An implant is a medical device manufactured to replace a missing biological structure, support a damaged biological structure, or enhance an existing biological structure. For example, an implant may be a rod, used to strengthen weak bones. Medical implants are human-made devices, in contrast to a transplant, which is a transplanted biomedical tissue. The surface of implants that contact the body might be made of a biomedical material such as titanium, silicone, or apatite depending on what is the most functional.[1] In 2018, for example, American Elements developed a nickel alloy powder for 3D printing robust, long-lasting, and biocompatible medical implants.[2] In some cases implants contain electronics, e.g. artificial pacemaker and cochlear implants. Some implants are bioactive, such as subcutaneous drug delivery devices in the form of implantable pills or drug-eluting stents.[3]
Applications
editImplants can roughly be categorized into groups by application:
Sensory and neurological
editSensory and neurological implants are used for disorders affecting the major senses and the brain, as well as other neurological disorders. They are predominately used in the treatment of conditions such as cataract, glaucoma, keratoconus, and other visual impairments; otosclerosis and other hearing loss issues, as well as middle ear diseases such as otitis media; and neurological diseases such as epilepsy, Parkinson's disease, and treatment-resistant depression. Examples include the intraocular lens, intrastromal corneal ring segment, cochlear implant, tympanostomy tube, and neurostimulator.[1][3][4]
Cardiovascular
editCardiovascular medical devices are implanted in cases where the heart, its valves, and the rest of the circulatory system is in disorder. They are used to treat conditions such as heart failure, cardiac arrhythmia, ventricular tachycardia, valvular heart disease, angina pectoris, and atherosclerosis. Examples include the artificial heart, artificial heart valve, implantable cardioverter-defibrillator, artificial cardiac pacemaker, and coronary stent.[1][3][4]
Orthopedic
editOrthopaedic implants help alleviate issues with the bones and joints of the body.[5] They are used to treat bone fractures, osteoarthritis, scoliosis, spinal stenosis, and chronic pain as well as in knee and hip replacements. Examples include a wide variety of pins, rods, screws, and plates used to anchor fractured bones while they heal.[1][3][4]
Metallic glasses based on magnesium with zinc and calcium addition are tested as the potential metallic biomaterials for biodegradable medical implants.[6][7]
Patients with orthopaedic implants sometimes need to be put under magnetic resonance imaging (MRI) machine for detailed musculoskeletal study. Therefore, concerns have been raised regarding the loosening and migration of implant, heating of the implant metal which could cause thermal damage to surrounding tissues, and distortion of the MRI scan that affects the imaging results. A study of orthopaedic implants in 2005 has shown that majority of the orthopaedic implants does not react with magnetic fields under the 1.0 Tesla MRI scanning machine with the exception of external fixator clamps.[8] However, at 7.0 Tesla, several orthopaedic implants would show significant interaction with the MRI magnetic fields, such as heel and fibular implant.[9]
Electric
editElectrical implants are being used to relieve pain from rheumatoid arthritis.[10] The electric implant is embedded in the neck of patients with rheumatoid arthritics, the implant sends electrical signals to electrodes in the vagus nerve.[11][12] The application of this device is being tested an alternative to medicating people with rheumatoid arthritis for their lifetime.[13]
Contraception
editContraceptive implants are primarily used to prevent unintended pregnancy and treat conditions such as non-pathological forms of menorrhagia. Examples include copper- and hormone-based intrauterine devices.[3][4][14]
Cosmetic
editCosmetic implants — often prosthetics — attempt to bring some portion of the body back to an acceptable aesthetic norm. They are used as a follow-up to mastectomy due to breast cancer, for correcting some forms of disfigurement, and modifying aspects of the body (as in buttock augmentation and chin augmentation). Examples include the breast implant, nose prosthesis, ocular prosthesis, and injectable filler.[1][3][4]
Other organs and systems
editOther types of organ dysfunction can occur in the systems of the body, including the gastrointestinal, respiratory, and urological systems. Implants are used in those and other locations to treat conditions such as gastroesophageal reflux disease, gastroparesis, respiratory failure, sleep apnea, urinary and fecal incontinence, and erectile dysfunction. Examples include the LINX, implantable gastric stimulator, diaphragmatic/phrenic nerve stimulator, neurostimulator, surgical mesh, artificial urinary sphincter and penile implant.[3][4][15][16][17][18][19]
Classification
editUnited States classification
editMedical devices are classified by the US Food and Drug Administration (FDA) under three different classes depending on the risks the medical device may impose on the user. According to 21CFR 860.3, Class I devices are considered to pose the least amount of risk to the user and require the least amount of control. Class I devices include simple devices such as arm slings and hand-held surgical instruments. Class II devices are considered to need more regulation than Class I devices and are required to undergo specific requirements before FDA approval. Class II devices include X-ray systems and physiological monitors. Class III devices require the most regulatory controls since the device supports or sustains human life or may not be well tested. Class III devices include replacement heart valves and implanted cerebellar stimulators. Many implants typically fall under Class II and Class III devices.[20][21]
Materials
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Commonly implanted metals
editA variety of minimally bioreactive metals are routinely implanted. The most commonly implanted form of stainless steel is 316L. Cobalt-chromium and titanium-based implant alloys are also permanently implanted. All of these are made passive by a thin layer of oxide on their surface. A consideration, however, is that metal ions diffuse outward through the oxide and end up in the surrounding tissue. Bioreaction to metal implants includes the formation of a small envelope of fibrous tissue. The thickness of this layer is determined by the products being dissolved, and the extent to which the implant moves around within the enclosing tissue. Pure titanium may have only a minimal fibrous encapsulation. Stainless steel, on the other hand, may elicit encapsulation of as much as 2 mm.[22]
List of implantable metal alloys
edit- ASTM F138/F139 316L
- ASTM F1314 22Cr-13Ni–5Mn
- ASTM F67 Unalloyed (Commercially Pure) Titanium
- ASTM F136 Ti-6Al-4V-ELI
- ASTM F1295 Ti-6Al-7Nb
- ASTM F1472 Ti-6Al-4V
- ASTM F90 Co-20Cr-15W-10Ni
- ASTM F562 Co-35Ni-20Cr-10Mo
- ASTM F1537 Co-28Cr-6Mo
Tantalum
edit- ASTM F560 Unalloyed Tantalum
Porosity in Implants
editPorous implants are characterized by the presence of voids in the metallic or ceramic matrix. Voids can be regular, such as in additively manufactured (AM) lattices,[23] or stochastic, such as in gas-infiltrated production processes.[24] The reduction in the modulus of the implant follows a complex nonlinear relationship dependent on the volume fraction of base material and morphology of the pores.[25]
Experimental models exist to predict the range of modulus that stochastic porous material may take.[26] Above 10% vol. fraction porosity, models begin to deviate significantly. Different models, such as the rule of mixtures for low porosity, two-material matrices have been developed to describe mechanical properties.[27]
AM lattices have more predictable mechanical properties compared to stochastic porous materials and can be tuned such that they have favorable directional mechanical properties. Variables such as strut diameter, strut shape, and number of cross-beams can have a dramatic effect on loading characteristics of the lattice.[28] AM has the ability to fine-tune the lattice spacing to within a much smaller range than stochastically porous structures, enabling the future cell-development of specific cultures in tissue engineering.[29]
Porosity in implants serves two primary purposes
edit1) The elastic modulus of the implant is decreased, allowing the implant to better match the elastic modulus of the bone. The elastic modulus of cortical bone (~18 GPa) is significantly lower than typical solid titanium or steel implants (110 GPa and 210 GPa, respectively), causing the implant take up a disproportionate amount of the load applied to the appendage, leading to an effect called stress shielding.
2) Porosity enables osteoblastic cells to grow into the pores of implants. Cells can span gaps of smaller than 75 microns and grow into pores larger than 200 microns.[24] Bone ingrowth is a favorable effect, as it anchors the cells into the implant, increasing the strength of the bone-implant interface.[30] More load is transferred from the implant to the bone, reducing stress shielding effects. The density of the bone around the implant is likely to be higher due to the increased load applied to the bone. Bone ingrowth reduces the likelihood of the implant loosening over time because stress shielding and corresponding bone resorption over extended timescales is avoided.[31] Porosity of greater than 40% is favorable to facilitate sufficient anchoring of the osteoblastic cells.[32]
Complications
editUnder ideal conditions, implants should initiate the desired host response. Ideally, the implant should not cause any undesired reaction from neighboring or distant tissues. However, the interaction between the implant and the tissue surrounding the implant can lead to complications.[1] The process of implantation of medical devices is subjected to the same complications that other invasive medical procedures can have during or after surgery. Common complications include infection, inflammation, and pain. Other complications that can occur include risk of rejection from implant-induced coagulation and allergic foreign body response. Depending on the type of implant, the complications may vary.[1]
When the site of an implant becomes infected during or after surgery, the surrounding tissue becomes infected by microorganisms. Three main categories of infection can occur after operation. Superficial immediate infections are caused by organisms that commonly grow near or on skin. The infection usually occurs at the surgical opening. Deep immediate infection, the second type, occurs immediately after surgery at the site of the implant. Skin-dwelling and airborne bacteria cause deep immediate infection. These bacteria enter the body by attaching to the implant's surface prior to implantation. Though not common, deep immediate infections can also occur from dormant bacteria from previous infections of the tissue at the implantation site that have been activated from being disturbed during the surgery. The last type, late infection, occurs months to years after the implantation of the implant. Late infections are caused by dormant blood-borne bacteria attached to the implant prior to implantation. The blood-borne bacteria colonize on the implant and eventually get released from it. Depending on the type of material used to make the implant, it may be infused with antibiotics to lower the risk of infections during surgery. However, only certain types of materials can be infused with antibiotics, the use of antibiotic-infused implants runs the risk of rejection by the patient since the patient may develop a sensitivity to the antibiotic, and the antibiotic may not work on the bacteria.[33]
Inflammation, a common occurrence after any surgical procedure, is the body's response to tissue damage as a result of trauma, infection, intrusion of foreign materials, or local cell death, or as a part of an immune response. Inflammation starts with the rapid dilation of local capillaries to supply the local tissue with blood. The inflow of blood causes the tissue to become swollen and may cause cell death. The excess blood, or edema, can activate pain receptors at the tissue. The site of the inflammation becomes warm from local disturbances of fluid flow and the increased cellular activity to repair the tissue or remove debris from the site.[33]
Implant-induced coagulation is similar to the coagulation process done within the body to prevent blood loss from damaged blood vessels. However, the coagulation process is triggered from proteins that become attached to the implant surface and lose their shapes. When this occurs, the protein changes conformation and different activation sites become exposed, which may trigger an immune system response where the body attempts to attack the implant to remove the foreign material. The trigger of the immune system response can be accompanied by inflammation. The immune system response may lead to chronic inflammation where the implant is rejected and has to be removed from the body. The immune system may encapsulate the implant as an attempt to remove the foreign material from the site of the tissue by encapsulating the implant in fibrinogen and platelets. The encapsulation of the implant can lead to further complications, since the thick layers of fibrous encapsulation may prevent the implant from performing the desired functions. Bacteria may attack the fibrous encapsulation and become embedded into the fibers. Since the layers of fibers are thick, antibiotics may not be able to reach the bacteria and the bacteria may grow and infect the surrounding tissue. In order to remove the bacteria, the implant would have to be removed. Lastly, the immune system may accept the presence of the implant and repair and remodel the surrounding tissue. Similar responses occur when the body initiates an allergic foreign body response. In the case of an allergic foreign body response, the implant would have to be removed.[34]
Failures
editThe many examples of implant failure include rupture of silicone breast implants, hip replacement joints, and artificial heart valves, such as the Bjork–Shiley valve, all of which have caused FDA intervention. The consequences of implant failure depend on the nature of the implant and its position in the body. Thus, heart valve failure is likely to threaten the life of the individual, while breast implant or hip joint failure is less likely to be life-threatening.[1][34][35]
Devices implanted directly in the grey matter of the brain produce the highest quality signals, but are prone to scar-tissue build-up, causing the signal to become weaker, or even non-existent, as the body reacts to a foreign object in the brain.[36]
In 2018, Implant files, an investigation made by ICIJ revealed that medical devices that are unsafe and have not been adequately tested were implanted in patients' bodies. In United Kingdom, Prof Derek Alderson, president of the Royal College of Surgeons, concludes: "All implantable devices should be registered and tracked to monitor efficacy and patient safety in the long-term."[37]
See also
editReferences
edit- ^ a b c d e f g h Wong, J.Y.; Bronzino, J.D.; Peterson, D.R., eds. (2012). Biomaterials: Principles and Practices. Boca Raton, Florida: CRC Press. p. 281. ISBN 9781439872512. Retrieved 12 March 2016.
- ^ "Medical Devices". American Elements. Retrieved 20 December 2023.
- ^ a b c d e f g "Download Product Code Classification Files". FDA.org/medicaldevices. Food and Drug Administration. 4 November 2014. Retrieved 12 March 2016.
Relevant info in the foiclass.zip file.
- ^ a b c d e f McLatchie, G.; Borley, N.; Chikwe, J., eds. (2013). Oxford Handbook of Clinical Surgery. Oxford, UK: OUP Oxford. p. 794. ISBN 9780199699476. Retrieved 12 March 2016.
- ^ Thomas, Daniel; Singh, Deepti (June 2017). "3D printing in surgery - The evolving paradigm-shift in surgical implants on demand". International Journal of Surgery (London, England). 42: 58–59. doi:10.1016/j.ijsu.2017.04.027. ISSN 1743-9159. PMID 28435025.
- ^ Ibrahim, H.; Esfahani, S. N.; Poorganji, B.; Dean, D.; Elahinia, M. (January 2017). "Resorbable bone fixation alloys, forming, and post-fabrication treatments". Materials Science and Engineering: C. 70 (1): 870–888. doi:10.1016/j.msec.2016.09.069. PMID 27770965.
- ^ Nowosielski R., Cesarz-Andraczke K., Sakiewicz P., Maciej A., Jakóbik-Kolon A., Babilas R., Corrosion of biocompatible Mg66+XZn30-XCa4 (X=0.2) bulk metallic glasses, Arch. Metall. Mater. 2016 vol. 61 iss. 2, s. 807-810
- ^ Ritabh, Kumar; Richard, A Lerski; Stephen, Gandy; Benedict, A Clift; Rami, J Abboud (12 July 2006). "Safety of orthopedic implants in magnetic resonance imaging: An experimental verification". Journal of Orthopaedic Research. 24 (9): 1799–1802. doi:10.1002/jor.20213. PMID 16838376. S2CID 2991113.
- ^ David, X Feng; Joseph, P McCauley (9 November 2015). "Evaluation of 39 medical implants at 7.0 T". British Journal of Radiology. 88 (1056): 20150633. doi:10.1259/bjr.20150633. PMC 4984944. PMID 26481696.
- ^ "With Bioelectronic Medicine, SetPoint Medical Wants To Revolutionize Autoimmune Disease Treatment". Forbes Magazine. 29 March 2019. Retrieved 19 November 2019.
- ^ "Arthritis sufferers offered hope after electrical implants leave". The Independent. 23 December 2014. Retrieved 1 February 2019.
- ^ Peeples, Lynne (3 December 2019). "Core Concept: The rise of bioelectric medicine sparks interest among researchers, patients, and industry". Proceedings of the National Academy of Sciences. 116 (49): 24379–24382. doi:10.1073/pnas.1919040116. PMC 6900593. PMID 31796581.
- ^ "New arthritis implant hailed as 'magic'". The Guardian. Press Association. 23 December 2014. ISSN 0261-3077. Retrieved 1 February 2019.
- ^ Duke, J.; Barhan, S. (2007). "Chapter 27: Modern Concepts in Intrauterine Devices". In Falcone, T.; Hurd, W. (eds.). Clinical Reproductive Medicine and Surgery. Elsevier Health Sciences. pp. 405–416. ISBN 9780323076593. Retrieved 12 March 2016.
- ^ "Upper G.I. Surgery - Gastroesophageal Reflux Disease (GERD)". Keck School of Medicine of USC. Archived from the original on 9 May 2018. Retrieved 12 March 2016.
- ^ "Gastric Electrical Stimulation". The Regents of The University of California. Archived from the original on 30 July 2019. Retrieved 12 March 2016.
- ^ "Chapter 1, Part 2, Section 160.19: Phrenic Nerve Stimulator" (PDF). Medicare National Coverage Determinations Manual. Centers for Medicare and Medicaid Services. 27 March 2015. Retrieved 19 February 2016.
- ^ Simmons M, Montague D (2008). "Penile prosthesis implantation: past, present, and future". International Journal of Impotence Research. 20 (5): 437–444. doi:10.1038/ijir.2008.11. PMID 18385678. S2CID 35545391.
- ^ Hjort, H; Mathisen, T; Alves, A; Clermont, G; Boutrand, JP (April 2012). "Three-year results from a preclinical implantation study of a long-term resorbable surgical mesh with time-dependent mechanical characteristics". Hernia. 16 (2): 191–7. doi:10.1007/s10029-011-0885-y. PMC 3895198. PMID 21972049.
- ^ Syring, G. (6 May 2003). "Overview: FDA Regulation of Medical Devices". Quality and Regulatory Associates, LLC. Retrieved 12 March 2016.
- ^ "Classify Your Medical Device". FDA.gov/MedicalDevices. Food and Drug Administration. 29 July 2014. Retrieved 12 March 2016.
- ^ Gotman, I. (December 1997). "Characteristics of metals used in implants". Journal of Endourology. 11 (6): 383–389. doi:10.1089/end.1997.11.383. PMID 9440845.
- ^ van den Brink, Wimar; Lamerigts, Nancy (26 November 2020). "Complete Osseointegration of a Retrieved 3-D Printed Porous Titanium Cervical Cage". Frontiers in Surgery. 7: 526020. doi:10.3389/fsurg.2020.526020. ISSN 2296-875X. PMC 7732662. PMID 33330602.
- ^ a b Spoerke, Erik D.; Murray, Naomi G.; Li, Huanlong; Brinson, L. Catherine; Dunand, David C.; Stupp, Samuel I. (September 2005). "A bioactive titanium foam scaffold for bone repair". Acta Biomaterialia. 1 (5): 523–533. doi:10.1016/j.actbio.2005.04.005. ISSN 1742-7061. PMID 16701832.
- ^ Kováčik, J. (1 July 1999). "Correlation between Young's modulus and porosity in porous materials". Journal of Materials Science Letters. 18 (13): 1007–1010. doi:10.1023/A:1006669914946. ISSN 1573-4811. S2CID 134497468.
- ^ Morrissey, Liam S.; Nakhla, Sam (24 April 2018). "A Finite Element Model to Predict the Effect of Porosity on Elastic Modulus in Low-Porosity Materials". Metallurgical and Materials Transactions A. 49 (7): 2622–2630. Bibcode:2018MMTA...49.2622M. doi:10.1007/s11661-018-4623-2. hdl:10315/35416. ISSN 1073-5623. S2CID 140090946.
- ^ COBLE, R. L.; KINGERY, W. D. (November 1956). "Effect of Porosity on Physical Properties of Sintered Alumina". Journal of the American Ceramic Society. 39 (11): 377–385. doi:10.1111/j.1151-2916.1956.tb15608.x. ISSN 0002-7820.
- ^ Fernandes, Matheus C.; Aizenberg, Joanna; Weaver, James C.; Bertoldi, Katia (February 2021). "Mechanically robust lattices inspired by deep-sea glass sponges". Nature Materials. 20 (2): 237–241. Bibcode:2021NatMa..20..237F. doi:10.1038/s41563-020-0798-1. ISSN 1476-4660. PMID 32958878. S2CID 221824575.
- ^ Egan, Paul F.; Gonella, Veronica C.; Engensperger, Max; Ferguson, Stephen J.; Shea, Kristina (10 August 2017). "Computationally designed lattices with tuned properties for tissue engineering using 3D printing". PLOS ONE. 12 (8): e0182902. Bibcode:2017PLoSO..1282902E. doi:10.1371/journal.pone.0182902. ISSN 1932-6203. PMC 5552288. PMID 28797066.
- ^ Ibrahim, Mahmoud Z.; Sarhan, Ahmed A.D.; Yusuf, Farazila; Hamdi, M. (August 2017). "Biomedical materials and techniques to improve the tribological, mechanical and biomedical properties of orthopedic implants – A review article". Journal of Alloys and Compounds. 714: 636–667. doi:10.1016/j.jallcom.2017.04.231. ISSN 0925-8388.
- ^ Carpenter, R. Dana; Klosterhoff, Brett S.; Torstrick, F. Brennan; Foley, Kevin T.; Burkus, J. Kenneth; Lee, Christopher S.D.; Gall, Ken; Guldberg, Robert E.; Safranski, David L. (April 2018). "Effect of porous orthopaedic implant material and structure on load sharing with simulated bone ingrowth: A finite element analysis comparing titanium and PEEK". Journal of the Mechanical Behavior of Biomedical Materials. 80: 68–76. doi:10.1016/j.jmbbm.2018.01.017. ISSN 1751-6161. PMC 7603939. PMID 29414477.
- ^ Apostu, Dragos; Lucaciu, Ondine; Berce, Cristian; Lucaciu, Dan; Cosma, Dan (3 November 2017). "Current methods of preventing aseptic loosening and improving osseointegration of titanium implants in cementless total hip arthroplasty: a review". Journal of International Medical Research. 46 (6): 2104–2119. doi:10.1177/0300060517732697. ISSN 0300-0605. PMC 6023061. PMID 29098919.
- ^ a b Black, J. (2006). Biological Performance of Materials: Fundamentals of Biocompatibility. Boca Raton, Florida: CRC Press. p. 520. ISBN 9780849339592. Retrieved 12 March 2016.
- ^ a b Dee, K.C.; Puleo, D.A.; Bizios, R. (2002). An Introduction to Tissue-Biomaterial Interactions. Hoboken, NJ: Wiley-Liss. p. 248. ISBN 9780471461128. Retrieved 12 March 2016.
- ^ Wagenberg, B.; Froum, S.J. (2006). "A retrospective study of 1925 consecutively placed immediate implants from 1988 to 2004". The International Journal of Oral & Maxillofacial Implants. 21 (1): 71–80. PMID 16519184.
- ^ Polikov, Vadim S.; Patrick A. Tresco & William M. Reichert (2005). "Response of brain tissue to chronically implanted neural electrodes". Journal of Neuroscience Methods. 148 (1): 1–18. doi:10.1016/j.jneumeth.2005.08.015. PMID 16198003. S2CID 11248506.
- ^ "Patients given unsafe medical implants". BBC. 25 November 2018. Retrieved 5 February 2019.
External links
edit- AAOMS - Dental Implant Surgery
- ACOG - IUDs and Birth Control Implants: Resource Overview
- FDA - Implants and Prosthetics
- International Medical Devices Database – Recalls, Safety Alerts and Field Safety Notices of medical devices – International Consortium of Investigative Journalists
- Implant-Register