Fact-checked by Grok 2 weeks ago

Artificial organ

An artificial organ is a human-engineered or tissue construct designed to replace a natural 's anatomical structure, physiological function, or both, either temporarily or permanently, in cases of organ failure or damage. These interface with living to perform essential bodily functions, such as , pumping, or oxygenation, and can be classified into (using non-biological materials like polymers and metals), biomechanical (incorporating living cells with synthetic scaffolds), or fully biological (tissue-engineered constructs). The development of artificial organs traces back to early 20th-century innovations, with Dutch physician Willem J. Kolff pioneering the field by inventing the first practical hemodialysis machine in 1943, which revolutionized treatment for by externally filtering blood. In the and , Kolff and his team advanced cardiac replacement technologies, creating early and the in 1961 to support heart function during surgery. A landmark achievement occurred in 1982 when the first permanent , the Jarvik-7, was implanted in patient Barney Clark at the , sustaining life for 112 days despite complications. These efforts laid the foundation for modern organ replacement, shifting from rudimentary pumps to sophisticated implants that bridge the gap until transplantation. Artificial organs encompass a range of examples tailored to specific organ failures, including the machine for kidneys, which removes waste from via and , serving millions worldwide as a life-sustaining . For the heart, ventricular assist devices (VADs) like the HeartMate series mechanically support circulation in end-stage patients, often as a bridge to transplant or destination . Other notable types include systems, such as closed-loop insulin pumps that automate glucose monitoring and delivery for , and extracorporeal membrane oxygenators (ECMO) that temporarily replace lung and heart functions during critical illness. Emerging bioartificial constructs, like tissue-engineered bladders and tracheas, integrate patient-derived cells onto scaffolds to promote regeneration. Today, artificial organs address the global organ shortage, with over 103,000 patients awaiting transplants in the U.S. as of 2025, but challenges persist in , long-term durability, and ethical considerations like access equity. Advances in and stem cell integration promise fully functional bioartificial organs, such as engineered livers for drug testing and potential implantation, though most remain in clinical trials. Ongoing research focuses on reducing rejection risks and improving integration with the body's to make these technologies more viable alternatives to donation-dependent transplantation.

Overview and Purpose

Definition and Classification

An artificial organ is a man-made or engineered designed to mimic, replace, or supplement the biological function of a natural organ in the . These include implants such as pumps or filters, bioartificial hybrids that combine synthetic materials with living cells, and fully synthetic replacements that perform organ-specific tasks without biological components. Artificial organs are classified in multiple ways based on their design, function, and intended use. One key distinction is between total artificial organs, which fully replace the failing organ—such as a total that assumes complete cardiac function—and partial artificial organs, which assist or supplement organ activity, like machines that perform filtration externally. Another classification divides them by duration: temporary devices, often used as bridges to recovery or transplantation, versus permanent implants intended for long-term replacement. By composition, they fall into mechanical (fully synthetic, non-living components), biomechanical (hybrid structures with some integration), and biological (cell-based or tissue-engineered constructs). Functionally, they can be passive, providing structural support like vascular grafts that maintain blood flow without active motion, or active, performing dynamic processes such as pumping in artificial hearts or filtering in systems. Unlike , which are external devices like braces or shoe inserts that support or align existing musculoskeletal structures without replacing organs, artificial organs are typically implanted internally to interface directly with living tissues and restore vital physiological functions. They also differ from organ transplants, which involve surgically transferring biological organs or tissues from donors, as artificial organs rely on engineered alternatives to avoid donor shortages and compatibility issues. The term "artificial organ" first appeared prominently in during the , coinciding with pioneering work on heart pumps and the establishment of dedicated programs, such as those led by J. Kolff, often called the father of artificial organs for his earlier of the machine.

Medical Applications and Benefits

Artificial organs primarily address organ failure by serving as bridges to transplantation, providing temporary support to stabilize patients until a donor organ becomes available. For example, mechanical circulatory support devices, such as ventricular assist devices, maintain cardiac function in patients with advanced heart failure, improving survival rates during the waiting period. These applications are critical given the global organ shortage, with over 108,000 individuals on the U.S. national transplant waiting list as of November 2025, the majority awaiting kidneys. In addition to bridging, artificial organs offer permanent replacement for end-stage organ failure, exemplified by hemodialysis systems that filter blood in place of nonfunctional kidneys, and augmentation for chronic diseases, such as implantable insulin pumps that regulate glucose levels in type 1 diabetes patients. The benefits of artificial organs include significant extensions in lifespan and enhancements in . , for instance, enables many patients to survive 5 to 20 years or longer, with five-year survival rates reaching approximately 50% overall, compared to rapid fatality without . They also reduce dependency on scarce donor organs, potentially alleviating the burden of waiting lists where thousands die annually while awaiting transplants. Furthermore, devices like prosthetic limbs restore mobility for amputees affected by or trauma, allowing independent daily activities and reducing long-term . Clinical outcomes demonstrate the transformative impact of artificial organs on patients. Cochlear implants, used for severe hearing loss, achieve device functionality success rates exceeding 95%, with 80-90% of recipients experiencing substantial improvements in and auditory function. Similarly, retinal prostheses for advanced have restored partial vision in trials, where 80% of participants gained clinically meaningful improvements in after one year, enabling tasks such as reading or recognizing faces. These general patient outcomes underscore how artificial organs not only prolong life but also reinstate sensory and functional , markedly elevating overall .

Historical Development

Early Concepts and Innovations (Pre-20th Century)

The earliest known attempts at prosthetic devices date back to ancient civilizations, where rudimentary replacements addressed limb loss for both functional and possibly cosmetic purposes. In , around 950 BCE, a wooden prosthetic crafted from wood and was created for a female mummy discovered near , demonstrating early biomechanical consideration as it allowed the wearer to walk effectively by mimicking the big toe's role in . This artifact, dated to the New Kingdom period (c. 1550–1069 BCE), represents one of the oldest functional prosthetics, predating similar devices by millennia and highlighting ancient Egyptian ingenuity in addressing physical impairments. In the Roman era, beginning as early as the BCE, priests and craftsmen produced the first ocular prostheses to replace absent eyes following enucleation or , primarily using painted clay to fit within the eye and provide a semblance of normal appearance. These early eye prosthetics, often simple shells rather than fully mobile devices, served mainly cosmetic roles but marked an initial shift toward restoring facial integrity after . During the medieval period, prosthetics evolved modestly, with iron limbs used by armored knights to conceal amputations and maintain , though these were more protective than restorative. The brought significant advancements through the work of French surgeon (1510–1590), widely regarded as the father of modern prosthetics for his innovations in mechanical limb design. Paré developed upper-limb prostheses, such as the "Le Petit Lorrain" iron hand operated by springs and catches, which allowed users to grip objects and was notably worn by a captain in battle. He also pioneered lower-limb prostheses with articulated joints, emphasizing functionality over mere replacement, and documented these in his 1579 treatise Les Oeuvres, influencing subsequent prosthetic development. Paré's designs, born from his battlefield experience treating war wounds, represented a conceptual pivot from passive cosmetic aids to active, mechanical supports that enhanced daily activities. Early experiments in , a precursor to artificial circulatory support, emerged in the amid growing understanding of blood circulation following William Harvey's 1628 discoveries. In , French physician Jean-Baptiste Denis performed the first recorded human , injecting lamb's blood into a young patient to treat fever, though the procedure led to complications and was soon banned due to ethical and medical concerns. These attempts, also conducted in by surgeons like Guglielmo Riva and Paolo Manfredi between 1667 and 1668, explored interspecies transfers but highlighted risks like incompatibility, halting progress until the . By the 18th and 19th centuries, prosthetics advanced toward more practical designs, particularly for amputees, with mechanical hands, peg legs, and hooks becoming standard. Peg legs, simple wooden posts strapped to the stump, had been used since the Middle Ages but proliferated in the 19th century for their affordability and stability in walking. Hand hooks, functional grippers made of metal, offered basic utility for tasks like holding tools, evolving from Paré's mechanisms into lighter, more accessible forms. The American Civil War (1861–1865) catalyzed this shift, with over 50,000 amputations creating demand for government-provided prosthetics that prioritized functionality to reintegrate veterans into society. Influenced by industrial manufacturing, these devices transitioned from elite, ornamental replacements to widespread, utilitarian aids, laying groundwork for later artificial organ concepts by emphasizing restoration of bodily functions amid wartime necessities.

20th Century Milestones

The development of artificial organs in the marked a shift from experimental concepts to practical medical devices, driven by advances in engineering and clinical needs during wartime and postwar eras. In the early , pioneering work on cardiac pacemakers laid foundational groundwork for electrical interventions in organ function. anesthesiologist Mark C. Lidwell and physician Albert M. Hyman independently developed the first external cardiac pacing devices in the late , using needle electrodes to deliver electrical stimuli to the heart in cases of or . These rudimentary machines, powered by hand-cranked or battery-operated mechanisms, demonstrated the feasibility of artificial rhythm regulation but were limited to short-term, emergency use due to their invasive and imprecise nature. By the 1940s, efforts to replicate kidney function advanced significantly amid shortages and medical urgencies. Dutch physician Willem J. Kolff constructed the first practical , or machine, in 1943 while working in occupied . Using tubing from sausage casings wrapped around a rotating drum and a solution of saline and , Kolff's device successfully removed waste from the blood of a comatose patient, marking the debut of as a life-sustaining for acute . This innovation, refined post-war, enabled repeated treatments and established as a bridge to recovery or transplantation, saving countless lives despite initial low success rates. Mid-century breakthroughs in the 1950s revolutionized cardiovascular surgery by enabling operations on a still, bloodless heart. American surgeon John H. Gibbon Jr. invented the first successful heart-lung machine in the early 1950s, a pump-oxygenator system that temporarily took over the heart's and lungs' functions during procedures. On May 6, 1953, Gibbon performed the world's first open-heart surgery using this device to repair an in an 18-month-old patient, who survived the operation. Subsequent improvements, such as those by surgeons in the mid-1950s, incorporated disposable components and better oxygenation, facilitating widespread adoption for congenital defect repairs and valve surgeries. The late 20th century saw implantable devices gain traction, with the introducing insulin pumps as analogs for pancreatic beta-cell function in . The first wearable insulin infusion pumps emerged around 1974, developed by teams including Danish engineer Knud Hermansen, delivering continuous subcutaneous insulin to mimic physiological secretion patterns. These battery-powered devices, such as the early Auto-Syringe model, allowed programmable basal rates and bolus doses, reducing hypoglycemic risks compared to multiple daily injections and improving glycemic control in clinical trials. By the decade's end, pumps like the Infuser had demonstrated long-term feasibility, paving the way for portable, patient-controlled . Cochlear implants, aimed at restoring auditory function, progressed from 1960s experiments to regulatory milestones in the 1980s. French physician André Djourno and researcher Claude Eyriès conducted the first human trials in 1957, but sustained development accelerated in the 1960s with American otologist implanting single-electrode prototypes to stimulate the auditory nerve directly. Facing initial skepticism over safety and efficacy, multi-channel designs evolved, leading to FDA approval of the / single-channel for adults in 1984—the first such device to receive clearance for profound deafness treatment. This approval followed rigorous trials showing improved in post-lingually deafened patients, though pediatric use awaited further validation into the . A pivotal milestone in cardiac replacement came in 1982 with the Jarvik-7 total artificial heart, designed by biomedical engineer under Willem Kolff's guidance at the . On December 2, 1982, surgeon William C. DeVries implanted the Jarvik-7 into Barney , the first permanent human recipient, after FDA investigational approval of the procedure earlier that year. Powered externally by compressed air via drivelines, the device fully replaced Clark's failing ventricles, sustaining him for 112 days until complications led to his death—establishing proof-of-concept for mechanical hearts as bridges to transplantation despite ethical and technical challenges. Subsequent implants in the refined the , with FDA approvals for similar ventricular assist devices following in the late decade, underscoring regulatory evolution for high-risk implants.

21st Century Advances

The has marked a shift toward bioengineered and artificial organs, integrating with mechanical devices to improve and functionality. In the 2000s and , bioartificial organs emerged as a key advancement, exemplified by the use of decellularized scaffolds to create -specific implants. A landmark event was the 2008 implantation of the world's first trachea in a with tracheal , where a decellularized donor trachea scaffold was reseeded with the recipient's autologous epithelial and mesenchymal stem cells, enabling successful integration without . This approach addressed previous limitations of synthetic tracheas by preserving the for natural recellularization. During the same period, prototypes gained traction for fabricating complex structures, with early demonstrations in the producing vascularized tissue models using bioinks composed of cells and hydrogels to mimic architecture. The 2020s have seen accelerated clinical translation, particularly for respiratory and urinary systems. The Organ Care System (OCS) Lung received FDA approval in 2019 following pivotal clinical trials, enabling ex vivo perfusion to assess and preserve donor lungs for transplantation, with studies showing improved graft utilization rates compared to traditional cold storage. For urinary applications, lab-grown bladders using bone marrow-derived cells seeded on biodegradable scaffolds have advanced to ongoing preclinical and early clinical trials as of 2024, demonstrating functional regeneration in animal models with restored bladder capacity and compliance over extended periods. These developments build on decellularization techniques to create fully biological implants, reducing rejection risks. Key milestones include the 2019 achievement of the first functional 3D-printed liver tissue using sacrificial bioinks to form perfusable vascular networks, which supported viability and metabolic activity , paving the way for scalable production. In , AI-optimized prosthetics incorporated algorithms to predict user intent from electromyographic signals, enhancing adaptive control and reducing energy consumption in upper-limb devices. The COVID-19 pandemic from 2020 to 2022 drove refinements in extracorporeal membrane oxygenation (ECMO) systems, with veno-venous ECMO survival rates improving from 49.4% in 2020 to 63% by 2022 due to optimizations like prone positioning and anticoagulation adjustments. As of 2025, over 100,000 left ventricular assist devices (LVADs)—a primary form of artificial heart support—have been implanted worldwide since their clinical introduction, reflecting widespread adoption as bridge-to-transplant or destination therapy options. Long-term success rates for these devices have risen to approximately 80% one-year survival, attributed to advancements in pump design and antithrombotic management that minimize complications like and .

Technologies and Materials

Biocompatible Materials

Biocompatible materials form the foundation of artificial organs, enabling seamless integration with the by minimizing adverse reactions such as or . These materials must exhibit properties like mechanical strength, flexibility, and to mimic natural tissues while supporting long-term functionality. Common categories include polymers, metals, and ceramics, each selected based on the organ's specific demands, such as durability in high-stress environments or softness for delicate tissues. Polymers are widely used due to their versatility and ease of fabrication into complex shapes. For instance, silicone-based polymers are employed in valves for their , tunable mechanical properties, and resistance to , allowing them to withstand millions of cycles without degradation. Similarly, materials are integral to artificial lungs, providing flexible, non-thrombogenic surfaces that reduce clotting risks and support efficiency. These polymers are prized for their low density, elasticity, and sterilizability via methods like gamma , ensuring they can be safely implanted or used in devices. Metals, particularly and its alloys, offer exceptional strength and corrosion resistance, making them suitable for load-bearing components in artificial organs like ventricular assist devices or bone-integrated implants. Titanium's passive oxide layer prevents ion release, enhancing long-term biocompatibility and reducing inflammatory responses. Ceramics, such as and alumina, are bioinert or bioactive alternatives ideal for skeletal or replacements within artificial organ systems, promoting without eliciting immune rejection. These materials must be non-thrombogenic to avoid when in contact with , flexible to accommodate physiological movements, and capable of repeated sterilization to prevent infections. Advancements in the introduced hydrogels as biocompatible scaffolds for artificial organs, leveraging their high water content and similarity to extracellular matrices to support and nutrient diffusion. These materials, often derived from natural polymers like or synthetic ones like , enable applications with minimal immune activation. In the 2020s, such as silver nanoparticles and two-dimensional structures have been incorporated to further reduce around implants, enhancing hemocompatibility and promoting faster healing in artificial organ interfaces. As of 2025, albumin-functionalized biomaterials and bioinspired designs have emerged to further improve hemocompatibility and integration in artificial organ applications. Biocompatibility is rigorously evaluated using standards, which outline tests for , , and to ensure materials do not cause harmful biological responses in artificial organ applications. For bioresorbable polymers, such as polyglycolic acid used in temporary scaffolds, degradation rates are controlled to occur over 2-4 months via , allowing gradual replacement by native without compromising structural integrity. These evaluations prioritize materials that maintain functionality while degrading predictably, as seen in poly(dioxanone) variants that lose mass completely within this timeframe.

Engineering Techniques (Including Tissue Engineering and Bioprinting)

Engineering techniques for artificial organs encompass a range of methods to fabricate functional replacements, from purely mechanical assemblies to biologically inspired constructs that integrate living cells. These approaches aim to replicate the organ's and , often combining precision manufacturing with biological components to achieve and . Mechanical techniques focus on durable, non-biological components, while and bioprinting incorporate cellular elements for regenerative potential. Hybrid methods bridge these paradigms by merging nanoscale fabrication with microfluidic testing platforms. Mechanical techniques primarily involve machining and assembly to create robust, pump-based systems for organs like the heart. Centrifugal pumps, a cornerstone of ventricular assist devices, use impellers to generate blood flow through rotational forces, with precision-machined titanium surfaces to minimize thrombosis. For instance, the HeartMate III device employs fully magnetic levitation for its rotor, assembled with integrated motors and levitation coils to enable continuous flow up to 10 liters per minute without mechanical bearings. Electronics integration enhances functionality, as seen in pacemakers where microprocessors, sensors on pacing leads, and lithium batteries monitor heart rhythm and deliver electrical pulses to regulate beating, with leads acting as both conductors and activity detectors. These assemblies ensure reliable operation but require sterile manufacturing to prevent infections. Tissue engineering utilizes scaffolds to guide cell growth into organ-like structures, emphasizing to create biocompatible templates. The process removes cellular components from donor organs using detergents like or physical methods such as freeze-thaw cycles, preserving the (ECM) architecture while eliminating . Resulting acellular scaffolds, with less than 50 ng double-stranded DNA per mg dry weight, are then seeded with patient-derived cells—such as induced pluripotent stem cells (iPSCs)—via or injection to repopulate the matrix. Examples include decellularized rat hearts reseeded with cardiomyocytes to restore partial contractility, and lung scaffolds repopulated with iPSC-derived epithelial cells to support alveolar function. This approach leverages the native ECM's biochemical cues to promote tissue integration and vascularization. Bioprinting advances these scaffolds through layer-by-layer deposition of bioinks—mixtures of cells suspended in hydrogels like or —to fabricate complex, vascularized constructs. Multi-material printers, utilizing or light-based techniques, enable precise patterning of components and endothelial cells to form perfusable networks. Recent 2024 developments in bioprinting achieve vascular diameters as small as 100-200 μm, supporting microvasculature for delivery in thicker tissues. For example, -based scaffolds printed with 20 μm incorporate internal channels (~100 μm) that, when perfused, foster capillary-like structures lined with CD31+ endothelial cells, demonstrating improved cell viability and organization. These methods address vascularization challenges by embedding sacrificial inks that dissolve to create hollow lumens. Hybrid approaches combine and biological fabrication, such as to produce nanofibers that mimic the ECM's nanoscale topology for enhanced . techniques, including coaxial and blend methods, generate core-shell nanofibers from polymers like PCL and , achieving high (up to 80%) and surface area for applications in vascular grafts that exhibit native-like over months. Organ-on-chip models, developed prominently in the , integrate these nanofibers with microfluidic channels to test tissue responses under physiological flows, such as in lung-on-chip devices using membranes (3-8 μm thick) to simulate air-liquid interfaces and . These platforms validate constructs before implantation, accelerating .

Examples of Artificial Organs

Cardiovascular Systems (Heart and Blood Vessels)

Artificial hearts and ventricular assist devices represent critical advancements in replacing or supporting cardiovascular functions, particularly for patients with end-stage . Total artificial hearts (TAHs), such as the SynCardia Total Artificial Heart, fully replace the native heart's ventricles and are primarily used as a bridge to transplantation. Approved by the FDA in 2004 and evolved from earlier designs like the Jarvik-7, the SynCardia device became portable with the introduction of the Freedom Driver in 2010, allowing patients greater mobility outside the hospital. In contrast, left ventricular assist devices (LVADs), such as the HeartMate 3, assist the native heart by supporting the left ventricle's pumping action without complete replacement; these are used either as bridges to transplant or destination for non-transplant candidates. LVADs have demonstrated one-year rates of approximately 85% in clinical use. Synthetic grafts have long provided durable replacements for damaged blood vessels, particularly in the . Dacron () grafts, introduced in the 1950s by pioneers like , remain the standard for aortic aneurysms and occlusive disease due to their strength and . These woven or knitted tubes mimic vascular compliance and integrate with host over time, enabling long-term patency in large-diameter vessels. More recently, tissue-engineered blood vessels (TEBVs) have emerged in the 2020s, incorporating endothelial cell linings to reduce and promote natural remodeling; clinical trials have shown promising results in pediatric congenital heart defects and , with seeded endothelial cells enhancing graft functionality. These devices primarily mimic the heart's essential functions of systemic and pulmonary circulation, delivering oxygenated at rates comparable to a resting heart of 60-80 beats per minute () to maintain of 4-6 liters per minute. While TAHs like SynCardia provide biventricular support for full circulation and oxygenation, LVADs focus on left-sided assistance, often paired with medications for right ventricular function. Power sources for portable systems, including lithium-ion batteries in the SynCardia Freedom Driver and LVAD controllers, typically last 4-6 hours before recharging, enabling outpatient management but requiring vigilant battery monitoring. Materials such as in LVAD pumps contribute to hemocompatibility and durability. By 2025, over 100,000 LVAD implants have been performed worldwide, reflecting widespread adoption for advanced management. However, complications persist, with rates ranging from 10-15% in the first year post-implantation, often due to or from anticoagulation needs. These outcomes underscore the devices' life-extending potential while highlighting ongoing needs for refined strategies.

Respiratory and Urinary Systems (Lungs and Kidneys)

Artificial lungs primarily function through extracorporeal membrane oxygenation (ECMO) systems, which were first clinically implemented in the 1970s to provide temporary respiratory support by oxygenating blood outside the body. These devices circulate blood through an external oxygenator that facilitates gas exchange, mimicking the lungs' role in adding oxygen and removing carbon dioxide. Portable ECMO variants emerged in the 2020s, enabling patient mobility and reducing hospital dependency during treatment. In severe acute respiratory distress syndrome (ARDS) cases, ECMO supports patients with survival-to-recovery rates of approximately 50-60% in severe cases, based on recent meta-analyses. ECMO systems typically achieve rates of 300-500 mL/min, comparable to partial native capacity, through across semipermeable . While primarily , research into implantable artificial lungs has advanced, with preclinical prototypes like the BioLung, which has shown promise in animal models for partial support. Artificial kidneys, exemplified by machines developed in the 1940s, serve as the cornerstone for by filtering blood to remove waste and excess fluids. Standard involves three sessions per week, each processing around 200 liters of blood to clear uremic toxins via and across a dialyzer . These sessions replicate the kidneys' natural , which normally eliminates 1-2 liters of waste daily, including and electrolytes. Advancements in wearable artificial kidneys have progressed to clinical trials by 2024, offering continuous ambulatory filtration to improve over intermittent . As of 2025, pivotal clinical trials for devices like the WAK3 are underway, aiming for continuous ambulatory . Early concepts of trace back to 20th-century innovations in . Emerging bioengineered scaffolds, informed by techniques, aim to support regenerative implants. Globally, and related therapies sustain over 2 million patients as of 2025, with estimates ranging from 2 to 3 million depending on the source, preventing uremic complications and extending in end-stage renal disease. For artificial lung applications, such devices have enabled recovery in roughly 50% of bridged patients, particularly in acute settings like COVID-19-related ARDS.

Digestive and Endocrine Systems (Liver and Pancreas)

Artificial organs targeting the digestive and endocrine systems primarily focus on supporting liver and pancreatic functions, which are essential for metabolic processing and regulation. The liver performs critical and synthetic roles, while the pancreas maintains glucose through insulin secretion. Bioartificial approaches for these organs often involve devices that bridge patients to recovery or transplantation, leveraging cellular therapies to mimic native organ capabilities.

Artificial Liver

The liver processes approximately 1.5 liters of per minute, filtering toxins and metabolizing nutrients to sustain bodily . In , this capacity is compromised, leading to accumulation of harmful substances like and . bioartificial liver (BAL) devices address this by temporarily performing and synthetic functions outside the body, using bioreactors containing viable hepatocytes to treat patient or . Prominent examples include the Extracorporeal Liver Assist Device (), which utilizes human-derived C3A cell lines in a system for . Clinical trials in the , such as a randomized controlled study in patients with acute-on-chronic , demonstrated ELAD's ability to reduce total by 25% during 3–5 days of treatment, compared to a 37% increase in controls. Some BAL systems incorporate porcine hepatocytes to enhance , as seen in devices like the Academic Medical Center BAL, where pig liver cells effectively lower and levels in preclinical models. For instance, a porcine acute model treated with a BAL using induced hepatocytes (adapted for xenogeneic parallels) corrected blood and , reducing and supporting regeneration. Progress in liver support has shown meaningful survival benefits in acute failure cases. In the aforementioned ELAD trial, transplant-free survival at day 28 reached 81.2% in the treatment group versus 47.1% in controls, representing approximately a 30% relative improvement. As of 2025, systematic reviews indicate that bioartificial systems continue to extend survival in select subgroups, such as fulminant hepatic failure, with risk reductions up to 44% compared to standard care, though broader efficacy requires further validation through ongoing trials.

Artificial Pancreas

The regulates blood glucose levels, maintaining them within a target range of 70–140 mg/dL through insulin and release to prevent hypo- and . In , beta-cell destruction disrupts this balance, necessitating external systems for automated control. Closed-loop artificial pancreas systems integrate continuous glucose monitors (CGMs), insulin pumps, and control algorithms to mimic pancreatic function by adjusting insulin delivery in based on . A landmark example is the MiniMed 670G, approved in 2016 as the first hybrid closed-loop system. It employs a algorithm to automate basal insulin dosing, suspending delivery if glucose trends low and increasing it during rises, while users manually bolus for meals. Clinical trials showed it increased time in target range (70–180 mg/dL) to 72% during auto mode, reducing HbA1c by 0.3–0.5% without raising risk. Real-world use has confirmed sustained benefits, with average auto mode engagement at 81% and improved glycemic variability. By 2025, artificial pancreas efficacy in management has advanced, with automated systems achieving time in range exceeding 70% in meta-analyses of advanced closed-loop devices, compared to 60–65% with sensor-augmented pumps alone. Recent evaluations, including the iLet bionic pancreas, report up to 10% greater time in range versus , alongside reduced and enhanced , positioning these systems as standard care for many patients.

Sensory and Limb Prosthetics (Eyes, Ears, Limbs)

Sensory and limb prosthetics represent a critical subset of artificial organs, focusing on restoring perceptual and motor functions lost due to , , or congenital conditions. These devices interface directly with neural pathways to bypass damaged sensory organs or musculoskeletal structures, enabling partial recovery of , hearing, and . Advances in , biomaterials, and neural interfacing have driven progress, with implants providing functional benefits that enhance for users. Artificial eyes, particularly retinal prostheses, target vision restoration in conditions like where photoreceptors degenerate but inner retinal layers remain viable. The Argus II system, approved by the U.S. Food and Drug Administration in 2013, features a 60-electrode epiretinal array that stimulates surviving retinal cells via a camera-mounted external unit and implanted receiver. This device induces perceptions, allowing users to detect light, shapes, and motion at low resolution, equivalent to about 1-2% of normal coverage in optimal cases, with clinical trials showing 50% of subjects recognizing large letters and improved object localization in 93-96% of participants. Outcomes include enhanced orientation and mobility, though limitations persist in acuity and color perception. Artificial ears, exemplified by cochlear implants, restore hearing by electrically stimulating the auditory nerve, bypassing damaged hair cells in the . Developed in the 1970s through pioneering single-channel devices, modern multi-channel systems process sound externally and deliver patterned stimulation via an electrode array inserted into the scala tympani. By 2022, over 1 million such implants had been performed worldwide, with continued growth exceeding this figure by 2025, enabling sound perception in severe-to-profound . Approximately 82% of postlingual adult users achieve significant speech perception improvements, often reaching open-set sentence recognition in quiet environments. Limb prosthetics, particularly for upper extremities, have evolved from passive devices to active myoelectric systems that interpret electromyographic (EMG) signals from residual muscles to motorized components. Myoelectric arms, commercially available since the , use surface EMG sensors to detect muscle contractions and drive multi-joint movements, offering intuitive for tasks like grasping. In the 2020s, bionic hands have advanced to 19-20+ , mimicking dexterity with tendon-driven actuators and integrated sensors for tasks such as pinching or power gripping, as seen in lightweight biomimetic designs weighing under 0.4 kg. Neural interfaces further enhance ; for instance, 2024 DARPA-funded trials demonstrated peripheral for sensory and precise prosthetic in amputees, improving embodiment and reducing during use.

Reproductive and Immune Organs (Ovaries, Testes, Thymus)

Artificial ovaries and testes represent emerging bioprosthetic implants designed to restore fertility and hormone production in patients facing gonadal failure due to cancer treatments or other conditions. These devices typically employ decellularized scaffolds or 3D-printed structures seeded with immature germ cells or stem cells to mimic natural gamete production and endocrine functions. For instance, bioprosthetic ovaries constructed from gelatin-based microporous scaffolds housing ovarian follicles have demonstrated the ability to restore hormone levels and fertility in surgically sterilized mice, with implanted devices becoming vascularized and supporting ovulation leading to live offspring. Recent advances in the 2020s incorporate microfluidics for precise hormone delivery and nutrient flow, enabling sustained estradiol and progesterone release in vitro models that simulate ovarian dynamics. Similarly, for artificial testes, decellularized extracellular matrix scaffolds support spermatogonial stem cell engraftment and differentiation, facilitating in vitro spermatogenesis in rodent models through biomimetic niches that promote sperm production. These reproductive artificial organs aim to address by enabling , with animal studies reporting success rates of approximately 10-20% for live births or viable production per implantation cycle, depending on the model and scaffold design. In experiments with bioprinted ovarian scaffolds, implanted bioprosthetics have achieved full of ovarian , including follicle maturation and , highlighting their potential for translating to applications. For testes, systems using scaffolds have supported complete from stem cells, yielding functional capable of fertilization , though long-term viability remains under investigation. Microfluidic platforms integrated into these scaffolds enhance efficiency by controlling and oxygen gradients, which are critical for survival and maturation. Regarding immune organs, the artificial focuses on stem cell-derived implants to regenerate T-cell production and immune surveillance, particularly for patients with thymic or post-chemotherapy immune deficiency. These constructs utilize induced pluripotent stem cells (iPSCs) differentiated into thymic epithelial cells, assembled into organoids or scaffolds that support T-cell education and maturation. In preclinical models, iPSC-derived thymic organoids have generated functional T cells capable of immune reconstitution, with scaffolds promoting thymopoiesis by mimicking the native thymic microenvironment. educates approximately $10^8 new T cells daily to maintain adaptive immunity, a that artificial versions seek to replicate for restoring immune competence after lymphodepletion. Current status includes ongoing human trials for ovarian tissue-based bioprosthetics, particularly for fertility preservation in cancer patients via cryopreservation and scaffold-supported transplantation, with 2024 data showing successful hormone recovery and pregnancies in over 200 cases worldwide following . For the , stem cell-derived approaches are in early preclinical stages for post-chemotherapy reconstitution, but cultured thymus tissue implants have advanced to clinical use for , achieving T-cell reconstitution in up to 70% of infants through allogeneic scaffolds that educate donor stem cells into mature T cells. These developments build on techniques to integrate , offering hope for comprehensive reproductive and immune restoration without relying on donor gametes or lifelong .

Challenges and Limitations

Biocompatibility and Immune Response Issues

One of the primary challenges in the deployment of artificial organs is achieving , defined as the ability of the implant to perform its intended function without eliciting detrimental host responses. When artificial organs, whether fully synthetic or biohybrid constructs, are introduced into the body, they are recognized as foreign entities, triggering a cascade of that can lead to device failure or reduced functionality. These responses encompass both innate and adaptive immunity, often culminating in , encapsulation, or outright rejection. The immune response to artificial organs typically manifests in several forms, including acute rejection, rejection, and , particularly in devices interfacing with blood. Acute rejection occurs rapidly, often within days to weeks post-implantation, driven by T-cell and release as the targets perceived foreign antigens on the implant surface or incorporated cells. This can result in severe and graft dysfunction if untreated. rejection develops over months to years, characterized by progressive and vascular remodeling, where persistent low-level immune leads to formation that impairs organ performance. In blood-contacting artificial organs, such as ventricular assist devices or vascular grafts, represents a critical complication; the foreign surface activates platelets and the cascade, often exacerbated by immune-mediated , leading to clot formation and potential . Contributing factors to these immune responses include the and, in biohybrid artificial organs, (HLA) mismatches. The involves macrophage recruitment and fusion into giant cells, culminating in fibrous encapsulation of the implant to isolate it from surrounding tissues, which can compromise nutrient diffusion and mechanical integration. For bioartificial organs incorporating living cells, HLA matching between donor cells and recipient is crucial, as mismatches provoke T-cell and antibody-mediated attacks, mirroring natural allograft rejection dynamics. To mitigate these issues, strategies focus on pharmacological and modifications. Immunosuppressants like cyclosporine, a inhibitor, suppress T-cell proliferation and have been shown to reduce acute rejection rates in organ transplant recipients when combined with other agents. Surface coatings, such as heparin immobilization on implant materials, inhibit by enhancing activity and reducing platelet adhesion, thereby improving hemocompatibility in cardiovascular artificial organs. Despite these advances, first-year failure rates due to biocompatibility-related complications remain significant. Ongoing research emphasizes immunomodulatory biomaterials that actively reprogram immune cells to tolerate implants, potentially lowering these rates further.

Durability, Maintenance, and Long-term Viability

Artificial organs with mechanical components are susceptible to wear over time, particularly in moving parts such as and , which can lead to structural failure and the need for replacement. Bioprosthetic heart , commonly used in valve replacements, typically endure for 10 to 15 years before significant degeneration occurs, influenced by factors like age and valve position. In contrast, mechanical demonstrate greater longevity, often exceeding 20 years without structural issues, though they require lifelong anticoagulation to prevent . Portable ventricular assist devices (VADs), essential for bridging to transplant, depend on external packs that provide 8 to 12 hours of continuous operation, necessitating frequent recharging to avoid pump failure. Maintenance demands for artificial organs include regular surgical revisions to address device-related complications, with studies indicating that up to 26% of VAD patients require re-intervention within five years due to issues like or driveline problems. Telehealth-enabled home monitoring applications, increasingly adopted in the 2020s, facilitate remote tracking of device parameters and patient vitals, enabling early detection of malfunctions and reducing hospitalization rates. These tools integrate with wearable sensors to support outpatient management, particularly for VAD recipients. Long-term viability is hindered by infection risks and challenges in adapting to physiological changes, especially in growing patients. Post-implantation occur in 20% to 30% of VAD cases within the first year, often involving drivelines or pump sites, and contribute to higher morbidity. In pediatric applications, fixed-size implants fail to accommodate somatic growth, resulting in patient-prosthesis mismatch that frequently necessitates multiple revisions as the child develops. Advancements in are addressing these limitations, with 2024 research on self-healing polymers showing potential to enhance durability by enabling autonomous repair of micro-damage in implant components. These biomimetic materials, inspired by human tissue, could extend device lifespans and reduce revision frequency, though clinical translation remains ongoing.

Ethical and Societal Considerations

Access, Equity, and Regulatory Frameworks

Access to artificial organs remains a significant barrier due to their high development and implantation costs, which typically range from $150,000 to $500,000 USD for devices like left ventricular assist devices (LVADs). In the United States, has covered LVADs as destination therapy since 2003, expanding access for end-stage patients ineligible for transplants, though out-of-pocket expenses and follow-up care still pose challenges. However, in low-income countries, such technologies are often unavailable due to limited infrastructure and funding, resulting in stark global disparities where advanced organ replacement options are primarily confined to wealthier nations. Equity concerns further complicate adoption, with the majority of artificial organ implants occurring in high-income countries, where low- and middle-income nations account for only a fraction of procedures despite higher burdens of organ failure. Racial and ethnic biases in clinical trials exacerbate these issues, as underrepresented groups in study populations lead to algorithms and eligibility criteria that may inadvertently disadvantage minorities, perpetuating unequal outcomes in device approval and allocation. Regulatory frameworks aim to balance innovation with safety, classifying most artificial organs as Class III medical devices under the U.S. (FDA), requiring rigorous premarket approval () to demonstrate safety and effectiveness through clinical data, though some lower-risk variants may use the 510(k) pathway for substantial equivalence to existing devices. In the , the Medical Device Regulation (MDR) of 2017/745 imposes stricter standards since its full implementation in 2021, mandating enhanced clinical evidence, post-market surveillance, and oversight to ensure higher across member states. Global efforts to address these barriers include the World Health Organization's Guiding Principles on Human Cell, Tissue and , established in 1991 and updated periodically to promote ethical practices and equitable access in resource-limited settings. Initiatives like India's Artificial Limbs Manufacturing Corporation (ALIMCO) under the ADIP Scheme provide subsidized low-cost prosthetics, enabling thousands of individuals to access affordable limb replacements annually through government and NGO partnerships. As of 2025, the FDA has issued guidance on incorporating in development, potentially accelerating approvals for bioartificial organs while addressing equity in clinical data representation.

Enhancement versus Therapeutic Use

Artificial organs are primarily developed and deployed for therapeutic purposes, aiming to restore or maintain normal physiological function in patients suffering from organ failure or dysfunction. For instance, cardiac pacemakers are implanted to treat , a condition characterized by an abnormally slow that can lead to symptoms such as , , or fainting, by delivering electrical impulses to regulate and prevent life-threatening pauses. This restorative application aligns with principles that prioritize alleviating suffering and enabling individuals to achieve baseline standards, without altering inherent human capabilities beyond what is necessary for survival or normalcy. In contrast, enhancement involves the use of artificial organs or related implants to augment human abilities beyond typical physiological limits, raising questions about the boundaries of medical intervention. Neural implants, such as those developed by in clinical trials during the 2020s, exemplify this shift; while initial trials focus on restoring motor or communication functions for individuals with or speech impairments, the technology's potential for cognitive enhancement—such as improving , processing speed, or direct brain-computer interfacing—positions it as a tool for non-therapeutic augmentation. These applications blur the line between therapy and improvement, as enhancements could enable superior performance in cognitive tasks, potentially transforming users into "cyborgs" with integrated technology that challenges traditional notions of human identity and . Ethical dilemmas surrounding enhancement center on issues of , , and societal . Consent becomes complex when enhancements alter self-perception or long-term decision-making capacities, prompting debates on whether individuals can fully comprehend irreversible changes to their cognitive or physical selves, as seen in discussions where integration of artificial components raises existential questions about humanity. Furthermore, the risk of exacerbating social divides is significant, as access to enhancements may be limited to affluent populations, widening gaps in capability and opportunity akin to disparities observed in therapeutic availability. To address these concerns, guidelines from bodies like the Nuffield Council on Bioethics emphasize distinguishing non-therapeutic implants from restorative ones, advocating for rigorous safety assessments and equitable frameworks to mitigate enhancement-driven inequalities. In military contexts, ethical restrictions on enhancements are evident; for example, reports on super-soldiers highlight bans or cautious approaches to non-essential augmentations due to risks of and , as outlined in 2023 analyses of DARPA-related initiatives.

Future Directions

Regenerative Medicine and Stem Cell Integration

Regenerative medicine leverages cells to engineer functional tissues that mimic native organs, potentially supplanting mechanical or synthetic artificial organs by enabling biological regeneration tailored to individual patients. Induced pluripotent cells (iPSCs), first reprogrammed from adult fibroblasts in 2006 by introducing four transcription factors—Oct3/4, , c-Myc, and —offer a renewable source of patient-specific cells that can differentiate into various organ lineages, bypassing ethical concerns associated with embryonic cells. These iPSCs have been pivotal in generating organoids, three-dimensional miniature organ models that recapitulate key structural and functional aspects of native tissues; for instance, iPSC-derived liver organoids, developed in the early 2010s, exhibit hepatocyte functionality including metabolic activity and vascular-like networks when transplanted into animal models. Integration of cells into scaffolds enhances organ regeneration by providing a structural framework for and maturation. Scaffolds, often composed of biocompatible polymers or decellularized extracellular matrices, are seeded with iPSCs or mesenchymal cells to promote tissue formation; this approach has shown promise in preclinical models where seeded constructs integrate with host vasculature and restore organ-specific functions. A notable example is the 2024 preclinical study in a model using stem cell-seeded polymeric grafts for augmentation, which demonstrated significant tissue regeneration and restored capacity to approximately 80% of normal function over two years, offering a viable alternative to traditional enterocystoplasty. Such biohybrid strategies build on current principles by fostering endogenous remodeling, potentially leading to fully biological replacements. Advanced techniques like CRISPR-Cas9 , refined in the , further enable compatibility by correcting genetic defects in iPSCs or modifying immune-related genes, such as HLA antigens, to minimize allogeneic responses. For vascularization—a critical hurdle in scaling engineered tissues to clinically relevant sizes—strategies incorporating angiogenic growth factors like (VEGF) have successfully induced capillary networks within scaffolds, improving nutrient delivery and tissue viability in models. Looking ahead, these advancements project the feasibility of advanced , with iPSC-derived cardiac patches and tissues anticipated to advance toward broader clinical use by 2030 through iterative improvements in and maturation protocols, as evidenced by ongoing bioengineering efforts and recent clinical trials. For example, in February 2025, Heartseed completed enrollment in a phase 1/2 trial (LAPiS Study) for HS-001, an investigational iPSC-derived cardiomyocyte therapy for . Patient-derived s inherently reduce rejection risks to near-zero by matching the recipient's genetic profile, eliminating the need for lifelong and transforming transplantation paradigms.

Emerging Technologies (Nanotechnology and AI Integration)

is revolutionizing the development of artificial organs by enabling the creation of biocompatible scaffolds and targeted delivery systems that mimic natural tissue environments. such as gold nanoparticles enhance biocompatibility in organ implants through precise surface modifications, reducing immune responses and facilitating to protect grafts from ischemia-reperfusion . For instance, poly(lactic-co-glycolic acid) () nanoparticles loaded with immunosuppressants like FK506 have demonstrated improved outcomes in rat models by selectively targeting lymphoid organs, thereby minimizing systemic side effects. Similarly, silica-based (SiO₂-VEGF) nanofibers serve as extracellular matrix-mimicking scaffolds for subcutaneous islet transplantation, promoting vascularization and cell viability without to pancreatic beta cells or endothelial cells. In bioartificial organ engineering, (HAp) nanoparticles coated on improve and mechanical matching to native , which extends to organ constructs by reducing stress shielding and enhancing long-term . These advancements, often incorporating polymers like or , allow for customizable nanostructures with diameters as small as 5-26 nm, aligning closely with physiological scales to support tissue regeneration in artificial livers and kidneys. Preclinical studies have shown that PEGylated bilirubin nanoparticles mitigate in islet , boosting graft survival rates by up to 50% in preclinical models. Artificial intelligence (AI) integration complements nanotechnology by enabling intelligent control and optimization of bioartificial organs, particularly through AI-driven and monitoring systems. In bioprinting, algorithms, such as and (LSTM) networks, adjust critical process parameters like rheology and printing temperature in , ensuring high viability (>90%) and structural fidelity in printed organoids. This closed-loop control facilitates the fabrication of complex artificial organs, such as vascularized liver tissues, by predicting and correcting defects during in situ printing on dynamic surfaces like . AI further enhances nanotechnology-enabled organoids and organs-on-chips by analyzing multi-scale data to simulate organ functions and personalize designs. For example, models integrate with nanomaterial scaffolds to optimize differentiation in organoids, accelerating for neurological disorders. In control systems, AI-driven twins predict organ maturation conditions, using to regulate nutrient delivery via nanoparticle-embedded sensors, which has led to candidates like AI-optimized for organ repair. These synergies, as seen in 2024 advancements, reduce development timelines by 30-50% while improving predictive accuracy for bioartificial heart and prototypes.

References

  1. [1]
    Artificial Organs | Harvard Catalyst Profiles
    Artificial organs are devices intended to replace non-functioning organs, either temporarily or permanently, and function as the natural organs they replace.
  2. [2]
    Bioartificial Organ Manufacturing Technologies - PMC - NIH
    Generally, an artificial organ is an engineered device that can be implanted or integrated into a human body—interfacing with living tissue—to replace a natural ...
  3. [3]
    Father of Artificial Organs ‐ The story of medical pioneer Willem J ...
    Willem J. Kolff invented the first clinically functioning hemodialysis machine and led the team that realized the first implantable fully artificial heart.Missing: definition | Show results with:definition<|control11|><|separator|>
  4. [4]
    KOLFF, WILLEM J. | Encyclopedia of Cleveland History
    In 1961, Kolff and his team developed the intra-aortic balloon pump, which further revolutionized heart surgery and still is used in heart surgeries.Missing: key | Show results with:key
  5. [5]
    Utah and the Artificial Heart: Impact and Reflections 40 Years Later
    Jan 25, 2023 · In 1982, a team at University of Utah Hospital made history by performing the first permanent artificial heart implant on a human.
  6. [6]
    BENG 100 - Lecture 25 - Biomedical Engineers and Artificial Organs
    Professor Saltzman talks about the design and function of some artificial organs, such as lens implants, heart valves and vessels, hip, dialyzer, heart/lung ...
  7. [7]
    Evolution of Artificial Hearts: An Overview and History - PMC - NIH
    Artificial hearts were developed as temporary devices for heart disease patients, to sustain life until a transplant, and are not intended to replace the human ...
  8. [8]
    Medical Devices/Artificial Organs - Regenerative Medicine
    Research in medical devices and artificial organs range from basic research to understand molecular and cellular mechanisms to the development of off-the-shelf ...
  9. [9]
    [PDF] Tissue Engineering: History, Principles, Applications, Challenges ...
    Tissue engineering uses a variety of cell types to produce tissues, such as adult stem cells and human embryonic stem cells. With the production of tissues, ...
  10. [10]
    Innovations in Biomedical Engineering Today - South Dakota Mines
    Artificial organs, such as the bionic pancreas and bioengineered lungs, are offering a lifeline to patients waiting for transplants. These devices mimic natural ...
  11. [11]
    Early-Phase Clinical Trials of Bio-Artificial Organ Technology
    Oct 31, 2022 · Regenerative medicine has emerged as a novel alternative solution to organ failure which circumvents the issue of organ shortage.
  12. [12]
    The heat is on for building 3D artificial organ tissues - UW Medicine
    Those artificial tissues could be used to study, for example, how drugs or toxins act on the liver.
  13. [13]
    Artificial Organ - an overview | ScienceDirect Topics
    Artificial organs are defined as man-made devices designed to replace or support the function of human vital organs, serving as alternatives to transplants, ...
  14. [14]
    Artificial Organs: Innovating to Replace Donors and Dialysis
    Jan 20, 2023 · Artificial organs are bioengineered devices or tissues that scientists create and integrate into the human body to replace, duplicate, or ...
  15. [15]
    Artificial Organs | SpringerLink
    May 27, 2021 · Artificial organs refer to all engineered devices (originally mechanical organs) or tissues both external (e.g., augmenting senses such as sight ...
  16. [16]
    [PDF] RIVM report 360050011 Artificial organs
    Artificial organs that can fully replace a failing organ are not yet commercially available. This RIVM report provides a comprehensive overview of the ...
  17. [17]
    Artificial blood vessel: The Holy Grail of peripheral vascular surgery
    Artificial blood vessels composed of viable tissue represent the ideal vascular graft. Compliance, lack of thrombogenicity, and resistance to infections
  18. [18]
    Artificial Organs - ScienceDirect.com
    Artificial organs comprise complex medical devices that have active mechanical or biochemical functions such as heart, lung, kidney, liver, pancreas, ...
  19. [19]
    What's the Difference Between Orthotics and Prosthetics?
    Sep 1, 2021 · However, while orthotics can assist an existing body part, prosthetics are artificial replacements for missing body parts. Artificial limbs are ...
  20. [20]
    Artificial Intelligence - Cleveland Clinic Magazine
    Widely regarded as the father of artificial organs, Willem Kolff, MD, PhD, established the Department of Artificial Organs at Cleveland Clinic.
  21. [21]
    Artificial organs as a bridge to transplantation - PubMed
    Some bioartificial organs may well be used to replace anatomical defects, while others allow to compensate for failing organ functions and to bridge patients ...
  22. [22]
    Organ Donation Statistics | organdonor.gov
    May 2, 2025 · There are currently over 103,000 people on the national transplant waiting list. You can learn more about the numbers and see specific ...
  23. [23]
    New Technologies for Organ Replacement and Augmentation
    Fully implantable artificial organs have been sought for decades as means for augmenting or replacing organ function. Implantable defibrillators help prevent ...
  24. [24]
    Statistics | The Kidney Project - UCSF
    After one year of treatment, those on dialysis have a 15-20% mortality rate, with a 5-year survival rate of under 50%. Persons who receive transplants have a ...Missing: extension | Show results with:extension
  25. [25]
    What if artificial organs could replace the need for donors?
    Nov 7, 2017 · The key benefits of artificial organs are that they open up the possibility of mass production and patients are less likely to experience organ ...
  26. [26]
    Cochlear™ Reliability Reports – Nucleus® System & Osia® System
    Jul 14, 2025 · Over 600,000 registered implants analyzed; Up to 99.8% Cumulative Survival Percentage (CSP) within 5 years for current-generation implants ...
  27. [27]
    Subretinal Photovoltaic Implant to Restore Vision in Geographic ...
    Oct 20, 2025 · The primary end points were a clinically meaningful improvement in visual acuity (defined as ≥0.2 logMAR) from baseline to month 12 after ...Missing: outcomes | Show results with:outcomes
  28. [28]
    This 3,000-Year-Old Wooden Toe Shows Early Artistry of Prosthetics
    Jun 21, 2017 · Crafted from leather and wood, the ancient Egyptian prosthesis was was adjusted to precisely fit its wearer's foot.
  29. [29]
    3,000-Year-Old Wooden Toe Prosthetic Discovered on Egyptian ...
    Jun 22, 2017 · That's because the toe is a 3,000-year-old wooden prosthesis, which was found attached to a female mummy in an ancient Egyptian grave site.
  30. [30]
    Frequently Asked Questions - American Society of Ocularists
    Artificial eye-making has been practiced since ancient times. The first ocular prostheses were made as early as the fifth century B.C., by Roman and Egyptian ...
  31. [31]
    History of the Prosthesis - Jahrling Ocular Prosthetics, Inc.
    The first ocular prostheses were made by Roman and Egyptian priests as early as the fifth century BC. In those days artificial eyes were made of painted clay ...
  32. [32]
    Ambroise Paré IV: The early history of artificial limbs (from robotic to ...
    During the European mediaeval period, armoured knights used iron prosthetics to conceal lost limbs. ... Ambroise Paré who invented both upper-limb and lower-limb ...
  33. [33]
    Paré and prosthetics: the early history of artificial limbs - PubMed
    Ambroise Paré who invented both upper-limb and lower-limb prostheses. His 'Le Petit Lorrain', a mechanical hand operated by catches and springs, was worn by a ...
  34. [34]
    PARÉ AND PROSTHETICS: THE EARLY HISTORY OF ARTIFICIAL ...
    Oct 28, 2007 · Ambroise Paré who invented both upper-limb and lower-limb prostheses. His 'Le Petit Lorrain', a mechanical hand operated by catches and springs, was worn by a ...
  35. [35]
    Transfusion Medicine History - AABB
    Reuben Ottenberg performs the first blood transfusion using blood typing and crossmatching in New York. Ottenberg also observed the mendelian inheritance of ...
  36. [36]
    The Earliest Blood Transfusions in 17th-Century in Italy (1667-1668)
    Historical accounts of the earliest experiments in blood transfusion celebrate work done in France and England in 1667 to 1668.Missing: 1700s | Show results with:1700s
  37. [37]
    The Civil War and the Birth of the US Prosthetics Industry - ASME
    Jun 6, 2011 · The Civil War set the prosthetics industry on a course from wooden legs and simple hooks to today's quasi-bionic limbs that look like the real thing.
  38. [38]
    After The Amputation - Prosthetic Limbs of the Civil War
    Feb 23, 2017 · The best options were prosthetic arms with hooks, and many veterans with a missing arm preferred an empty sleeve to a metal hook. Moreover, ...
  39. [39]
    A brief history of cardiac pacing - PMC - PubMed Central
    Late 1920's – Early 1930's: first pacing machines. Credit for the first external cardiac pacemaker has been shared by two doctors: the Australian ...
  40. [40]
    Engineering Heartbeats: The Evolution of Artificial Pacemakers
    The very first pacemaker was developed in the late 1920s almost simultaneously by both Australian anesthesiologist Mark Lidwell and American physiologist ...
  41. [41]
    Dr. Willem Kolff: The Father of the Artificial Kidney - PMC - NIH
    Sep 10, 2024 · By the 1960s, Kolff's invention of the artificial kidney had solved the problem of acute kidney failure; however, it was not seen as the ...
  42. [42]
    Dialysis Machine Museum
    The first practical artificial kidney was built during World War II by the Dutch doctor Willem Kolff. ... first parallel flow artificial kidney at Case ...Missing: origin | Show results with:origin
  43. [43]
    Medical Innovations: Under Occupation, the Development of Dialysis
    Apr 6, 2020 · In secret, hidden from occupying German forces, Willem Kolff developed the first dialysis machine to save patients from kidney failure.
  44. [44]
    John H. Gibbon, Jr. Part I. The development of the first ... - PubMed
    In 1950, he received support from IBM to build a heart-lung machine on a more sophisticated scale. Finally, on May 6, 1953, Dr. Gibbon performed his first ...Missing: 1950s | Show results with:1950s
  45. [45]
    Part I. The Development of the First Successful Heart-Lung Machine
    John Gibbon performed the world's first suc- cessful open-heart surgery using extracorporeal oxygenation on May 6, 1953. This event, the culmination of a 22 ...Missing: 1950s | Show results with:1950s<|separator|>
  46. [46]
    This 1950s Heart-Lung Machine Revolutionized Cardiac Surgery
    May 24, 2019 · This 1950s Heart-Lung Machine Revolutionized Cardiac Surgery. Open-heart procedures evolved rapidly once Mayo Clinic surgeon John Kirklin made his improvements.
  47. [47]
    Evolution of Diabetes Insulin Delivery Devices - PMC - NIH
    The first manufactured insulin pump was introduced in the 1970s, while the first manufactured insulin pen, the NovoPen® (Novo Nordisk), was introduced in 1985.
  48. [48]
    Closed-Loop Insulin Delivery Systems: Past, Present, and Future ...
    Insulin pumps first became clinically feasible in the 1970s, and have since become miniaturized and more reliable. Continuous glucose monitoring systems (CGMS) ...
  49. [49]
    Insulin Pumps: Products, Design Features, Indications
    Jan 4, 2023 · Since the first human trials of insulin pumps in the late 1970s, insulin pump therapy, also known as continuous subcutaneous insulin ...
  50. [50]
    History of the Cochlear Implant - Page 6 of 8 - ENTtoday
    Apr 1, 2013 · 1984—Silver Spring, Md.: FDA approves the House/3M single-channel implant for adults. 1987-2000—Silver Spring, Md.: FDA approves multiple- ...
  51. [51]
    History - The House Institute Foundation
    1981 Name is changed to House Ear Institute (HEI) in honor of founder Howard P. House, M.D.; 1984 FDA approves the first cochlear implant, the 3M/House device ...
  52. [52]
    Evolution of the candidacy requirements and patient perioperative ...
    Dec 8, 2022 · In the early 1980s, the FDA approved a single-channel implant for adults (House/3M single-channel device), which consisted of a receiver/ ...
  53. [53]
    Permanent Implantation of the Jarvik-7 Total Artificial Heart
    All four patients subsequently suffered serious complications; despite these, three patients achieved survival with the TAH for intervals of 112, 488, and 620 ...
  54. [54]
    Robert Jarvik, MD on the Jarvik-7
    Robert Jarvik, MD is widely known as the inventor of the first successful permanent artificial heart, the Jarvik 7. In 1982, the first implantation of the ...
  55. [55]
    F.D.A. APPROVES PLAN TO USE ARTIFICIAL HEART
    Sep 12, 1981 · The Food and Drug Administration has approved a University of Utah proposal to implant an artificial heart in a human, a procedure already ...
  56. [56]
    3D Bioprinting of Human Hollow Organs - PMC - PubMed Central
    May 10, 2022 · There are several bioprinting techniques and approaches by which researchers are fabricating functional 3D-printed human organ constructs.
  57. [57]
    Long-term outcomes of the international EXPAND trial of Organ ...
    The EXPAND trial was the first multicenter, international clinical trial to evaluate the use of portable normothermic EVLP with the OCS Lung for the ...
  58. [58]
    Scientists regenerate fully functional urinary bladder tissue using a ...
    Jan 30, 2024 · This unique model initially created by the Sharma Research Group explores long term bladder tissue regeneration at both anatomical and physiological levels.
  59. [59]
    Organ bioprinting gets a breath of fresh air
    May 2, 2019 · In the tests of therapeutic implants for liver disease, the team 3D printed tissues, loaded them with primary liver cells and implanted them ...
  60. [60]
    Advances in AI-based prosthetics development: editorial - PMC - NIH
    Adding AI to these smart prostheses allows the algorithm to decipher electrical nerve impulses sent by the patient's muscles, allowing for finer-grained control ...
  61. [61]
    Outcomes of Extracorporeal Membrane Oxygenation for COVID-19 ...
    Notably, hospital mortality for V-V ECMO for COVID-19 improved (50.6% in 2020, 48.4% in 2021, and 37.0% in 2022) between 2020-2022.
  62. [62]
    Artificial Hearts | Victor Chang Cardiac Research Institute
    LVADs can keep people alive for almost six years. Research shows that around 80–85% of patients are alive 12 months after having an LVAD implanted, whilst up to ...
  63. [63]
    How long do people live with an artificial heart? - CureIndia
    Jul 14, 2025 · Recent reports indicate that 72% of patients with long-term devices successfully achieved transplant candidacy, reflecting a reasonable result ...
  64. [64]
    Ceramic Materials for Biomedical Applications: An Overview ... - NIH
    Biomaterials can be classified according to their chemical nature as metallic, polymeric, ceramic, and composite, and can also be biologically derived [3]. Care ...
  65. [65]
    Article Bioinspired Heart Valve Prosthesis Made by Silicone Additive ...
    Jul 10, 2019 · Using biocompatible silicones with tunable mechanical properties, heart valves were fabricated by combining spray and extrusion-based additive ...
  66. [66]
    Artificial Lungs for Lung Failure: JACC Technology Corner
    Sep 24, 2018 · The cTAL uses flexible polyurethane housing with a polypropylene fiber bundle with surface area of 2.4 m2 (57). The design provides maximized ...
  67. [67]
    An overview of polyurethane biomaterials and their use in drug ...
    Nov 20, 2023 · Additionally, polyurethanes with excellent biocompatibility and hemocompatibility can be synthesized, enabling their use as biomaterials in the ...<|control11|><|separator|>
  68. [68]
    Advancement in biomedical implant materials—a mini review
    Jul 2, 2024 · Metal alloys like stainless steel, titanium, and cobalt-chromium alloys are preferable for bio-implants due to their exceptional strength, ...
  69. [69]
    In Depth on Biomaterials in Life Sciences | Reports - Boyd Biomedical
    Ceramics, such as hydroxyapatite and alumina, are bioinert or bioactive materials widely used in bone grafts, dental implants, and coatings for medical devices.
  70. [70]
    Bioinspired Approaches to Engineer Antithrombogenic Medical ...
    Apr 20, 2023 · Here, we review material and surface coating technologies that have taken bioinspiration from the endothelium to reduce medical device thrombosis.
  71. [71]
    Advancements in the Use of Hydrogels for Regenerative Medicine
    Most are biocompatible, so they are widely used in tissue engineering. However, they lack the desired mechanical properties and can trigger immune responses ...
  72. [72]
    Current developments and future perspectives of nanotechnology in ...
    Silver nanoparticles are also an effective adjunct therapy for bone healing because they can reduce surrounding inflammation. To improve osseointegration ...
  73. [73]
    Two-dimensional nanomaterials for inflammation-related disease ...
    In recent years, 2D materials have demonstrated significant potential in regulating inflammatory responses through multiple mechanisms, including combating ...
  74. [74]
    [PDF] Use of International Standard ISO 10993-1, "Biological evaluation of ...
    Sep 8, 2023 · use of ISO 10993-1 and the FDA-modified matrix (Attachment A) to determine the relevant biocompatibility endpoints for an evaluation; general ...
  75. [75]
    Bioresorbable Polymer - an overview | ScienceDirect Topics
    By itself, PGA is more hydrophilic than PLA due to the lack of methyl group and has a rapid degradation rate of 6–12 months. Due to its rapid degradation rate ...
  76. [76]
    Biomedical Applications of Biodegradable Polymers - PMC
    ... degrading polymer (6 – 12 months for complete mass loss). With a low modulus (1.5 GPa), but good flexibility and strength maintenance (1 – 2 months) PDO ...
  77. [77]
    Total Artificial Heart: A Life-Saving Bridge to Transplant
    Aug 22, 2025 · The total artificial heart (TAH), SynCardia, evolved from Jarvik-7 and is used for heart failure patients awaiting a human heart transplant.
  78. [78]
    One-year outcomes with the HeartMate 3 left ventricular assist device
    1-year survival after HM3 implantation was 85%. The HM3 showed excellent midterm results with 0% stroke and 0% pump thrombosis rates 1 year after implantation.
  79. [79]
    Dr. DeBakey and Dacron grafts - Research.va.gov
    Feb 22, 2021 · The Dacron graft is still widely used today. It was used on DeBakey himself when he developed an aortic aneurysm in 2005.
  80. [80]
    Dacron Vascular Prosthesis - an overview | ScienceDirect Topics
    Michael DeBakey and colleagues, in 1964, published an 8-year study of 67 patients where Dacron® vascular grafts were used for aortic aneurysm and vessel bypass ...
  81. [81]
    Artificial blood vessels-clinical development of TEVG - PMC - NIH
    May 26, 2025 · This paper focuses on the clinical development of tissue-engineered vascular grafts (TEVGs), especially those that have progressed to clinical ...
  82. [82]
    Fluid–structure interaction modelling of a positive-displacement ...
    Apr 14, 2023 · The Realheart TAH is a four-chamber artificial heart that uses a positive-displacement pumping technique mimicking the native heart to produce ...
  83. [83]
    Artificial heart | Benefits, Risks & History | Britannica
    Oct 9, 2025 · Artificial heart, device that maintains blood circulation and oxygenation in the human body for varying periods of time.
  84. [84]
    SynCardia – myactioneducation.org
    The batteries for the C2 driver usually last approximately 1 and a half hours. The Freedom Driver batteries last approximately 4 hours and can be recharged ...
  85. [85]
    Shared care left ventricular assist device site to implant center
    The number of LVADs implanted worldwide exceeds 100,000 of which 18,539 are reported in the Interagency Registry for Mechanically Assisted Circulatory Support ...
  86. [86]
    Stroke Incidence and Impact of Continuous-Flow Left Ventricular ...
    Jan 3, 2019 · The rate of adverse events associated with CF-LVAD use—specifically, strokes—is high (Figure 1), as 10% of individuals are affected by stroke in ...
  87. [87]
    Liver blood flow: Physiology, measurement, and clinical relevance
    May 31, 2016 · A total liver blood flow (LBF) of 1.5 L/min is considered the normal value in the average male, but the range can be quite wide (1 to 2 L/min).<|separator|>
  88. [88]
    Extracorporeal Bioartificial Liver for Treating Acute Liver Diseases
    The bioartificial liver (BAL) device uses metabolically active liver cells to address liver-specific functions. They are incorporated in a bioreactor where they ...
  89. [89]
    Comparison of extracorporeal cellular therapy (ELAD®) vs standard ...
    Nov 16, 2018 · Results demonstrate a significant improvement in TFS in ELAD vs control groups in association with significant improvements in serum bilirubin ...<|separator|>
  90. [90]
    Liver assistive devices in acute liver failure: Current use and future ...
    Bioartificial ECLS incorporates active hepatocytes (human or porcine in origin) to improve liver detoxification capacity and to support hepatic synthetic ...
  91. [91]
    Improved survival of porcine acute liver failure by a bioartificial liver ...
    Jan 15, 2016 · In a porcine ALF model, hiHep-BAL treatment restored liver functions, corrected blood levels of ammonia and bilirubin, and prolonged survival.
  92. [92]
    Bioartificial liver support for acute liver ... - KoreaMed Synapse
    Apr 22, 2025 · Early extracorporeal liver support efforts relied on artificial-liver devices, which primarily performed detoxification but failed to improve ...
  93. [93]
    Time-In-Range and Diabetes | Endocrine Society
    Jan 24, 2022 · Glucose goals can vary for each person, but a typical target glucose range is from 70 to 180 mg/dL. For most people with type 1 or type 2 ...
  94. [94]
    Closed-Loop Insulin Delivery Systems: Past, Present, and Future ...
    Jun 6, 2022 · Insulin pumps first became clinically feasible in the 1970s, and have since become miniaturized and more reliable. Continuous glucose monitoring ...
  95. [95]
    Automated Insulin Delivery Algorithms | Diabetes Spectrum
    Aug 1, 2019 · All AP systems have three basic components: sensors, decision-making algorithms (controllers), and insulin infusion pumps. The first AP systems ...
  96. [96]
    Type 1 Diabetes and AID Systems: Meta-Analysis Proves Eff | DZD
    At the same time, AHCL systems reduced the time with elevated glucose values (>180 mg/dl) as well as with severely elevated values (>250 mg/dl) compared to ...
  97. [97]
    Efficacy and Safety of iLet Bionic Pancreas in Patients With Type 1 ...
    Oct 28, 2025 · This systematic review and meta‐analysis evaluated the efficacy and safety of the iLet bionic pancreas (iLet BP), a novel automated insulin ...
  98. [98]
    FDA approves first bionic eye for the blind
    Feb 14, 2013 · The Argus II can partially restore the sight of blind individuals after surgical implantation. Clinical trials demonstrated that totally blind ...Missing: details vision
  99. [99]
    The functional performance of the Argus II retinal prosthesis - PMC
    The Argus II retinal prosthesis aims to restore vision in patients with profound vision loss due to end-stage retinal degenerative diseases such as retinitis ...
  100. [100]
    What Are Cochlear Implants for Hearing? | NIDCD - NIH
    Jun 13, 2024 · ... cochlear implants. As of December 2019, approximately 736,900 registered devices have been implanted worldwide. In the United States ...What is a cochlear implant? · Who gets cochlear implants?
  101. [101]
    Quick Statistics About Hearing, Balance, & Dizziness - NIDCD - NIH
    Sep 20, 2024 · As of July 2022, more than 1 million cochlear implants have been implanted worldwide. In the United States, roughly 118,100 devices have been ...
  102. [102]
    Cochlear implantation outcomes in adults: A scoping review - PMC
    May 5, 2020 · At the individual level, 82.0% of adults with postlingual hearing loss and 53.4% of adults with prelingual hearing loss improved their speech ...
  103. [103]
    Advanced technologies for intuitive control and sensation of ... - NIH
    Aug 8, 2019 · While control of motorized prosthetic devices through the use of electromyography has been widely available since the 1980s, this technology is ...Missing: history | Show results with:history
  104. [104]
    USTC Successfully Develops 19-DOF Biomimetic Dexterous ...
    Feb 12, 2025 · The 19-DOF prosthetic hand uses shape-memory alloys, a tendon system, 23 sensors, and voice recognition, weighing 0.37kg, and can perform daily ...Missing: 2020s | Show results with:2020s
  105. [105]
    HAPTIX: Hand Proprioception and Touch Interfaces - DARPA
    HAPTIX technologies are being designed to tap into the motor and sensory signals of the arm to allow users to control and sense the prosthesis via the same ...
  106. [106]
    A Review of the Biocompatibility of Implantable Devices
    This review focuses on the foreign body response and the approaches that have been taken to overcome this. The biological response following device implantation ...
  107. [107]
    Activation of immune signals during organ transplantation - PMC
    Mar 11, 2023 · The activation of host's innate and adaptive immune systems can lead to acute and chronic graft rejection, which seriously impacts graft survival.
  108. [108]
    Immunology of Transplant Rejection - Medscape Reference
    Jul 11, 2023 · Hyperacute rejection is humorally mediated and occurs because the recipient has preexisting antibodies against the graft, which can be induced ...
  109. [109]
    Thrombogenic and Inflammatory Reactions to Biomaterials in ...
    Mar 11, 2020 · In this review, we will compare the mechanisms of thrombus development and progression in the arterial and venous systems.
  110. [110]
    HLA Mismatching Strategies for Solid Organ Transplantation
    HLA matching provides numerous benefits in organ transplantation including better graft function, fewer rejection episodes, longer graft survival, and the ...
  111. [111]
    Cyclosporine - StatPearls - NCBI Bookshelf - NIH
    Aug 28, 2023 · Cyclosporine is an immunosuppressive agent used to treat organ rejection post-transplant. It also has use in certain other autoimmune diseases.
  112. [112]
    Immunosuppression trends in solid organ transplantation: The future ...
    Oct 31, 2020 · All received cyclosporine, prednisone, and ATG induction. Six-month rejection rates were 22% lower in the mycophenolate arm (23% vs. 45%), ...
  113. [113]
    Strategies for surface coatings of implantable cardiac medical devices
    Surface modification, with the immobilization of bioactive molecules, is the most commonly used and effective method to strengthen the biocompatibility and ...
  114. [114]
    Acute Rejection in the First Year in Heart Transplant...
    Conclusions:The cumulative incidence of acute rejection was 15.36% at discharge and 35.05% at one year. The maintenance therapy comprising of tacrolimus, ...Missing: implants | Show results with:implants
  115. [115]
    Degeneration of Bioprosthetic Heart Valves: Update 2020
    Sep 21, 2020 · On average, native valves undergo ≈600 million cycles of opening and closing during 15 years of operation and ≈3 billion cycles during a ...
  116. [116]
    Know the Facts About Heart Valve Choice
    Valve Durability. Mechanical Valves. Mechanical valves are designed to last a lifetime for patients of all ages.2. On-X® Aortic Heart Valve. On-X® Mitral Heart ...
  117. [117]
    Mechanical Aortic Valve Replacement - StatPearls - NCBI Bookshelf
    Sep 2, 2024 · Mechanical valves, known for their longevity—often lasting over 20 years—are particularly beneficial for younger patients or those who can ...
  118. [118]
    Portability - Jarvik Heart Inc.
    The Jarvik 2000 Ventricular Assist Device can be powered for 8-10 hours on a single rechargeable Lithium-ion battery pack that weighs less than two pounds.
  119. [119]
    Living With a VAD: How Your Daily Routine Changes - Temple Health
    Jul 27, 2020 · Two full batteries usually last 8–12 hours. If you want to save battery power, you can plug into a wall outlet at work or home during the day, ...
  120. [120]
    Ventricular Assist Devices – Evolution of Surgical Heart Failure ... - NIH
    Survival of patients still on VAD support was 72 % at three years. Main complications were bleeding requiring surgical re-intervention in 26 %, driveline/pump ...
  121. [121]
    Review article The impact of artificial intelligence on remote healthcare
    This review examines how AI has transformed virtual healthcare with regard to patient engagement and connectivity, real-time monitoring of health status, and ...
  122. [122]
    AlloHome - CareDx
    AlloHome is a remote patient monitoring (RPM) solution designed to drive patient engagement and timely interventions for patients pre- and post-transplant.Missing: artificial 2020s
  123. [123]
    Remote Patient Monitoring in the United States: 2025 Landscape ...
    Remote patient monitoring (RPM) refers to using digital technologies to collect patients' health data outside of traditional care settings and transmit it ...
  124. [124]
    Medical complications in patients with LVAD devices
    Feb 13, 2017 · The reported incidence of ischaemic stroke during support with the HeartMate II, as either BTT or DT, is 0.064 – 0.082 events per patient per ...
  125. [125]
    Left ventricular assist device-associated infections: incidence and ...
    May 28, 2020 · The probability of having a LVAD-associated infection at one year after implantation was 26.6% (95% CI: 17.5–40.5). Figure 1 Cumulative ...
  126. [126]
    A Growth-Accommodating Implant for Paediatric Applications - NIH
    Medical implants of fixed size cannot accommodate normal tissue growth in children, and often require eventual replacement or in some cases removal, ...
  127. [127]
    Pediatric pulmonary valve replacements: Clinical challenges ... - NIH
    Another significant contributor is the inevitability of somatic growth in pediatric patients, causing structural discrepancies between the patient and PPVR, ...
  128. [128]
    Research Progress of Human Biomimetic Self‐Healing Materials
    Oct 28, 2024 · This review discusses various organ-inspired self-healing materials in detail, summarizes their synthetic principles and introduces their fascinating ...
  129. [129]
    Enhancing regenerative medicine with self-healing hydrogels
    Self-healing hydrogels are 3D structures that self-heal after breaking, acting as delivery platforms for tissue repair and in cyborganics, using dynamic bonds.
  130. [130]
    Long-Term Outcomes and Costs of Ventricular Assist Devices ... - NIH
    In 2003, Medicare expanded coverage of ventricular assist devices as destination, or permanent, therapy for end-stage heart failure.
  131. [131]
    Policy innovations to advance equity in solid organ transplantation
    Aug 1, 2025 · Low-income and middle-income countries have particularly low rates of transplantation, as well as less access to new technologies, mainly due ...
  132. [132]
    Racial Bias in Clinical Tools and Impact on Organ Transplantation
    Misuse of race in clinical and research equations wrongly perpetuates race as a categorical and biological construct and may be a source of continuous mistrust ...
  133. [133]
    Premarket Approval (PMA) - FDA
    May 16, 2019 · Premarket approval (PMA) is the FDA process of scientific and regulatory review to evaluate the safety and effectiveness of Class III medical devices.Overview · When A Pma Is Required · Data Requirements
  134. [134]
    New Regulations - Public Health - European Commission
    The Regulation introduces a staggered extension of the transition period provided for in Regulation (EU) 2017/745 on medical devices (MDR), subject to certain ...
  135. [135]
    [PDF] Increasing availability, ethical access and oversight of ...
    Jun 1, 2024 · The goal is to increase availability, ethical access, and oversight of transplantation, which is crucial for end-stage organ failure and other ...Missing: guidelines | Show results with:guidelines
  136. [136]
    Best Government Schemes for Free and Low-Cost Prosthetics in India
    The ADIP Scheme: Free and Subsidized Prosthetic Limbs for Eligible Individuals. One of the most well-known government schemes in India for free and low-cost ...
  137. [137]
    Bradycardia - Diagnosis and treatment - Mayo Clinic
    Dec 13, 2024 · A pacemaker is placed under the skin near the collarbone during a minor surgery. The device helps fix a slow heartbeat.
  138. [138]
    Pacemakers - Who Needs Them | NHLBI, NIH
    Mar 24, 2022 · The most common reason people get a pacemaker is their heart beats too slowly (called bradycardia), or it pauses, causing fainting spells or ...
  139. [139]
    Clinical Trials - Neuralink
    Investigating decoding words from thought. For people with severe speech impairment from ALS, stroke, brain injury, organ removal, and other conditions. Join ...Missing: enhancement 2020s
  140. [140]
    Ethical considerations for the use of brain–computer interfaces for ...
    Oct 28, 2024 · We discuss the ethical, legal, and scientific implications of eBCIs, including issues related to privacy, autonomy, inequality, and the broader societal impact.
  141. [141]
    Neurotechnology and ethics guidelines for human enhancement ...
    Aug 2, 2023 · This technology raises several ethical issues, including as related to identity and memory, autonomy and authenticity.Missing: dilemmas | Show results with:dilemmas
  142. [142]
    The Ethics of Artificial Organs - Viterbi Conversations in Ethics
    The ethics of artificial organs is discussed, including the Biomedical Engineering Society Code of Ethics and the ethics of artificial hearts.
  143. [143]
    [PDF] Medical implants - Nuffield Council on Bioethics
    Medical implants can be used to treat or monitor health conditions, or to restore body function. • High-profile cases involving failing implants.
  144. [144]
    Medical implants - Nuffield Council on Bioethics
    This briefing note highlights the ethical issues raised by the use of medical implants and the challenges faced by regulatory bodies, manufacturers, and ...
  145. [145]
    [PDF] THE ETHICAL AND LEGAL SIGNIFICANCE OF SUPER SOLDIERS
    Drawing upon premier scholarship on the ethical, legal, and social significance of super soldiers, as well as current and near-future technological innovations.
  146. [146]
    Multipotent bone marrow cell–seeded polymeric composites drive ...
    Two-year study data demonstrate that PRS/stem-cell-seeded grafts drive bladder tissue regeneration and are a suitable alternative to BAE. urinary bladder, ...Abstract · Introduction · Results · Discussion
  147. [147]
    Development of immunocompatible pluripotent stem cells via ...
    Jan 7, 2019 · In this study, we used CRISPR/Cas9 to knockout HLA-B from inducible pluripotent stem cells (iPSCs) with heterogenous HLA-B and showed that the HLA-B knockout ...Endothelial Cell... · Mesenchymal Stem Cell... · Results
  148. [148]
    Vascularization Strategies for Tissue Engineering - PMC - NIH
    Tissue engineering is currently limited by the inability to adequately vascularize tissues in vitro or in vivo. Issues of nutrient perfusion and mass ...<|separator|>
  149. [149]
    Nanotechnology-driven advancements in organ transplantation - NIH
    Aug 25, 2025 · For example, gold nanoparticles are known for their biocompatibility and ability to facilitate targeted drug delivery, whereas carbon nanotubes ...5.1. Ex Vivo Detection · 5.2. In Vivo Imaging Probes · 6.1. Targeted Oxygen...Missing: implants | Show results with:implants
  150. [150]
    https://www.penncerl.org/wp-content/uploads/2024/03/The-Ethical-and-Legal-Significance-of-Super-Soldiers-April-2023.pdf
  151. [151]
    https://doi.org/10.1016/j.cell.2006.07.024
  152. [152]
    AI-driven 3D bioprinting for regenerative medicine: From bench to ...
    This paper aims to present a systematic methodology for AI-driven 3D bioprinting, structured within the theoretical framework of Quality by Design (QbD).
  153. [153]
    When artificial intelligence (AI) meets organoids and organs-on ...
    AI-organoids/OoC partnerships can significantly contribute to the development of precision medicine by facilitating patient classification, predicting patient- ...