Source: http://www.google.com/patents/US20040059187?dq=6,757,682
Timestamp: 2016-06-30 05:22:51
Document Index: 303020032

Matched Legal Cases: ['art 11', 'art 11', 'art 11', 'art 41', 'art 44', 'art 51', 'art 41', 'art 41', 'art 56', 'art 72', 'art 72']

Patent US20040059187 - Cardiac reinforcement device - Google PatentsSearch Images Maps Play YouTube News Gmail Drive More »Sign inPatentsThe present disclosure is directed to a cardiac reinforcement device (CRD) and method for the treatment of cardiomyopathy. The CRD provides for reinforcement of the walls of the heart by constraining cardiac expansion, beyond a predetermined limit, during diastolic expansion of the heart. A CRD of the...http://www.google.com/patents/US20040059187?utm_source=gb-gplus-sharePatent US20040059187 - Cardiac reinforcement deviceAdvanced Patent SearchPublication numberUS20040059187 A1Publication typeApplicationApplication numberUS 10/668,460Publication dateMar 25, 2004Filing dateSep 23, 2003Priority dateOct 2, 1996Also published asCA2267104A1, CA2267104C, CA2451964A1, DE29724206U1, DE69731890D1, DE69731890T2, EP0930856A1, EP0930856B1, US5702343, US6077218, US6126590, US6165121, US6165122, US6375608, US6544168, US6893392, US7163507, US7166071, US7255674, US7261684, US7278964, US7351200, US20020091296, US20030149333, US20040059181, US20040059182, US20040059188, US20040059189, US20040171909, US20040181124, US20070225547, WO1998014136A1Publication number10668460, 668460, US 2004/0059187 A1, US 2004/059187 A1, US 20040059187 A1, US 20040059187A1, US 2004059187 A1, US 2004059187A1, US-A1-20040059187, US-A1-2004059187, US2004/0059187A1, US2004/059187A1, US20040059187 A1, US20040059187A1, US2004059187 A1, US2004059187A1InventorsClifton AlfernessOriginal AssigneeAcorn Cardiovascular, Inc.Export CitationBiBTeX, EndNote, RefManPatent Citations (14), Referenced by (32), Classifications (12), Legal Events (7) External Links: USPTO, USPTO Assignment, EspacenetCardiac reinforcement device
US 20040059187 A1Abstract
BRIEF DESCRIPTION OF THE DRAWINGS [0011] [0011]FIG. 1 is a frontal view of one embodiment of a cardiac reinforcement patch. [0012] [0012]FIG. 2 is a perspective view of the cardiac reinforcement patch of FIG. 1 in place on the epicardium of a heart. [0013] [0013]FIG. 3 is a perspective view of one embodiment of a cardiac reinforcement jacket according to the invention. [0014] [0014]FIG. 4 is a second embodiment of a cardiac reinforcement jacket according to the invention. [0015] [0015]FIG. 5 is a perspective view of the embodiment of the cardiac reinforcement jacket shown in FIG. 3 in place around the heart. [0016] [0016]FIG. 6 is a schematic cross sectional view of one embodiment of a mechanism for selectively adjusting the predetermined size of a cardiac reinforcement jacket. [0017] [0017]FIG. 7 is a perspective view of a placement tool which can be used for applying a cardiac reinforcement jacket. [0018] [0018]FIG. 8 is a perspective view of a placement tool being employed to place a cardiac reinforcement jacket over the heart. DETAILED DESCRIPTION [0019] The present invention is directed to reinforcement of the heart wall during diastolic filling of a chamber of the heart. The invention is particularly suited for use in cardiomyopathies where abnormal dilation of one or more chambers of the heart is a component of the disease. [0020] As used herein, “cardiac chamber” refers to the left or right atrium or the left or right ventricle. The term “myocardium” refers to the cardiac muscle comprising the contractile walls of the heart. The term “endocardial surface” refers to the inner walls of the heart. The term “epicardial surface” refers to the outer walls of the heart. [0021] The heart is enclosed within a double walled sac known as the pericardium. The inner layer of the pericardial sac is the visceral pericardium or epicardium. The outer layer of the pericardial sac is the parietal pericardium. [0022] According to the present invention, a cardiac reinforcement device (CRD) limits the outward expansion of the heart wall during diastolic chamber filling beyond a predetermined size. The expansion constraint applied to the heart by a CRD is predetermined by the physician based on, for example, cardiac output performance or cardiac volume. In contrast to known ventricular assist devices which provide cardiac assistance during systole, a CRD according to the present disclosure provides cardiac reinforcement during diastole. [0023] A CRD is made from a biomedical material which can be applied to the epicardial surface of the heart. As used herein, a “biomedical material” is a material which is physiologically inert to avoid rejection or other negative inflammatory response. A CRD can be prepared from an elastic or substantially non-elastic biomedical material. The biomedical material can be inflexible, but is preferably sufficiently flexible to move with the expansion and contraction of the heart without impairing systolic function. The biomedical material should, however, constrain cardiac expansion, during diastolic filling of the heart, to a predetermined size. Examples of suitable biomedical materials include perforate and non-perforate materials. Perforate materials include, for example, a mesh such as a polypropylene or polyester mesh. Non-perforate materials include, for example, silicone rubber. [0024] A biomedical material suitable for a device of the invention generally has a lower compliance than the heart wall. Even though the biomedical material is less compliant than the heart wall, some limited expansion of an elastic biomedical material can occur during cardiac filling. [0025] In an alternative embodiment, the biomedical material can be substantially non-elastic. According to this embodiment, the term “substantially non-elastic” refers to a material which constrains cardiac expansion during diastole at a predetermined size, but which has substantially no elastic properties. [0026] Regardless if the biomedical material is elastic or non-elastic, advantageous to a CRD according to the present disclosure is cardiac reinforcement which is provided during diastole. Moreover, a CRD as disclosed herein does not provide cardiac assistance through active pumping of the heart. [0027] I. CRD Patch [0028] In one embodiment, a cardiac reinforcement device (CRD) provides for local constraint of the heart wall during cardiac expansion. According to this embodiment, a CRD is a “patch” that provides reinforcement of the heart wall at a localized area, such as a cardiac aneurysm or at an area of the myocardium which has been damaged due to myocardial infarction. When discussing a “patch”, “predetermined size” of the patch means that the size of the patch is selected to cover an area of the epicardial surface of the heart in need of reinforcement without completely surrounding the circumference of the heart. [0029] A CRD patch can be prepared from the biomedical materials described above. In a preferred embodiment, the patch is an open mesh material. [0030] A CRD patch can be applied to the epicardial surface of the heart over or under the parietal pericardium. A patch is typically applied to the epicardial surface by suturing around the periphery of the patch. The peripheral edge of the patch can include a thickened “ring” or other reinforcement to enhance the strength of the patch at the point of suture attachment to the epicardium. Generally, a patch is applied to the epicardium through a thoracotomy or other incision providing sufficient exposure of the heart. [0031] II. CRD Jacket [0032] In another embodiment, a CRD is a jacket that circumferentially surrounds the epicardial surface of the heart. When applied to the heart, a CRD jacket can be placed over or under the parietal pericardium. [0033] A CRD applied to the epicardium is fitted to a “predetermined size” for limitation of cardiac expansion. According to a jacket embodiment, “predetermined size” refers to the predetermined expansion limit of the jacket which circumferentially constrains cardiac expansion during diastolic filling of the heart. In practice, for example, a physician could measure cardiac output and adjust the jacket size to an optimal size for the desired effect. In this example, the optimal size is the “predetermined size”. In one embodiment, the predetermined size can be adjusted for size reduction as the cardiac size is reduced. [0034] In one embodiment, the CRD jacket is a cone-shaped tube, having a base broader than the apex, which generally conforms to the external geometry of the heart. When applied to the epicardial surface of the heart, the base of the jacket is oriented towards the base of the heart, and the apex of the jacket is oriented towards the apex of the heart. Typically, the base of the jacket includes an opening for applying the jacket by passing the jacket over the epicardial surface of the heart. The apical end of the jacket can be a continuous surface which covers the apex of the heart. Alternatively, the apex of the jacket can have an opening through which the apex of the heart protrudes. [0035] A cardiac reinforcement jacket, as disclosed herein, is not an inflatable device that surrounds the heart. Rather, the device is typically a single layer of biomedical material. In one embodiment discussed below, an inflatable member can be included with the device, but the inflatable member serves to reduce the volume within a localized region of the jacket and does not follow the entire jacket to surround the epicardial surface of the heart. [0036] In one embodiment, the CRD jacket can be secured to the epicardium by a securing arrangement mounted at the base of the jacket. A suitable securing arrangement includes, for example, a circumferential attachment device, such as a cord, suture, band, adhesive or shape memory element which passes around the circumference of the base of the jacket. The ends of the attachment device can be fastened together to secure the jacket in place. Alternatively, the base of the jacket can be reinforced for suturing the base of the jacket to the epicardium. [0037] Various sized CRD jackets can be prepared such that different sized jackets are used for different predetermined cardiac expansion sizes or expansion ranges. Alternatively, a CRD jacket can include a mechanism for selectively adjusting the size of the jacket. A mechanism for selectively adjusting the volumetric size of the jacket theoretically provides for a “one size fits all” device. More importantly, however, an adjustable jacket provides the ability to titrate (readjust) the amount of cardiac reinforcement by graded reduction in jacket size as therapeutic reduction of cardiac expansion occurs. [0038] A mechanism for selectively adjusting the size of the jacket can include a slot which opens at the base of the jacket and extends toward the apex end of the CRD. If the apex end of the CRD jacket is open, the apical extent of the slot can be continuous with the apex opening. The slot includes opposing lateral edges. By adjusting the proximity of the opposing lateral edges, the overall size of the jacket can be varied. Moving the opposing edges of the slot closer together narrows the slot and reduces the volumetric size of the jacket. The opposing edges of the slot can be fastened together at a predetermined proximity by, for example, one or more lateral attachment devices, such as a cord, suture, band, adhesive or shape memory element attached to each lateral edge. [0039] In another embodiment, a mechanism for selectively adjusting the size of the jacket can be an inflatable member. According to this embodiment, the inflatable member is mounted between the jacket and the epicardium. The volumetric size of the jacket can be reduced by inflating the inflatable member through an inflation port with, for example, a gas or liquid. As cardiac expansion volume responds to cardiac constraint by size reduction, the predetermined size of the jacket can then be reduced by inflating the inflatable member within the jacket. Once inflated, the size of the inflatable member is preferably maintained until therapeutic response causes a need for further inflation. According to the invention, the inflation of the inflatable member provides a reduction in the predetermined size of the jacket by a fixed increase in volume of the inflatable member. The inflatable member is not rhythmically inflated and deflated to provide assistance to cardiac contraction during systole. [0040] The biomedical material of the invention can be radioluscent or radiopaque. In one embodiment, the material of the jacket can be made radiopaque by inclusion of radiopaque markers for identification of the outside surface of the heart, the expansion slot or inflation port. As used herein, radiopaque means causing the CRD to be visible on x-ray or fluoroscopic viewing. Suitable radiopaque markers include, for example, platinum wires, titanium wires and stainless steel wires. [0041] A CRD according to the present disclosure provides a new method for the treatment of cardiac disease. As used herein, cardiac disease includes diseases in which dilation of one of the chambers of the heart is a component of the disease. Examples include heart failure or cardiomyopathy. Heart failure can occur as a result of cardiac dilation due to ventricular hypertrophy or secondary to, for example, valvular incompetency, valvular insufficiency or valvular stenosis. Cardiomyopathy, according to the invention, can be primary or secondary to infection, ischemia, metabolic disease, genetic disorders, etc. [0042] It is foreseen that constraint of cardiac expansion by a device of the invention can provide reduced cardiac dilation. Reduced cardiac dilation can cause reduction in the problems associated with cardiac dilation such as arrhythmias and valvular leakage. As reduction of cardiac dilation occurs, selective reduction of the predetermined size of the jacket also provides continued reinforcement for the size reduced heart. [0043] A CRD jacket can also be used to measure cardiac performance. According to this embodiment, the CRD jacket is rendered radiopaque by use of a radiographic marker. The radiographic markers are distributed throughout the jacket over the surface of the heart. By evaluation of the markers relative to one another with each heart beat, cardiac performance may be measured. As such, evaluation of cardiac performance may assist in adjusting the predetermined size of a CRD jacket. [0044] A CRD as described herein can be applied to the epicardium of a heart through a thoracotomy or through a minimally invasive procedure. For a minimally invasive procedure a CRD placement tool can be used to apply the CRD over the epicardium of the heart through a thorascopic incision. According to this embodiment, a CRD placement tool includes a cannula, a stiff rod or wire and a guide tube. For placement of a CRD, the wire is threaded through the guide tube which is passed around the circumference of the base of the jacket. The CRD with wire and guide tube passed through the base opening are then passed into the cannula. The cannula is of sufficient length and diameter to enclose the CRD, wire and guide tube during passage of the placement tool through a thorascopic incision. The placement tool is passed into the thoracic cavity and positioned at a point near the apex of the heart. When in position, the wire and guide tube are pushed out of the cannula away from the operator. Once outside the cannula, the wire and guide tube sufficiently expand the opening of the base of the CRD jacket to pass over the epicardial surface of the heart. When the CRD jacket is in position over the epicardial surface, the wire, guide tube and cannula can be removed. A second incision can then be made to provide access for suitable surgical instruments to secure or adjust the size of the CRD. [0045] The invention will now be further described by reference to the drawings. [0046] [0046]FIG. 1 is a frontal view of one embodiment of a cardiac reinforcement patch 1. The CRD patch 1 shown here is a mesh biomedical material 2 having a thickened peripheral ring 3 which reinforces the peripheral edge 4 of the patch for attachment of the patch to the epicardial surface of the heart. [0047] [0047]FIG. 2. is a perspective view of a CRD patch 10 in place on the epicardial surface of a heart 11, for example, over a cardiac aneurysm (not shown) of the heart. In one preferred embodiment, the patch 10 is sized to cover the extent of the cardiac aneurysm and is placed on the epicardial surface of the heart 11. In practice, the thorax is surgically opened and the region of the heart 11 with the aneurysm (not shown) is located and exposed. The patch 10 is placed over the aneurysm and sutured in place around the periphery 12 of the patch to provide sufficient constraint to prevent further dilation of the aneurysm. [0048] [0048]FIG. 3 is a perspective view of one embodiment of a CRD jacket 15 according to the invention. According to the embodiment shown, the jacket 15 is a mesh material 16, and includes a circumferential attachment device 17 at the base end 18 of the CRD jacket. The apex end 24 of the jacket 15 is closed. The jacket 15 shown also includes a slot 19 having opposing lateral edges 20 and 21, and fasteners (e.g. lateral attachment device 22 and 23) for selectively adjusting the volumetric size of the jacket 15. The CRD jacket 15 shown also includes radiopaque markers 25 for visualizing the surface of the heart through radiographic study. [0049] [0049]FIG. 4 is an alternative embodiment of a CRD jacket 30. Similar to the embodiment shown in FIG. 3, the embodiment of FIG. 4 includes a base end 31 and an apex 32 end. The base end includes a circumferential attachment device 33 for securing the CRD jacket 30 to the heart. The CRD jacket 30 of FIG. 4 also includes a slot 34 having opposing lateral edges 35, 36. The lateral edges 35, 36 are shown pulled together at 37 by a lateral attachment device 38, for example, a suture. In contrast to the embodiment shown in FIG. 3, the embodiment shown in FIG. 4 has an opening 39 at the apex end 32 of the CRD jacket 30. [0050] [0050]FIG. 5. is a perspective view of a CRD jacket 40 around a heart 41. According to the embodiment shown, at the base 42 of the jacket 40, there is a circumferential attachment device 43 which secures the CRD jacket 40 near the base of the heart 44. A slot 45, is shown with opposing lateral edges 46, 47 fastened together by a lateral attachment device 48. In the embodiment shown, the CRD jacket 40 has an opening 49 at the apical end 50 of the jacket. The apex of the heart 51 protrudes through the opening 49 at the apical end 50 of the jacket 40. [0051] Still referring to FIG. 5, in a preferred embodiment, if one or more of the lateral attachment device 48 are made of an elastic material, such as silicone rubber, the device can provide a way of applying a graded constraint around the outside of the heart 41 to reduce cardiac dilation over time. In practice, the jacket would be placed over the heart 41 as shown, either over or under the parietal pericardium (not shown). The circumferential attachment device 43 and lateral attachment device 48 would then be tightened to cause a constraining effect on the outside of the heart. [0052] In a preferred embodiment, if one or more of the lateral attachment cords 48 is made of an elastic material, such as silicone rubber, surface pressure exerted on the epicardial surface of the heart varies as a function of the amount of dilation of the heart. This variable pressure has the effect of reducing the cardiac dilation to a certain point and then stopping because the surface pressure drops to a negligible amount. The amount of constraint or reduction in dilation that is accomplished over time and the resultant cardiac performance may be monitored radiographically using techniques known in the art, for example fluoroscopy, by observing radiographic markers (FIG. 4, 25), if present. [0053] [0053]FIG. 6 is a schematic cross sectional view of an alternative embodiment of an arrangement for selectively adjusting the predetermined size of a jacket 53. According to this embodiment, an inflatable member 54 is inserted within the jacket 53 between the jacket 53 and the epicardial surface 55 of the heart 56. The inflatable member 54 includes a filling apparatus 57 for entry of a fluid (liquid or gas) to inflate the inflatable member 54 and reduce the predetermined size of the jacket 53. [0054] [0054]FIG. 7 is a perspective view of a placement tool 60 which can be used for placement of a CRD jacket 61 around the epicardium of the heart. As shown here, the base end of the jacket 62 is held open by guide tube 63 through which is passed a wire or stiffening rod 64. The wire 64 can be removed from the guide tube 63 by pulling on the wire extraction grip 66. The placement tool 60 includes a cannula 65 which encloses the jacket 61, guide tube 63 and wire 64 during insertion of the tool into a thorascopic incision. [0055] [0055]FIG. 8 is a perspective view of a placement tool 70 being employed to place a jacket 71 over the heart 72 on the outside of the parietal pericardium 73. The placement tool 70 is guided through a small incision in the thorax and the jacket 71 is maneuvered into position over the heart 72. Once the jacket 71 is in proper position, the wire 74, which is passed through the guide tube 75 around the base 76 of the jacket 71, is extracted from the guide tube 75 by pulling on the wire extraction grip 77. The guide tube 75 is then extracted by pulling on the guide tube extraction grip 78. The cannula 79 is removed from the chest and the circumferential attachment cord (not shown in this view), and the lateral attachment cord 80 can be fastened to secure the jacket 71. [0056] The above specification and drawings provide a description of a cardiac reinforcement device and method of using on the heart. Since many embodiments of the invention can be made without departing from the spirit and scope of the invention, the invention resides in the claims hereinafter appended. Patent CitationsCited PatentFiling datePublication dateApplicantTitleUS393863 *Aug 20, 1888Dec 4, 1888 SleighUS4048990 *Sep 17, 1976Sep 20, 1977Goetz Robert HHeart massage apparatusUS4403604 *May 13, 1982Sep 13, 1983Wilkinson Lawrence HGastric pouchUS4428375 *Feb 16, 1982Jan 31, 1984Ellman Barry RSurgical bag for splenorrhaphyUS4630597 *Apr 30, 1984Dec 23, 1986Adrian KantrowitzDynamic aortic patch for thoracic or abdominal implantationUS4690134 *Jul 1, 1985Sep 1, 1987Snyders Robert VVentricular assist deviceUS4821773 *Mar 7, 1988Apr 18, 1989Herion-Werke KgDirectional control valveUS4834707 *Sep 16, 1987May 30, 1989Evans Phillip HVenting apparatus and method for cardiovascular pumping applicationUS4878890 *Oct 13, 1987Nov 7, 1989Ethicon, Inc.Perihepatic prosthesisUS4936857 *Feb 15, 1988Jun 26, 1990Kulik Yaroslav PProsthetic pericardiumUS4957477 *May 9, 1989Sep 18, 1990Astra Tech AbHeart assist jacket and method of using itUS4973300 *Sep 22, 1989Nov 27, 1990Pioneering Technologies, Inc.Cardiac sling for circumflex coronary artery surgeryUS4976730 *Oct 11, 1988Dec 11, 1990Kwan Gett Clifford SArtificial pericardiumUS6508756 *Dec 30, 1998Jan 21, 2003Abiomed, Inc.Passive cardiac assistance device* Cited by examinerReferenced byCiting PatentFiling datePublication dateApplicantTitleUS7666224Jul 7, 2005Feb 23, 2010Edwards Lifesciences LlcDevices and methods for heart valve treatmentUS7678145Jul 1, 2005Mar 16, 2010Edwards Lifesciences LlcDevices and methods for heart valve treatmentUS7695425Feb 17, 2004Apr 13, 2010Edwards Lifesciences LlcHeart wall tension reduction apparatus and methodUS7722523Jul 9, 2002May 25, 2010Edwards Lifesciences LlcTransventricular implant tools and devicesUS7766812Apr 14, 2006Aug 3, 2010Edwards Lifesciences LlcMethods and devices for improving mitral valve functionUS7883539Apr 23, 2002Feb 8, 2011Edwards Lifesciences LlcHeart wall tension reduction apparatus and methodUS7981020Jun 5, 2008Jul 19, 2011Edwards Lifesciences LlcTransventricular implant tools and devicesUS8070805Jan 25, 2010Dec 6, 2011Edwards Lifesciences LlcDevices and methods for heart valve treatmentUS8092367Jan 10, 2012Mardil, Inc.Method for external stabilization of the base of the heartUS8128553Dec 12, 2006Mar 6, 2012Mardil, Inc.Method and apparatus for external stabilization of the heartUS8187323May 29, 2012Edwards Lifesciences, LlcValve to myocardium tension members device and methodUS8226711Jul 24, 2012Edwards Lifesciences, LlcValve to myocardium tension members device and methodUS8267852Jul 8, 2010Sep 18, 2012Edwards Lifesciences, LlcHeart wall tension reduction apparatus and methodUS8439817May 14, 2013Edwards Lifesciences, LlcChordae capturing methods for stress reductionUS8460173Jun 11, 2013Edwards Lifesciences, LlcHeart wall tension reduction apparatus and methodUS8506624Dec 2, 2011Aug 13, 2013Edwards Lifesciences, LlcDevices and methods for heart valve treatmentUS8579798Jun 5, 2008Nov 12, 2013Edwards Lifesciences, LlcExternal cardiac stress reduction methodUS9198757Jul 7, 2009Dec 1, 2015Edwards Lifesciences, LlcMethods and devices for improving mitral valve functionUS20020029080 *Oct 19, 2001Mar 7, 2002Myocor, Inc.Valve to myocardium tension members device and methodUS20020077524 *Feb 14, 2002Jun 20, 2002Myocor, Inc.Heart wall tension reduction apparatusUS20020169359 *May 2, 2002Nov 14, 2002Myocor, Inc.Methods and devices for improving cardiac function in heartsUS20020173694 *May 6, 2002Nov 21, 2002Myocor, Inc.Stress reduction apparatus and methodUS20030032979 *Jul 9, 2002Feb 13, 2003Myocor, Inc.Transventricular implant tools and devicesUS20040167374 *Feb 17, 2004Aug 26, 2004Myocor, Inc.Heart wall tension reduction apparatus and methodUS20050065396 *Jul 27, 2004Mar 24, 2005Myocor, Inc.External stress reduction device and methodUS20050148815 *Jan 28, 2005Jul 7, 2005Myocor, Inc.Transventricular implant tools and devicesUS20070129598 *Dec 12, 2006Jun 7, 2007Raman JaishankerMethod and apparatus for external stabilization of the heartUS20080091057 *Oct 11, 2006Apr 17, 2008Cardiac Pacemakers, Inc.Method and apparatus for passive left atrial supportUS20080215074 *May 16, 2008Sep 4, 2008Raman JaishankarMethod and apparatus for external stabilization of the heartUS20080319256 *Jun 5, 2008Dec 25, 2008Myocor, Inc.Transventricular implant tools and devicesUS20090137863 *Dec 2, 2008May 28, 2009Myocor, Inc.Heart wall tension reduction apparatusUS20090270980 *Jul 7, 2009Oct 29, 2009Edwards Lifesciences LlcMethods and Devices for Improving Mitral Valve Function* Cited by examinerClassifications U.S. Classification600/37International ClassificationA61F2/24, A61F2/00, A61M1/10, A61F2/02, A61B19/00Cooperative ClassificationA61M1/1068, A61F2/2481, A61F2002/2484, A61F2250/0003European ClassificationA61F2/24W2, A61M1/10E50BLegal EventsDateCodeEventDescriptionNov 20, 2006ASAssignmentOwner name: ACORN MEDICAL, INC., MINNESOTAFree format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:ALFERNESS, CLIFTON A.;REEL/FRAME:018539/0052Effective date: 19961129Owner name: ACORN CARDIOVASCULAR, INC., MINNESOTAFree format text: CHANGE OF NAME;ASSIGNOR:ACORN MEDICAL, INC.;REEL/FRAME:018539/0220Effective date: 19980206Jul 13, 2010FPAYFee paymentYear of fee payment: 4Jul 7, 2011ASAssignmentOwner name: MARDIL, INC., MINNESOTAFree format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:ACORN CARDIOVASCULAR, INC.;REEL/FRAME:026558/0507Effective date: 20101210Jul 19, 2011ASAssignmentOwner name: MARDIL, INC., MINNESOTAFree format text: CORRECTIVE ASSIGNMENT TO CORRECT THE ASSIGNMENT DOCUMENT A COPY OF WHICH WAS INCOMPLETE WHEN SUBMITTED PREVIOUSLY RECORDED ON REEL 026558 FRAME 0507. ASSIGNOR(S) HEREBY CONFIRMS THE COMPLETENESS OF THE ATTACHED ASSIGNMENT DOCUMENT;ASSIGNOR:ACORN CARDIOVASCULAR, INC.;REEL/FRAME:026616/0655Effective date: 20101210Aug 29, 2014REMIMaintenance fee reminder mailedJan 16, 2015LAPSLapse for failure to pay maintenance feesMar 10, 2015FPExpired due to failure to pay maintenance feeEffective date: 20150116RotateOriginal ImageGoogle Home - Sitemap - USPTO Bulk Downloads - Privacy Policy - Terms of Service - About Google Patents - Send FeedbackData provided by IFI CLAIMS Patent Services