vascular filter, the paradoxical increase in DVT seen with conventional long-term IVC filters is likely circumvented.
Embodiments of the present invention will now be described in detail with reference to the drawings and pictures, which are provided as illustrative examples so as to enable those skilled in the art to practice the invention. Notably, the figures and examples below are not meant to limit the scope of the present invention to a single embodiment, but other embodiments are possible by way of interchange of some or all of the described or illustrated elements. Wherever convenient, the same reference numbers will be used throughout the drawings to refer to same or like parts. Where certain elements of these embodiments can be partially or fully implemented using known components, only those portions of such known components that are necessary for an understanding of the present invention will be described, and detailed descriptions of other portions of such known components will be omitted so as not to obscure the invention. In the present specification, an embodiment showing a singular component should not be considered limiting; rather, the invention is intended to encompass other embodiments including a plurality of the same component, and vice-versa, unless explicitly stated otherwise herein. Moreover, applicants do not intend for any term in the specification or claims to be ascribed an uncommon or special meaning unless explicitly set forth as such. Further, the present invention encompasses present and future known equivalents to the components referred to herein by way of illustration.
Referring to the embodiment depicted in
Such engineered, sequential bioabsorption/biodegradation of the capture elements can be achieved with numerous synthetic materials. The goal is to select the absorbable filter materials to match a desired filter indwell time. Per the prior background section, a filter indwell time of 6 weeks would be suitable for an IVC filter to prevent PE following trauma or in conjunction with major surgeries. Synthetic materials which can be used to form the capture elements include:
Polydioxanone (PDO, PDS)—colorless, crystalline, biodegradable synthetic polymer of multiple repeating ether-ester units. In suture form, PDS II (Ethicon, Somerville, N.J.) size 4/0 and smaller maintains 60%, 40%, and 35% of its tensile strength at 2, 4, and 6 weeks respectively. For PDS II size 3/0 and larger, it retains 80%, 70%, and 60% of its tensile strength at 2, 4, and 6 weeks respectively. In addition to providing wound support for 6 weeks, PDS II suture is fully absorbed in 183-238 days via hydrolysis making it a strong candidate for IVC filter applications. Basically absorption is minimal in the first 90 days and is essentially complete in 6 months. Finally, PDS has a low affinity for microorganisms and possesses minimal tissue reaction.
Polytrimethylene carbonate (Maxon)—similar to PDS in absorption profile yet with slightly higher breaking strength. Maxon (Covidien, Mansfield, Mass.) maintains 81%, 59%, and 30% of its tensile strength at 2, 4, and 6 weeks respectively, and is fully hydrolyzed in 180-210 days.
Polyglactin 910 (Vicryl)—braided multifilament coated with a copolymer of lactide and glycolide (polyglactin 370). In suture form, Vicryl (Ethicon) size 6/0 and larger maintains 75%, 50%, and 25% of its tensile strength at 2, 3, and 4 weeks respectively and is fully absorbed in 56-70 days.
Polyglycolic acid (Dexon)—similar to Polyglactin, made from polyglycolic acid and coated with polycaprolate. Dexon has similar tensile strength and absorption profile as Polyglactin.
Poliglecaprone 25 (Monocryl)—synthetic copolymer of glycolide and e-caprolactone. Monocryl (Ethicon) maintains 50%-70% and 20%-40% of its tensile strength at 1 and 2 weeks respectively and is fully absorbed in 91-119 days.
Polylacticoglycolic acid (PLGA) copolymer of monomers glycolic acid and lactic acid. Different forms and properties of PLGA can be fabricated by controlling the ratio of lactide to glycolide for polymerization. Like the other synthetic absorbable materials, PLGA degrades by hydrolysis with the absorption profile dependent on the monomer ratio; the higher content of glycolide, the faster degradation. However, the 50:50 copolymer exhibits the fastest degradation at 2 months. Since the polymer degrades in the body to produce lactic acid and glycolic acid, both being normal physiological substances, PLGA poses minimal systemic toxicity.
Poly L-lactic Acid (PLA) is also a polymer made from lactic acid yet with considerable longevity. In soft tissue approximation, PLA remains intact for 28 weeks, and is fully absorbed within 52 weeks.
As an example of engineering capture elements to sequentially degrade following the period of PE protection, the proximal capture elements 30,41 could be fabricated with PDS II size 4/0 (0.15 mm dia.), while the middle capture elements 31,40 fabricated with size 2/0 (0.3 mm dia.), and finally the distal capture elements 32 fabricated with size 2 (0.5 mm) PDS II suture.
As an alternative to assembling a plurality of capture elements, the vascular filter can be fabricated with absorbable or non-absorbable composite mesh. Candidates for a mesh capture system include polypropylene such as C-QUR (Atrium Medical Corp. Hudson N.H.), polypropylene encapsulated by polydioxanone as in PROCEED (Ethicon, Somerville, N.J.), polypropylene co-knitted with polyglycolic acid fibers as in Bard Sepramesh I P Composite (Davol, Inc., Warwick, R.I.), polyethylene terephathalate as in Parietiex Composite (Covidien, Mansfield, Mass.), and ePTFE used in DUALAMESH (W. Gore & Assoc. Inc., Flagstaff, Ariz.).
Regarding the circumferential element 2 in
Referring to the embodiment depicted in
The circumferential stent element 2 in
A specific embodiment of an absorbable vascular filter with sequential degradation was constructed, tested, and evaluated with assorted polydioxanone sutures (sizes 3-0, 2-0, 0, and 1) and is shown in
The primary endpoint for evaluating the absorbable polymers for vascular filter application was load at break as a function of time. In addition to the absorbable filters pictured in
The candidate absorbable polymers (representing capture elements) sewn into the test cells were embedded in a closed circulation system engineered to mimic human cardio physiology. At weekly intervals, the system was shut down to extract sutures of each size and type to perform destructive tensile testing. As a control, identical absorbable sutures were submerged into a static buffer bath (StableTemp digital utility bath, Cole-Parmer, Vernon Hill, Ill.) held at 37° C. and also tested on a weekly basis. The hypothesis being that the increased thermodynamics of the circulation system accelerates both absorption rate and tensile strength loss of the capture elements.
The closed circulation system was constructed with thin walled ¾″ PVC with od 26.7 mm that fit snug inside the flexible 25.4 mm id Tygon tubing that simulated the IVC. The heart of the system was a Harvard Apparatus large animal pulsatile blood pump (Holliston, Mass.) that simulated the ventricular action of the heart. The Harvard Apparatus blood pump was operated near continuously for 22 weeks (913K L pumped) with minor preventative maintenance.
The heart rate was adjusted to 60 bpm, stroke volume between 60 and 70 ml, systolic/diastolic duration ratio 35%/65%, and systolic blood pressure varied from 120 mmHg (simulated conditions for an arterial filter to prevent cerebral and systemic embolism) to 5 mmHg (simulated conditions for an IVC filter to prevent PE).
Real time measurements were available from the upstream and downstream sensor manifolds. The sensors upstream from the absorbable filters under test included digital temperature, flow rate (L/min), total flow (L), and pressure (mmHg). Downstream instrumentation included real time measurement of % oxygen, total dissolved solids (TDS in ppt), and pH. TDS monitoring was included to evaluate the absorption by-products less than 20 microns in size, while the downstream 80 micron in-line filter would catch fragments of suture from the filters and test cells.
The 4 candidate absorbable vascular filters introduced in
Absorption and tensile properties of the selected polymers were determined as a function of time until compete strength degradation in both the circulation system and control bath. The phosphate buffer in the circulation system was changed weekly as the pH decreased from 7.4 to an average 6.6 during each week. Buffer was changed in the control bath only monthly due to better pH stability in the static environment. Mean flow was 4.7 L/min while oxygen averaged 30% and TDS 8.8 ppt.
The phased or sequential absorption of the webbed absorbable filter design is illustrated in the collage of
Perhaps the paramount characteristic under consideration for use in an absorbable vascular filter is the strength retention profile of the absorbable polymers as depicted in
The proposed filter designs employ multiple strands serving as capture elements, hence the emboli load is distributed across N strands. Therefore assuming equal distribution, the net emboli load that can be accommodated by the filter is a multiple, N, of the per strand load at break. Consequently, a polydioxanone size 2-0 filter with 8 capture elements secured at the circumferential support would accommodate a net emboli load of 32 kg.
An alternative method for accessing strength retention for the polymers is to chart the percentage strength retention as a function of time as shown in
Young's modulus of elasticity ranged from 1.0-2.3 GPa for polydioxanone as shown in
In conclusion from the in-vitro absorbable filter study, polydioxanone appears to be a strong candidate for absorbable vascular filters with sufficient strength retention to capture emboli for at least 6 weeks, then absorb rapidly over the next 16 weeks via hydrolysis into carbon dioxide and water. Specifically polydioxanone size 2-0 was shown to conservatively maintain 4 kg load at break per strand throughout 5 weeks in circulation. Hence a filter incorporating 8 capture elements would trap an embolus load of 32 kg; or equivalently, an embolism would have to deliver 1600 kgmm of energy to break through the filter which is highly unlikely given that the pressure in the IVC is a mere 5 mmHg (about 0.1 psi). Moreover, the webbed filter geometry with varied diameter capture elements and expiration dates was shown to disintegrate in a sequential or phased manner, releasing 1 or 2 small brittle filter fragments (less than 5 mm×0.3 mm each) weekly in circulation from weeks 14 through 22. Together with polydioxanone being FDA-approved and proven to be nonallergenic and nonpyrogenic, a catheter-deployed polydioxanone absorbable vascular filter would likely be an efficient and effective device for the prevention of pulmonary embolism.
A preferred installation of the absorbable vascular filter is via intravenous insertion with a catheter requiring only a local anesthetic as illustrated in
An alternative embodiment of the absorbable vascular filter 1 is portrayed in
The integrated absorbable vascular filter shown in
For illustration, a simple cylindrical braided weave (L=7, P=4) is shown in
The algorithm can be visualized by a table as shown in Table 1 to indicate the relationship between L, P and the angle φ for any desired number of circumferential loops (L).
L/P represents the fractional number of sinusoids traversed per circumference, and N represents the total number of turns around the circumference of the cylinder. Essentially the weave creates sinusoids that are out of phase by a fixed increment until the final loop is achieved for which the final sinusoid is desired to be in-phase with the initial sinusoid. The in-phase condition requires the product N×(L/P) to be an integer. Moreover, to ensure all pins are looped, the first integer to be formed by the product N×(L/P) must occur where N=P.
For example with L=7 and P=4, the first integer that appears in the row corresponding to P=4 of Table 1 is where N=4 so this combination of L, P, and N will provide a successful braid wherein all pins will be utilized (7 across the top, 7 across the bottom) and the final weave will terminate at the origin. It can be demonstrated that L must be an odd integer for a successful braid. It can further be shown that the angle φ can be expressed as φ=2 tan−1(Pπr/L1) where r and l is the radius and length of the desired filter circumferential support 102. The values for r and l used for calculating φ in Table 1 were 0.625 and 1.5 inches respectively. Also τ is easily computed from the relationship Lτ=2πr or τ=2πr/L.
Although only a set of 7 looping pins were considered for simplicity in the above illustrations, a more likely number useful for an absorbable vascular filter for the IVC may well be 17 or 19 with φ>100°. Specifically, an absorbable IVC filter with integrated circumferential support and capture basket was fabricated with a single 10 ft synthetic filament (0.5 mm diameter) as shown in
Although the present invention has been described with reference to specific exemplary embodiments, it will be evident to one of ordinary skill in the art that various modifications and changes may be made to these embodiments without departing from the broader spirit and scope of the invention. Accordingly, the specification and drawings are to be regarded in an illustrative rather than a restrictive sense.
This application is a continuation-in-part application of U.S. patent application Ser. No. 13/036,351, filed Feb. 28, 2011, and is a continuation-in-part application of U.S. patent application Ser. No. 13/096,049, filed Apr. 28, 2011, all of which applications are expressly incorporated herein by reference in their entirety.
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Number | Date | Country | |
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20130226222 A1 | Aug 2013 | US |
Number | Date | Country | |
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Parent | 13096049 | Apr 2011 | US |
Child | 13403790 | US | |
Parent | 13036351 | Feb 2011 | US |
Child | 13096049 | US |