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Artificial heart valve

January 01, 1970

An artificial heart valve is a one-way valve implanted into a person's heart to replace a heart valve that is not functioning properly (valvular heart disease). Artificial heart valves can be separated into three broad classes: mechanical heart valves, bioprosthetic tissue valves and engineered tissue valves.

Artificial heart valve
Different types of artificial heart valves[1]
Specialtycardiology
[edit on Wikidata]

The human heart contains four valves: tricuspid valve, pulmonary valve, mitral valve and aortic valve. Their main purpose is to keep blood flowing in the proper direction through the heart, and from the heart into the major blood vessels connected to it (the pulmonary artery and the aorta). Heart valves can malfunction for a variety of reasons, which can impede the flow of blood through the valve (stenosis) and/or let blood flow backwards through the valve (regurgitation). Both processes put strain on the heart and may lead to serious problems, including heart failure. While some dysfunctional valves can be treated with drugs or repaired, others need to be replaced with an artificial valve.[2]

Background edit

 
3D Medical Animation still shot of Artificial Heart Valve

A heart contains four valves (tricuspid, pulmonary, mitral and aortic valves) which open and close as blood passes through the heart.[3] Blood enters the heart in the right atrium and passes through the tricuspid valve to the right ventricle. From there, blood is pumped through the pulmonary valve to enter the lungs. After being oxygenated, blood passes to the left atrium, where is it pumped through the mitral valve to the left ventricle. The left ventricle pumps blood to the aorta through the aortic valve.

There are many potential causes of heart valve damage, such as birth defects, age related changes, and effects from other disorders, such as rheumatic fever and infections causing endocarditis. High blood pressure and heart failure which can enlarge the heart and arteries, and scar tissue can form after a heart attack or injury.[4]

The three main types of artificial heart valves are mechanical, biological (bioprosthetic/tissue), and tissue-engineered valves. In the US, UK and the European Union, the most common type of artificial heart valve is the bioprosthetic valve. Mechanical valves are more commonly used in Asia and Latin America.[citation needed] Companies that manufacture heart valves include Edwards Lifesciences,[5] Medtronic,[6] Abbott (St. Jude Medical),[7] CryoLife,[8] and LifeNet Health.[9]

Mechanical valves edit

Mechanical valves come in three main types – caged ball, tilting-disc and bileaflet – with various modifications on these designs.[10] Caged ball valves are no longer implanted.[11] Bileaflet valves are the most common type of mechanical valve implanted in patients today.[12]

Caged ball valves edit

 
Caged ball valve

The first artificial heart valve was the caged ball valve, a type of ball check valve, in which a ball is housed inside a cage. When the heart contracts and the blood pressure in the chamber of the heart exceeds the pressure on the outside of the chamber, the ball is pushed against the cage and allows blood to flow. When the heart finishes contracting, the pressure inside the chamber drops and the ball moves back against the base of the valve forming a seal.

In 1952, Charles A. Hufnagel implanted caged ball heart valves into ten patients (six of whom survived the operation), marking the first success in prosthetic heart valves.[citation needed] A similar valve was invented by Miles 'Lowell' Edwards and Albert Starr in 1960, commonly referred to as the Starr-Edwards silastic ball valve.[13] This consisted of a silicone ball enclosed in a methyl metacrylate cage welded to a ring. The Starr-Edwards valve was first implanted in a human on August 25, 1960, and was discontinued by Edwards Lifesciences in 2007.[13]

Caged ball valves are strongly associated with blood clot formation, so people who have one required a high degree of anticoagulation, usually with a target INR of 3.0–4.5.[14]

Tilting-disc valves edit

 
tilting-disc valve

Introduced in 1969, the first clinically available tilting-disc valve was the Bjork-Shiley valve.[15] Tilting‑disc valves, a type of swing check valve, are made of a metal ring covered by an ePTFE fabric. The metal ring holds, by means of two metal supports, a disc that opens when the heart beats to let blood flow through, then closes again to prevent blood flowing backwards. The disc is usually made of an extremely hard carbon material (pyrolytic carbon), enabling the valve to function for years without wearing out.[citation needed]

Bileaflet valves edit

 
Bileaflet valve

Introduced in 1979, bileaflet valves are made of two semicircular leaflets that revolve around struts attached to the valve housing. With a larger opening than caged ball or tilting-disc valves, they carry a lower risk of blood clots. They are, however, vulnerable to blood backflow.[citation needed]

Advantages of mechanical valves edit

The major advantage of mechanical valves over bioprosthetic valves is their greater durability.[16] Made from metal and/or pyrolytic carbon,[10] they can last 20–30 years.[16]

Disadvantages of mechanical valves edit

One of the major drawbacks of mechanical heart valves is that they are associated with an increased risk of blood clots. Clots formed by red blood cell and platelet damage can block blood vessels leading to stroke. People with mechanical valves need to take anticoagulants (blood thinners), such as warfarin, for the rest of their life.[16] Mechanical heart valves can also cause mechanical hemolytic anemia, a condition where the red blood cells are damaged as they pass through the valve.[citation needed] Cavitation, the rapid formation of microbubbles in a fluid such as blood due to a localized drop of pressure, can lead to mechanical heart valve failure,[17] so cavitation testing is an essential part of the valve design verification process.

Many of the complications associated with mechanical heart valves can be explained through fluid mechanics. For example, blood clot formation is a side effect of high shear stresses created by the design of the valves. From an engineering perspective, an ideal heart valve would produce minimal pressure drops, have small regurgitation volumes, minimize turbulence, reduce prevalence of high stresses, and not create flow separations in the vicinity of the valve.[citation needed]

Implanted mechanical valves can cause foreign body rejection. The blood may coagulate and eventually result in a hemostasis. The usage of anticoagulation drugs will be interminable to prevent thrombosis.[18][non-primary source needed]

Bioprosthetic tissue valves edit

Bioprosthetic valves are usually made from animal tissue (heterograft/xenograft) attached to a metal or polymer support.[11] Bovine (cow) tissue is most commonly used, but some are made from porcine (pig) tissue.[19][non-primary source needed] The tissue is treated to prevent rejection and calcification.[citation needed]

Alternatives to animal tissue valves are sometimes used, where valves are used from human donors, as in aortic homografts and pulmonary autografts. An aortic homograft is an aortic valve from a human donor, retrieved either after their death or from a heart that is removed to be replaced during a heart transplant.[12] A pulmonary autograft, also known as the Ross procedure, is where the aortic valve is removed and replaced with the patient's own pulmonary valve (the valve between the right ventricle and the pulmonary artery). A pulmonary homograft (a pulmonary valve taken from a cadaver) is then used to replace the patient's own pulmonary valve. This procedure was first performed in 1967 and is used primarily in children, as it allows the patient's own pulmonary valve (now in the aortic position) to grow with the child.[12]

Advantages of bioprosthetic heart valves edit

Bioprosthetic valves are less likely than mechanical valves to cause blood clots, so do not require lifelong anticoagulation. As a result, people with bioprosthetic valves have a lower risk of bleeding than those with mechanical valves.[16]

Disadvantages of bioprosthetic heart valves edit

Tissue valves are less durable than mechanical valves, typically lasting 10–20 years.[20] This means that people with bioprosthetic valves have a higher incidence of requiring another aortic valve replacement in their lifetime.[16] Bioprosthetic valves tend to deteriorate more quickly in younger patients.[21]

In recent years, scientists have developed a new tissue preservation technology, with the aim of improving the durability of bioprosthetic valves. In sheep and rabbit studies, tissue preserved using this new technology had less calcification than control tissue.[22] A valve containing this tissue is now marketed, but long-term durability data in patients are not yet available.[23][non-primary source needed]

Current bioprosthetic valves lack longevity, and will calcify over time.[24] When a valve calcifies, the valve cusps become stiff and thick and cannot close completely.[24] Moreover, bioprosthetic valves can't grow with or adapt to the patient: if a child has bioprosthetic valves they will need to get the valves replaced several times to fit their physical growth.[24]

Tissue-engineered valves edit

For over 30 years researchers have been trying to grow heart valves in vitro.[25] These tissue‑engineered valves involve seeding human cells on to a scaffold.[25] The two main types of scaffold are natural scaffolds, such as decellularized tissue, or scaffolds made from degradable polymers.[26] The scaffold acts as an extracellular matrix, guiding tissue growth into the correct 3D structure of the heart valve.[26][25] Some tissue-engineered heart valves have been tested in clinical trials,[26] but none are commercially available.

Tissue engineered heart valves can be person-specific and 3D modeled to fit an individual recipient[27] 3D printing is used because of its high accuracy and precision of dealing with different biomaterials.[27] Cells that are used for tissue engineered heart valves are expected to secrete the extracellular matrix (ECM).[24] Extracellular matrix provides support to maintain the shape of the valves and determines the cell activities.[28]

Scientists can follow the structure of heart valves to produce something that looks similar to them, but since tissue engineered valves lack the natural cellular basis, they either fail to perform their functions like natural heart valves, or function when they are implanted but gradually degrade over time.[citation needed] An ideal tissue engineered heart valve would be non‐thrombogenic, biocompatible, durable, resistant to calcification, grow with the surrounding heart, and exhibit a physiological hemodynamic profile.[29] To achieve these goals, the scaffold should be carefully chosen—there are three main candidates: decellularized ECM (xenografts or homografts), natural polymers, and synthetic polymers.[29]

Differences between mechanical and tissue valves edit

Mechanical and tissue valves are made of different materials. Mechanical valves are generally made of titanium and carbon.[30] Tissue valves are made up of human or animal tissue. The valves composed of human tissue, known as allografts or homografts, are from donors' human hearts.[30]

Mechanical valves can be a better choice for younger people and people at risk of valve deterioration due to its durability. It is also preferable for people who are already taking blood thinners and people who would be unlikely to tolerate another valve replacement operation.[citation needed]

Tissue valves are better for older age groups as another valve replacement operation may not be needed in their lifetime. Due to the risk of forming blood clots for mechanical valves and severe bleeding as a major side effect of taking blood-thinning medications, people who have a risk of blood bleeding and are not willing to take warfarin may also consider tissue valves. Other patients who may be more suitable for tissue valves are people who have other planned surgeries and unable to take blood-thinning medications. People who plan to become pregnant may also consider tissue valves as warfarin causes risks in pregnancy.[citation needed]

Functional requirements of artificial heart valves edit

An artificial heart valve should ideally function like a natural heart valve.[11] The functioning of natural heart valves is characterized by many advantages:

  • Minimal regurgitation – This means that the amount of blood leaking backwards through the valve as it closes is small. Some degree of valvular regurgitation is inevitable and natural, up to around 5 ml per beat.[31] However, several heart valve pathologies (e.g. rheumatic endocarditis) may lead to clinically significant valvular regurgitation. A desirable characteristic of heart valve prostheses is that regurgitation is minimal over the full range of physiological heart function.
  • Minimal transvalvular pressure gradient – Whenever a fluid flows through a restriction, such as a valve, a pressure gradient arises over the restriction. This pressure gradient is a result of the increased resistance to flow through the restriction. Natural heart valves have a low transvalvular pressure gradient as they present little obstruction to the flow through themselves, normally less than 16 mmHg. A desirable characteristic of heart valve prostheses is that their transvalvular pressure gradient is as small as possible.
  • Non-thrombogenic – Natural heart valves are lined with an endothelium comparable with the endothelium lining the heart chambers, so they are not normally thrombogenic (i.e. they don't cause blood clots). Blood clots can be hazardous because they can lodge in, and block, downstream arteries (e.g. coronary arteries, leading to heart attack [myocardial infarction]; or cerebral arteries, leading to stroke). A desirable characteristic of artificial heart valves is that they are non- or minimally thrombogenic.
  • Self-repairing – Valve leaflets retain some capacity for repair thanks to regenerative cells (e.g. fibroblasts) in the connective tissue from which the leaflets are composed. As the human heart beats approximately 3.4×109 times during a typical human lifespan, this limited but nevertheless present repair capacity is critically important. No heart valve prostheses can currently self-repair, but tissue-engineered valves may eventually offer such capabilities.[26]

Artificial heart valve repair edit

Artificial heart valves are expected to last from 10 to 30 years.[16]

The most common problems with artificial heart valves are various forms of degeneration, including gross billowing of leaflets, ischemic mitral valve pathology, and minor chordal lengthening.[24] The repairing process of the artificial heart valve regurgitation and stenosis usually requires an open-heart surgery, and a repair or partial replacement of regurgitant valves is usually preferred.[24]

Researchers are investigating catheter-based surgery that allows repair of an artificial heart valve without large incisions.[32]

Researchers are investigating Interchangeable Prosthetic Heart Valve that allows redo and fast-track repair of an artificial heart valve. [33]

Additional images edit

  •  
    3D Rendering of Mechanical Valve
  •  
    3D Rendering of Mechanical Valve (St. Francis model)

See also edit

References edit

  1. ^ Kostrzewa B, Rybak Z (2013). "[History, present and future of biomaterials used for artificial heart valves]". Polimery W Medycynie. 43 (3): 183–9. PMID 24377185.
  2. ^ Baumgartner H, Falk V, Bax JJ, De Bonis M, Hamm C, Holm PJ, et al. (September 2017). "2017 ESC/EACTS Guidelines for the management of valvular heart disease". European Heart Journal. 38 (36): 2739–2791. doi:10.1093/eurheartj/ehx391. PMID 28886619.
  3. ^ "Heart Valve Replacement: Which Type Is Best for You?". Health Essentials from Cleveland Clinic. 2018-06-14. Retrieved 2020-08-04.
  4. ^ Muraru D, Anwar AM, Song JK (December 2016). "Heart valve disease: tricuspid valve disease". Oxford Medicine Online. doi:10.1093/med/9780198726012.003.0037.
  5. ^ "Surgical aortic heart valves | Edwards Lifesciences". www.edwards.com. Retrieved 2019-07-29.
  6. ^ Medtronic. "Heart Valve Therapies - Surgical Replacement". www.medtronic.com. Retrieved 2019-07-29.
  7. ^ "Surgical Valves | Trifecta GT Valve and Epic Mitral Valve". www.cardiovascular.abbott. Retrieved 2019-07-29.[permanent dead link]
  8. ^ "On-X Heart Valves". CryoLife, Inc. Retrieved 2019-07-29.
  9. ^ "Cardiac | LifeNet Health". www.lifenethealth.org. Retrieved 2019-07-29.
  10. ^ a b Gott VL, Alejo DE, Cameron DE (December 2003). "Mechanical heart valves: 50 years of evolution". The Annals of Thoracic Surgery. 76 (6): S2230-9. doi:10.1016/j.athoracsur.2003.09.002. PMID 14667692.
  11. ^ a b c Pibarot P, Dumesnil JG (February 2009). "Prosthetic heart valves: selection of the optimal prosthesis and long-term management". Circulation. 119 (7): 1034–48. doi:10.1161/CIRCULATIONAHA.108.778886. PMID 19237674.
  12. ^ a b c Bloomfield P (June 2002). "Choice of heart valve prosthesis". Heart. 87 (6): 583–9. doi:10.1136/heart.87.6.583. PMC 1767148. PMID 12010950.
  13. ^ a b Matthews AM (1998). "The development of the Starr-Edwards heart valve". Texas Heart Institute Journal. 25 (4): 282–93. PMC 325574. PMID 9885105.
  14. ^ Goldsmith I, Turpie AG, Lip GY (November 2002). "Valvar heart disease and prosthetic heart valves". BMJ. 325 (7374): 1228–31. doi:10.1136/bmj.325.7374.1228. PMC 1124694. PMID 12446543.
  15. ^ Sun JC, Davidson MJ, Lamy A, Eikelboom JW (August 2009). "Antithrombotic management of patients with prosthetic heart valves: current evidence and future trends". Lancet. 374 (9689): 565–76. doi:10.1016/S0140-6736(09)60780-7. PMID 19683642. S2CID 43661491.
  16. ^ a b c d e f Tillquist MN, Maddox TM (February 2011). "Cardiac crossroads: deciding between mechanical or bioprosthetic heart valve replacement". Patient Preference and Adherence. 5: 91–9. doi:10.2147/PPA.S16420. PMC 3063655. PMID 21448466.
  17. ^ Johansen P (September 2004). "Mechanical heart valve cavitation". Expert Review of Medical Devices. 1 (1): 95–104. doi:10.1586/17434440.1.1.95. PMID 16293013. S2CID 27933945.
  18. ^ Namdari M, Eatemadi A (December 2016). "Nanofibrous bioengineered heart valve-Application in paediatric medicine". Biomedicine & Pharmacotherapy. 84: 1179–1188. doi:10.1016/j.biopha.2016.10.058. PMID 27780149.
  19. ^ Hickey GL, Grant SW, Bridgewater B, Kendall S, Bryan AJ, Kuo J, Dunning J (June 2015). "A comparison of outcomes between bovine pericardial and porcine valves in 38,040 patients in England and Wales over 10 years". European Journal of Cardio-Thoracic Surgery. 47 (6): 1067–74. doi:10.1093/ejcts/ezu307. PMID 25189704.
  20. ^ Harris C, Croce B, Cao C (July 2015). "Tissue and mechanical heart valves". Annals of Cardiothoracic Surgery. 4 (4): 399. doi:10.3978/j.issn.2225-319X.2015.07.01. PMC 4526499. PMID 26309855.
  21. ^ Johnston DR, Soltesz EG, Vakil N, Rajeswaran J, Roselli EE, Sabik JF, et al. (April 2015). "Long-term durability of bioprosthetic aortic valves: implications from 12,569 implants". The Annals of Thoracic Surgery. 99 (4): 1239–47. doi:10.1016/j.athoracsur.2014.10.070. PMC 5132179. PMID 25662439.
  22. ^ Flameng W, Hermans H, Verbeken E, Meuris B (January 2015). "A randomized assessment of an advanced tissue preservation technology in the juvenile sheep model". The Journal of Thoracic and Cardiovascular Surgery. 149 (1): 340–5. doi:10.1016/j.jtcvs.2014.09.062. PMID 25439467.
  23. ^ Bartuś K, Litwinowicz R, Kuśmierczyk M, Bilewska A, Bochenek M, Stąpór M, et al. (2017-12-19). "Primary safety and effectiveness feasibility study after surgical aortic valve replacement with a new generation bioprosthesis: one-year outcomes". Kardiologia Polska. 76 (3): 618–624. doi:10.5603/KP.a2017.0262. PMID 29297188. S2CID 4061454.
  24. ^ a b c d e f Hasan A, Saliba J, Pezeshgi Modarres H, Bakhaty A, Nasajpour A, Mofrad MR, Sanati-Nezhad A (October 2016). "Micro and nanotechnologies in heart valve tissue engineering". Biomaterials. 103: 278–292. doi:10.1016/j.biomaterials.2016.07.001. PMID 27414719.
  25. ^ a b c Stassen OM, Muylaert DE, Bouten CV, Hjortnaes J (September 2017). "Current Challenges in Translating Tissue-Engineered Heart Valves". Current Treatment Options in Cardiovascular Medicine. 19 (9): 71. doi:10.1007/s11936-017-0566-y. PMC 5545463. PMID 28782083.
  26. ^ a b c d Blum KM, Drews JD, Breuer CK (June 2018). "Tissue-Engineered Heart Valves: A Call for Mechanistic Studies". Tissue Engineering. Part B, Reviews. 24 (3): 240–253. doi:10.1089/ten.teb.2017.0425. PMC 5994154. PMID 29327671.
  27. ^ a b Theus AS, Tomov ML, Cetnar A, Lima B, Nish J, McCoy K, Mahmoudi M, Serpooshan V (2019-06-01). "Biomaterial approaches for cardiovascular tissue engineering". Emergent Materials. 2 (2): 193–207. doi:10.1007/s42247-019-00039-3. ISSN 2522-574X. S2CID 201165755.
  28. ^ Hay ED (2013-11-11). Cell Biology of Extracellular Matrix (Second ed.). Springer Science & Business Media. ISBN 978-1-4615-3770-0.
  29. ^ a b Nachlas AL, Li S, Davis ME (December 2017). "Developing a Clinically Relevant Tissue Engineered Heart Valve-A Review of Current Approaches". Advanced Healthcare Materials. 6 (24): 1700918. doi:10.1002/adhm.201700918. PMID 29171921. S2CID 2339263.
  30. ^ a b Schmidt JB, Tranquillo RT (2013). Tissue-Engineered Heart Valves. Boston, MA: Springer US. pp. 261–280. doi:10.1007/978-1-4614-6144-9_11. ISBN 978-1-4614-6143-2. {{cite book}}: |work= ignored (help)
  31. ^ Kasegawa H, Iwasaki K, Kusunose S, Tatusta R, Doi T, Yasuda H, Umezu M (January 2012). "Assessment of a novel stentless mitral valve using a pulsatile mitral valve simulator". The Journal of Heart Valve Disease. 21 (1): 71–5. PMID 22474745.
  32. ^ Bezuidenhout D, Williams DF, Zilla P (January 2015). "Polymeric heart valves for surgical implantation, catheter-based technologies and heart assist devices". Biomaterials. 36: 6–25. doi:10.1016/j.biomaterials.2014.09.013. PMID 25443788.
  33. ^ Roberto de Menezes Lyra | title = Eight Types of Interchangeable Prosthetic Heart Valve: A Mini Review. | journal = https://globaljournals.org | https://globaljournals.org/GJMR_Volume22/2-Eight-Types-of-Interchangeable-Prosthetic-Heart-Valve.pdf

Further reading edit

  • Bendet I, Morozov SM, Skumin VA [in French] (June 1980). "[Psychological aspects of the rehabilitation of patients after the surgical treatment of heart defects]" Психологические аспекты реабилитации больных после хирургического лечения пороков сердца [Psychological aspects of the rehabilitation of patients after the surgical treatment of heart defects]. Kardiologiia (in Russian). 20 (6): 45–51. PMID 7392405.
  • Skumin VA [in French] (September 1979). "[Nurse's role in medico-psychological rehabilitation of patients with artificial heart valves]". Meditsinskaia Sestra. 38 (9): 44–5. PMID 259874.
  • Skumin VA [in French] (1982). "[Nonpsychotic mental disorders in patients with acquired heart defects before and after surgery (review)]". Zhurnal Nevropatologii I Psikhiatrii Imeni S.S. Korsakova. 82 (11): 130–5. PMID 6758444.
  • Klepetko W, Moritz A, Mlczoch J, Schurawitzki H, Domanig E, Wolner E (January 1989). "Leaflet fracture in Edwards-Duromedics bileaflet valves". The Journal of Thoracic and Cardiovascular Surgery. 97 (1): 90–4. doi:10.1016/S0022-5223(19)35130-X. PMID 2911200.
  • Podesser BK, Khuenl-Brady G, Eigenbauer E, Roedler S, Schmiedberger A, Wolner E, Moritz A (May 1998). "Long-term results of heart valve replacement with the Edwards Duromedics bileaflet prosthesis: a prospective ten-year clinical follow-up". The Journal of Thoracic and Cardiovascular Surgery. 115 (5): 1121–9. doi:10.1016/s0022-5223(98)70412-x. PMID 9605082.
  • Knapp RJ, Daily JW, Hammitt FG (1970). Cavitation. New York: McGraw-Hill Int. Book Co.
  • Lim WL, Chew YT, Low HT, Foo WL (September 2003). "Cavitation phenomena in mechanical heart valves: the role of squeeze flow velocity and contact area on cavitation initiation between two impinging rods". Journal of Biomechanics. 36 (9): 1269–80. doi:10.1016/s0021-9290(03)00161-1. PMID 12893035.
  • Bluestein D, Einav S, Hwang NH (November 1994). "A squeeze flow phenomenon at the closing of a bileaflet mechanical heart valve prosthesis". Journal of Biomechanics. 27 (11): 1369–78. doi:10.1016/0021-9290(94)90046-9. PMID 7798287.
  • Graf T, Fischer H, Reul H, Rau G (March 1991). "Cavitation potential of mechanical heart valve prostheses". The International Journal of Artificial Organs. 14 (3): 169–74. doi:10.1177/039139889101400309. PMID 2045192. S2CID 23086590.
  • Kafesjian R, Wieting DW, Ely J, Chahine GL, Frederick GS, Watson RE (1990). "Characterization of Cavitation Potential of Pyrolitic Carbon". In Bodnar E (ed.). Surgery for Heart Valve Disease: Proceedings of the 1989 Symposium. ICR. pp. 509–16. ISBN 978-1-872743-00-4.
  • Chahine GL (March 1996). "Scaling of mechanical heart valves for cavitation inception: observation and acoustic detection". The Journal of Heart Valve Disease. 5 (2): 207–14, discussion 214–5. PMID 8665016.
  • Zapanta CM, Stinebring DR, Sneckenberger DS, Deutsch S, Geselowitz DB, Tarbell JM, et al. (1996). "In vivo observation of cavitation on prosthetic heart valves". ASAIO Journal. 42 (5): M550-5. doi:10.1097/00002480-199609000-00047. PMID 8944940.
  • Richard G, Beavan A, Strzepa P (April 1994). "Cavitation threshold ranking and erosion characteristics of bileaflet heart valve prostheses". The Journal of Heart Valve Disease. 3 (Suppl 1): S94-101. PMID 8061875.

External links edit

  • . Mayo Clinic. Archived from the original on 13 November 2006.
  • "New Design for Mechanical Heart Valves". ScienceDaily. 23 November 2011.

January 01, 1970
artificial, heart, valve, this, article, needs, more, reliable, medical, references, verification, relies, heavily, primary, sources, please, review, contents, article, appropriate, references, unsourced, poorly, sourced, material, challenged, removed, find, s. This article needs more reliable medical references for verification or relies too heavily on primary sources Please review the contents of the article and add the appropriate references if you can Unsourced or poorly sourced material may be challenged and removed Find sources Artificial heart valve news newspapers books scholar JSTOR January 2022 An artificial heart valve is a one way valve implanted into a person s heart to replace a heart valve that is not functioning properly valvular heart disease Artificial heart valves can be separated into three broad classes mechanical heart valves bioprosthetic tissue valves and engineered tissue valves Artificial heart valveDifferent types of artificial heart valves 1 Specialtycardiology edit on Wikidata The human heart contains four valves tricuspid valve pulmonary valve mitral valve and aortic valve Their main purpose is to keep blood flowing in the proper direction through the heart and from the heart into the major blood vessels connected to it the pulmonary artery and the aorta Heart valves can malfunction for a variety of reasons which can impede the flow of blood through the valve stenosis and or let blood flow backwards through the valve regurgitation Both processes put strain on the heart and may lead to serious problems including heart failure While some dysfunctional valves can be treated with drugs or repaired others need to be replaced with an artificial valve 2 Contents 1 Background 2 Mechanical valves 2 1 Caged ball valves 2 2 Tilting disc valves 2 3 Bileaflet valves 2 4 Advantages of mechanical valves 2 5 Disadvantages of mechanical valves 3 Bioprosthetic tissue valves 3 1 Advantages of bioprosthetic heart valves 3 2 Disadvantages of bioprosthetic heart valves 4 Tissue engineered valves 5 Differences between mechanical and tissue valves 6 Functional requirements of artificial heart valves 7 Artificial heart valve repair 8 Additional images 9 See also 10 References 11 Further reading 12 External linksBackground edit nbsp 3D Medical Animation still shot of Artificial Heart Valve A heart contains four valves tricuspid pulmonary mitral and aortic valves which open and close as blood passes through the heart 3 Blood enters the heart in the right atrium and passes through the tricuspid valve to the right ventricle From there blood is pumped through the pulmonary valve to enter the lungs After being oxygenated blood passes to the left atrium where is it pumped through the mitral valve to the left ventricle The left ventricle pumps blood to the aorta through the aortic valve There are many potential causes of heart valve damage such as birth defects age related changes and effects from other disorders such as rheumatic fever and infections causing endocarditis High blood pressure and heart failure which can enlarge the heart and arteries and scar tissue can form after a heart attack or injury 4 The three main types of artificial heart valves are mechanical biological bioprosthetic tissue and tissue engineered valves In the US UK and the European Union the most common type of artificial heart valve is the bioprosthetic valve Mechanical valves are more commonly used in Asia and Latin America citation needed Companies that manufacture heart valves include Edwards Lifesciences 5 Medtronic 6 Abbott St Jude Medical 7 CryoLife 8 and LifeNet Health 9 Mechanical valves editMechanical valves come in three main types caged ball tilting disc and bileaflet with various modifications on these designs 10 Caged ball valves are no longer implanted 11 Bileaflet valves are the most common type of mechanical valve implanted in patients today 12 Caged ball valves edit nbsp Caged ball valve The first artificial heart valve was the caged ball valve a type of ball check valve in which a ball is housed inside a cage When the heart contracts and the blood pressure in the chamber of the heart exceeds the pressure on the outside of the chamber the ball is pushed against the cage and allows blood to flow When the heart finishes contracting the pressure inside the chamber drops and the ball moves back against the base of the valve forming a seal In 1952 Charles A Hufnagel implanted caged ball heart valves into ten patients six of whom survived the operation marking the first success in prosthetic heart valves citation needed A similar valve was invented by Miles Lowell Edwards and Albert Starr in 1960 commonly referred to as the Starr Edwards silastic ball valve 13 This consisted of a silicone ball enclosed in a methyl metacrylate cage welded to a ring The Starr Edwards valve was first implanted in a human on August 25 1960 and was discontinued by Edwards Lifesciences in 2007 13 Caged ball valves are strongly associated with blood clot formation so people who have one required a high degree of anticoagulation usually with a target INR of 3 0 4 5 14 Tilting disc valves edit nbsp tilting disc valve Introduced in 1969 the first clinically available tilting disc valve was the Bjork Shiley valve 15 Tilting disc valves a type of swing check valve are made of a metal ring covered by an ePTFE fabric The metal ring holds by means of two metal supports a disc that opens when the heart beats to let blood flow through then closes again to prevent blood flowing backwards The disc is usually made of an extremely hard carbon material pyrolytic carbon enabling the valve to function for years without wearing out citation needed Bileaflet valves edit nbsp Bileaflet valve Introduced in 1979 bileaflet valves are made of two semicircular leaflets that revolve around struts attached to the valve housing With a larger opening than caged ball or tilting disc valves they carry a lower risk of blood clots They are however vulnerable to blood backflow citation needed Advantages of mechanical valves edit The major advantage of mechanical valves over bioprosthetic valves is their greater durability 16 Made from metal and or pyrolytic carbon 10 they can last 20 30 years 16 Disadvantages of mechanical valves edit One of the major drawbacks of mechanical heart valves is that they are associated with an increased risk of blood clots Clots formed by red blood cell and platelet damage can block blood vessels leading to stroke People with mechanical valves need to take anticoagulants blood thinners such as warfarin for the rest of their life 16 Mechanical heart valves can also cause mechanical hemolytic anemia a condition where the red blood cells are damaged as they pass through the valve citation needed Cavitation the rapid formation of microbubbles in a fluid such as blood due to a localized drop of pressure can lead to mechanical heart valve failure 17 so cavitation testing is an essential part of the valve design verification process Many of the complications associated with mechanical heart valves can be explained through fluid mechanics For example blood clot formation is a side effect of high shear stresses created by the design of the valves From an engineering perspective an ideal heart valve would produce minimal pressure drops have small regurgitation volumes minimize turbulence reduce prevalence of high stresses and not create flow separations in the vicinity of the valve citation needed Implanted mechanical valves can cause foreign body rejection The blood may coagulate and eventually result in a hemostasis The usage of anticoagulation drugs will be interminable to prevent thrombosis 18 non primary source needed Bioprosthetic tissue valves editBioprosthetic valves are usually made from animal tissue heterograft xenograft attached to a metal or polymer support 11 Bovine cow tissue is most commonly used but some are made from porcine pig tissue 19 non primary source needed The tissue is treated to prevent rejection and calcification citation needed Alternatives to animal tissue valves are sometimes used where valves are used from human donors as in aortic homografts and pulmonary autografts An aortic homograft is an aortic valve from a human donor retrieved either after their death or from a heart that is removed to be replaced during a heart transplant 12 A pulmonary autograft also known as the Ross procedure is where the aortic valve is removed and replaced with the patient s own pulmonary valve the valve between the right ventricle and the pulmonary artery A pulmonary homograft a pulmonary valve taken from a cadaver is then used to replace the patient s own pulmonary valve This procedure was first performed in 1967 and is used primarily in children as it allows the patient s own pulmonary valve now in the aortic position to grow with the child 12 Advantages of bioprosthetic heart valves edit Bioprosthetic valves are less likely than mechanical valves to cause blood clots so do not require lifelong anticoagulation As a result people with bioprosthetic valves have a lower risk of bleeding than those with mechanical valves 16 Disadvantages of bioprosthetic heart valves edit Tissue valves are less durable than mechanical valves typically lasting 10 20 years 20 This means that people with bioprosthetic valves have a higher incidence of requiring another aortic valve replacement in their lifetime 16 Bioprosthetic valves tend to deteriorate more quickly in younger patients 21 In recent years scientists have developed a new tissue preservation technology with the aim of improving the durability of bioprosthetic valves In sheep and rabbit studies tissue preserved using this new technology had less calcification than control tissue 22 A valve containing this tissue is now marketed but long term durability data in patients are not yet available 23 non primary source needed Current bioprosthetic valves lack longevity and will calcify over time 24 When a valve calcifies the valve cusps become stiff and thick and cannot close completely 24 Moreover bioprosthetic valves can t grow with or adapt to the patient if a child has bioprosthetic valves they will need to get the valves replaced several times to fit their physical growth 24 Tissue engineered valves editFor over 30 years researchers have been trying to grow heart valves in vitro 25 These tissue engineered valves involve seeding human cells on to a scaffold 25 The two main types of scaffold are natural scaffolds such as decellularized tissue or scaffolds made from degradable polymers 26 The scaffold acts as an extracellular matrix guiding tissue growth into the correct 3D structure of the heart valve 26 25 Some tissue engineered heart valves have been tested in clinical trials 26 but none are commercially available Tissue engineered heart valves can be person specific and 3D modeled to fit an individual recipient 27 3D printing is used because of its high accuracy and precision of dealing with different biomaterials 27 Cells that are used for tissue engineered heart valves are expected to secrete the extracellular matrix ECM 24 Extracellular matrix provides support to maintain the shape of the valves and determines the cell activities 28 Scientists can follow the structure of heart valves to produce something that looks similar to them but since tissue engineered valves lack the natural cellular basis they either fail to perform their functions like natural heart valves or function when they are implanted but gradually degrade over time citation needed An ideal tissue engineered heart valve would be non thrombogenic biocompatible durable resistant to calcification grow with the surrounding heart and exhibit a physiological hemodynamic profile 29 To achieve these goals the scaffold should be carefully chosen there are three main candidates decellularized ECM xenografts or homografts natural polymers and synthetic polymers 29 Differences between mechanical and tissue valves editMechanical and tissue valves are made of different materials Mechanical valves are generally made of titanium and carbon 30 Tissue valves are made up of human or animal tissue The valves composed of human tissue known as allografts or homografts are from donors human hearts 30 Mechanical valves can be a better choice for younger people and people at risk of valve deterioration due to its durability It is also preferable for people who are already taking blood thinners and people who would be unlikely to tolerate another valve replacement operation citation needed Tissue valves are better for older age groups as another valve replacement operation may not be needed in their lifetime Due to the risk of forming blood clots for mechanical valves and severe bleeding as a major side effect of taking blood thinning medications people who have a risk of blood bleeding and are not willing to take warfarin may also consider tissue valves Other patients who may be more suitable for tissue valves are people who have other planned surgeries and unable to take blood thinning medications People who plan to become pregnant may also consider tissue valves as warfarin causes risks in pregnancy citation needed Functional requirements of artificial heart valves editAn artificial heart valve should ideally function like a natural heart valve 11 The functioning of natural heart valves is characterized by many advantages Minimal regurgitation This means that the amount of blood leaking backwards through the valve as it closes is small Some degree of valvular regurgitation is inevitable and natural up to around 5 ml per beat 31 However several heart valve pathologies e g rheumatic endocarditis may lead to clinically significant valvular regurgitation A desirable characteristic of heart valve prostheses is that regurgitation is minimal over the full range of physiological heart function Minimal transvalvular pressure gradient Whenever a fluid flows through a restriction such as a valve a pressure gradient arises over the restriction This pressure gradient is a result of the increased resistance to flow through the restriction Natural heart valves have a low transvalvular pressure gradient as they present little obstruction to the flow through themselves normally less than 16 mmHg A desirable characteristic of heart valve prostheses is that their transvalvular pressure gradient is as small as possible Non thrombogenic Natural heart valves are lined with an endothelium comparable with the endothelium lining the heart chambers so they are not normally thrombogenic i e they don t cause blood clots Blood clots can be hazardous because they can lodge in and block downstream arteries e g coronary arteries leading to heart attack myocardial infarction or cerebral arteries leading to stroke A desirable characteristic of artificial heart valves is that they are non or minimally thrombogenic Self repairing Valve leaflets retain some capacity for repair thanks to regenerative cells e g fibroblasts in the connective tissue from which the leaflets are composed As the human heart beats approximately 3 4 109 times during a typical human lifespan this limited but nevertheless present repair capacity is critically important No heart valve prostheses can currently self repair but tissue engineered valves may eventually offer such capabilities 26 Artificial heart valve repair editArtificial heart valves are expected to last from 10 to 30 years 16 The most common problems with artificial heart valves are various forms of degeneration including gross billowing of leaflets ischemic mitral valve pathology and minor chordal lengthening 24 The repairing process of the artificial heart valve regurgitation and stenosis usually requires an open heart surgery and a repair or partial replacement of regurgitant valves is usually preferred 24 Researchers are investigating catheter based surgery that allows repair of an artificial heart valve without large incisions 32 Researchers are investigating Interchangeable Prosthetic Heart Valve that allows redo and fast track repair of an artificial heart valve 33 Additional images edit nbsp 3D Rendering of Mechanical Valve nbsp 3D Rendering of Mechanical Valve St Francis model See also editArtificial heart Artificial pacemaker Mitral valve replacement Aortic valve replacementReferences edit Kostrzewa B Rybak Z 2013 History present and future of biomaterials used for artificial heart valves Polimery W Medycynie 43 3 183 9 PMID 24377185 Baumgartner H Falk V Bax JJ De Bonis M Hamm C Holm PJ et al September 2017 2017 ESC EACTS Guidelines for the management of valvular heart disease European Heart Journal 38 36 2739 2791 doi 10 1093 eurheartj ehx391 PMID 28886619 Heart Valve Replacement Which Type Is Best for You Health Essentials from Cleveland Clinic 2018 06 14 Retrieved 2020 08 04 Muraru D Anwar AM Song JK December 2016 Heart valve disease tricuspid valve disease Oxford Medicine Online doi 10 1093 med 9780198726012 003 0037 Surgical aortic heart valves Edwards Lifesciences www edwards com Retrieved 2019 07 29 Medtronic Heart Valve Therapies Surgical Replacement www medtronic com Retrieved 2019 07 29 Surgical Valves Trifecta GT Valve and Epic Mitral Valve www cardiovascular abbott Retrieved 2019 07 29 permanent dead link On X Heart Valves CryoLife Inc Retrieved 2019 07 29 Cardiac LifeNet Health www lifenethealth org Retrieved 2019 07 29 a b Gott VL Alejo DE Cameron DE December 2003 Mechanical heart valves 50 years of evolution The Annals of Thoracic Surgery 76 6 S2230 9 doi 10 1016 j athoracsur 2003 09 002 PMID 14667692 a b c Pibarot P Dumesnil JG February 2009 Prosthetic heart valves selection of the optimal prosthesis and long term management Circulation 119 7 1034 48 doi 10 1161 CIRCULATIONAHA 108 778886 PMID 19237674 a b c Bloomfield P June 2002 Choice of heart valve prosthesis Heart 87 6 583 9 doi 10 1136 heart 87 6 583 PMC 1767148 PMID 12010950 a b Matthews AM 1998 The development of the Starr Edwards heart valve Texas Heart Institute Journal 25 4 282 93 PMC 325574 PMID 9885105 Goldsmith I Turpie AG Lip GY November 2002 Valvar heart disease and prosthetic heart valves BMJ 325 7374 1228 31 doi 10 1136 bmj 325 7374 1228 PMC 1124694 PMID 12446543 Sun JC Davidson MJ Lamy A Eikelboom JW August 2009 Antithrombotic management of patients with prosthetic heart valves current evidence and future trends Lancet 374 9689 565 76 doi 10 1016 S0140 6736 09 60780 7 PMID 19683642 S2CID 43661491 a b c d e f Tillquist MN Maddox TM February 2011 Cardiac crossroads deciding between mechanical or bioprosthetic heart valve replacement Patient Preference and Adherence 5 91 9 doi 10 2147 PPA S16420 PMC 3063655 PMID 21448466 Johansen P September 2004 Mechanical heart valve cavitation Expert Review of Medical Devices 1 1 95 104 doi 10 1586 17434440 1 1 95 PMID 16293013 S2CID 27933945 Namdari M Eatemadi A December 2016 Nanofibrous bioengineered heart valve Application in paediatric medicine Biomedicine amp Pharmacotherapy 84 1179 1188 doi 10 1016 j biopha 2016 10 058 PMID 27780149 Hickey GL Grant SW Bridgewater B Kendall S Bryan AJ Kuo J Dunning J June 2015 A comparison of outcomes between bovine pericardial and porcine valves in 38 040 patients in England and Wales over 10 years European Journal of Cardio Thoracic Surgery 47 6 1067 74 doi 10 1093 ejcts ezu307 PMID 25189704 Harris C Croce B Cao C July 2015 Tissue and mechanical heart valves Annals of Cardiothoracic Surgery 4 4 399 doi 10 3978 j issn 2225 319X 2015 07 01 PMC 4526499 PMID 26309855 Johnston DR Soltesz EG Vakil N Rajeswaran J Roselli EE Sabik JF et al April 2015 Long term durability of bioprosthetic aortic valves implications from 12 569 implants The Annals of Thoracic Surgery 99 4 1239 47 doi 10 1016 j athoracsur 2014 10 070 PMC 5132179 PMID 25662439 Flameng W Hermans H Verbeken E Meuris B January 2015 A randomized assessment of an advanced tissue preservation technology in the juvenile sheep model The Journal of Thoracic and Cardiovascular Surgery 149 1 340 5 doi 10 1016 j jtcvs 2014 09 062 PMID 25439467 Bartus K Litwinowicz R Kusmierczyk M Bilewska A Bochenek M Stapor M et al 2017 12 19 Primary safety and effectiveness feasibility study after surgical aortic valve replacement with a new generation bioprosthesis one year outcomes Kardiologia Polska 76 3 618 624 doi 10 5603 KP a2017 0262 PMID 29297188 S2CID 4061454 a b c d e f Hasan A Saliba J Pezeshgi Modarres H Bakhaty A Nasajpour A Mofrad MR Sanati Nezhad A October 2016 Micro and nanotechnologies in heart valve tissue engineering Biomaterials 103 278 292 doi 10 1016 j biomaterials 2016 07 001 PMID 27414719 a b c Stassen OM Muylaert DE Bouten CV Hjortnaes J September 2017 Current Challenges in Translating Tissue Engineered Heart Valves Current Treatment Options in Cardiovascular Medicine 19 9 71 doi 10 1007 s11936 017 0566 y PMC 5545463 PMID 28782083 a b c d Blum KM Drews JD Breuer CK June 2018 Tissue Engineered Heart Valves A Call for Mechanistic Studies Tissue Engineering Part B Reviews 24 3 240 253 doi 10 1089 ten teb 2017 0425 PMC 5994154 PMID 29327671 a b Theus AS Tomov ML Cetnar A Lima B Nish J McCoy K Mahmoudi M Serpooshan V 2019 06 01 Biomaterial approaches for cardiovascular tissue engineering Emergent Materials 2 2 193 207 doi 10 1007 s42247 019 00039 3 ISSN 2522 574X S2CID 201165755 Hay ED 2013 11 11 Cell Biology of Extracellular Matrix Second ed Springer Science amp Business Media ISBN 978 1 4615 3770 0 a b Nachlas AL Li S Davis ME December 2017 Developing a Clinically Relevant Tissue Engineered Heart Valve A Review of Current Approaches Advanced Healthcare Materials 6 24 1700918 doi 10 1002 adhm 201700918 PMID 29171921 S2CID 2339263 a b Schmidt JB Tranquillo RT 2013 Tissue Engineered Heart Valves Boston MA Springer US pp 261 280 doi 10 1007 978 1 4614 6144 9 11 ISBN 978 1 4614 6143 2 a href Template Cite book html title Template Cite book cite book a work ignored help Kasegawa H Iwasaki K Kusunose S Tatusta R Doi T Yasuda H Umezu M January 2012 Assessment of a novel stentless mitral valve using a pulsatile mitral valve simulator The Journal of Heart Valve Disease 21 1 71 5 PMID 22474745 Bezuidenhout D Williams DF Zilla P January 2015 Polymeric heart valves for surgical implantation catheter based technologies and heart assist devices Biomaterials 36 6 25 doi 10 1016 j biomaterials 2014 09 013 PMID 25443788 Roberto de Menezes Lyra title Eight Types of Interchangeable Prosthetic Heart Valve A Mini Review journal https globaljournals org https globaljournals org GJMR Volume22 2 Eight Types of Interchangeable Prosthetic Heart Valve pdfFurther reading editBendet I Morozov SM Skumin VA in French June 1980 Psychological aspects of the rehabilitation of patients after the surgical treatment of heart defects Psihologicheskie aspekty reabilitacii bolnyh posle hirurgicheskogo lecheniya porokov serdca Psychological aspects of the rehabilitation of patients after the surgical treatment of heart defects Kardiologiia in Russian 20 6 45 51 PMID 7392405 Skumin VA in French September 1979 Nurse s role in medico psychological rehabilitation of patients with artificial heart valves Meditsinskaia Sestra 38 9 44 5 PMID 259874 Skumin VA in French 1982 Nonpsychotic mental disorders in patients with acquired heart defects before and after surgery review Zhurnal Nevropatologii I Psikhiatrii Imeni S S Korsakova 82 11 130 5 PMID 6758444 Klepetko W Moritz A Mlczoch J Schurawitzki H Domanig E Wolner E January 1989 Leaflet fracture in Edwards Duromedics bileaflet valves The Journal of Thoracic and Cardiovascular Surgery 97 1 90 4 doi 10 1016 S0022 5223 19 35130 X PMID 2911200 Podesser BK Khuenl Brady G Eigenbauer E Roedler S Schmiedberger A Wolner E Moritz A May 1998 Long term results of heart valve replacement with the Edwards Duromedics bileaflet prosthesis a prospective ten year clinical follow up The Journal of Thoracic and Cardiovascular Surgery 115 5 1121 9 doi 10 1016 s0022 5223 98 70412 x PMID 9605082 Knapp RJ Daily JW Hammitt FG 1970 Cavitation New York McGraw Hill Int Book Co Lim WL Chew YT Low HT Foo WL September 2003 Cavitation phenomena in mechanical heart valves the role of squeeze flow velocity and contact area on cavitation initiation between two impinging rods Journal of Biomechanics 36 9 1269 80 doi 10 1016 s0021 9290 03 00161 1 PMID 12893035 Bluestein D Einav S Hwang NH November 1994 A squeeze flow phenomenon at the closing of a bileaflet mechanical heart valve prosthesis Journal of Biomechanics 27 11 1369 78 doi 10 1016 0021 9290 94 90046 9 PMID 7798287 Graf T Fischer H Reul H Rau G March 1991 Cavitation potential of mechanical heart valve prostheses The International Journal of Artificial Organs 14 3 169 74 doi 10 1177 039139889101400309 PMID 2045192 S2CID 23086590 Kafesjian R Wieting DW Ely J Chahine GL Frederick GS Watson RE 1990 Characterization of Cavitation Potential of Pyrolitic Carbon In Bodnar E ed Surgery for Heart Valve Disease Proceedings of the 1989 Symposium ICR pp 509 16 ISBN 978 1 872743 00 4 Chahine GL March 1996 Scaling of mechanical heart valves for cavitation inception observation and acoustic detection The Journal of Heart Valve Disease 5 2 207 14 discussion 214 5 PMID 8665016 Zapanta CM Stinebring DR Sneckenberger DS Deutsch S Geselowitz DB Tarbell JM et al 1996 In vivo observation of cavitation on prosthetic heart valves ASAIO Journal 42 5 M550 5 doi 10 1097 00002480 199609000 00047 PMID 8944940 Richard G Beavan A Strzepa P April 1994 Cavitation threshold ranking and erosion characteristics of bileaflet heart valve prostheses The Journal of Heart Valve Disease 3 Suppl 1 S94 101 PMID 8061875 External links edit Page describing types of heart valve replacements Mayo Clinic Archived from the original on 13 November 2006 New Design for Mechanical Heart Valves ScienceDaily 23 November 2011 Retrieved from https en wikipedia org w index php title Artificial heart valve amp oldid 1197348846, wikipedia, wiki, book, books, library,

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