Nitinol biocompatibility

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Nitinol biocompatibility is an important factor in biomedical applications. Nitinol (NiTi), which is formed by alloying nickel and titanium (~ 50% Ni), is a shape-memory alloy with superelastic properties more similar to that of bone,[ clarification needed ] when compared to stainless steel, another commonly used biomaterial. Biomedical applications that utilize nitinol include stents, heart valve tools, bone anchors, staples, septal defect devices and implants. It is a commonly used biomaterial especially in the development of stent technology.

Contents

Metal implants containing a combination of biocompatible metals or used in conjunction with other biomaterials are often considered the standard for many implant types. Passivation is a process that removes corrosive implant elements from the implant-body interface and creates an oxide layer on the surface of the implant. The process is important for making biomaterials more biocompatible.

Overview of common passivation methods

When materials are introduced to the body it is important not only that the material does not damage the body, but also that the environment of the body does not damage the implant. [1] One method that prevents the negative effects resulting from this interaction is called passivation.[ citation needed ]

In general, passivation is considered to be a process that creates a non-reactive layer at the surface of materials, such that the material may be protected from damage caused by the environment. Passivation can be accomplished through many mechanisms. Passive layers can be made through the assembly of monolayers through polymer grafting. Often, for corrosion protection, passive layers are created through the formation of oxide or nitride layers at the surface.[ citation needed ]

TiO2 Unit Cell Structure Rutile-unit-cell-3D-balls.png
TiO2 Unit Cell Structure

Oxide films

Passivation often occurs naturally in some metals like titanium, a metal that often forms an oxide layer mostly composed of TiO2. This process occurs spontaneously as the enthalpy of formation of TiO2 is negative. In alloys, such as nitinol, the formation of an oxide layer not only protects against corrosion, but also removes Ni atoms from the surface of the material. Removing certain elements from the surface of materials is another form of passivation. In nitinol, the removal of Ni is important, because Ni is toxic if leached into the body. [2] Stainless steel is commonly passivated by the removal of iron from the surface through the use of acids and heat. Nitric acid is commonly used as a mild oxidant to create the thin oxide film on the surface of materials that protects against corrosion. [3]

Electropolishing

Another mode of passivation involves polishing. Mechanical polishing removes many surface impurities and crystal structure breaks that may promote corrosion. Electropolishing is even more effective, because it doesn’t leave the scratches that mechanical polishing will. Electropolishing is accomplished by creating electrochemical cells where the material of interest is used as the anode. The surface will have jagged qualities where certain points are higher than others. In this cell the current density will be higher at the higher points and cause those points dissolve at a higher rate than the lower points, thus smoothing the surface. Crystal lattice point impurities will also be removed as the current will force these high-energy impurities to dissolve from the surface. [4]

Coatings

Another commonly used method of passivation is accomplished through coating the material with polymer layers. Layers composed of polyurethane have been used to improve biocompatibility, but have seen limited success. Coating materials with biologically similar molecules has seen much better success. For example, phosphorylcholine surface modified stents have exhibited reduced thrombogenic activity. Passivation is an extremely important area of research for biomedical applications, as the body is a harsh environment for materials and materials can damage the body through leaching and corrosion. All of the above passivation methods have been used in the development of nitinol biomaterials to produce the most biocompatible implants. [5]

Influence of surface passivation on biocompatibility

Surface passivation techniques can greatly increase the corrosion resistance of nitinol. In order for nitinol to have the desired superelastic and shape memory properties, heat treatment is required. After heat treatment, the surface oxide layer contains a larger concentration of nickel in the form of NiO2 and NiO. This increase in nickel has been attributed to the diffusion of nickel out of the bulk material and into the surface layer during elevated temperature treatments. Surface characterization methods have shown that some surface passivation treatments decrease the concentration of NiO2 and NiO within the surface layer, leaving a higher concentration of the more stable TiO2 than in raw, heat-treated nitinol. [6]

The decrease in nickel concentration in the surface layer of nitinol is correlated with a greater corrosion resistance. A potentiodynamic test is commonly employed to measure a material’s resistance to corrosion. This test determines the electrical potential at which a material begins to corrode. The measurement is called the pitting or breakdown potential. After passivation in a nitric acid solution, nitinol stent components showed significantly higher breakdown potentials than those that were unpassivated. [6] In fact, there are many surface treatments that can greatly enhance the breakdown potentials of nitinol. These treatments include mechanical polishing, electropolishing, and chemical treatments such as, Nitric Oxide submersion, etching of the raw surface oxide layer, and pickling to break down bulk material near the surface.[ citation needed ]

Thrombogenicity, a material’s tendency to induce clot formation, is an important factor that determines the biocompatibility of any biomaterial that comes into contact with the bloodstream. There are two proteins, fibrinogen and albumin, that first adsorb to the surface of a foreign object in contact with blood. It has been suggested that fibrinogen may cause platelet activation due to a breakdown of the protein structure as it interacts with high energy grain boundaries on certain surfaces. Albumin on the other hand, inhibits platelet activation. This implies that there are two mechanisms which can help lower thrombogenicity, an amorphous surface layer where there will be no grain boundary interactions with fibrinogen, and a surface with a higher affinity to albumin than fibrinogen.[ citation needed ]


Just as thrombogenicity is important in determining suitability of other biomaterials, it is equally important with nitinol as a stent material. Currently, when stents are implanted, the patient receives antiaggregant therapy for a year or more in order to prevent the formation of a clot near the stent. By the time the drug therapy has ceased, ideally, a layer of endothelial cells, which line the inside of blood vessels would coat the outside of the stent. The stent is effectively integrated into the surrounding tissue and no longer in direct contact with the blood. There have been many attempts made using surface treatments to create stents that are more biocompatible and less thrombogenic, in an attempt to reduce the need for extensive antiplatelet therapy. Surface layers that are higher in nickel concentration cause less clotting due to albumin’s affinity to nickel. This is opposite of the surface layer characteristics that increase corrosion resistance. In vitro tests use indicators of thrombosis, such as platelet, Tyrosine aminotransferase, and β-TG levels. Surface treatments that have to some extent, lowered thrombogenicity in vitro are:

Another area of research involves binding various pharmaceutical agents such as heparin to the surface of the stent. These drug-eluting stents show promise in further reducing thrombogenicity while not compromising corrosion resistance.

Welding

New advances with micro laser welding have vastly improved the quality of medical devices made with nitinol.[ citation needed ]

Remarks

Nitinol is an important alloy for use in medical devices, due to its exceptional biocompatibility, especially in the areas of corrosion resistance and thrombogenicity. Corrosion resistance is enhanced through methods that produce a uniform titanium dioxide layer on the surface with very few defects and impurities. Thrombogenicity is lowered on nitinol surfaces that contain nickel, so processes that retain nickel oxides in the surface layer are beneficial. The use of coatings has also been shown to greatly improve biocompatibility.

Because implanted devices contact the surface of the material, surface science plays an integral role in research aimed at enhancing biocompatibility, and in the development of new biomaterials. The development and improvement of nitinol as an implant material, from characterizing and improving the oxide layer to developing coatings, has been based largely on surface science.

Research is underway to produce better, more biocompatible, coatings. This research involves producing a coating that is very much like biologic material in order to further lessen the foreign body reaction. Biocomposite coatings containing cells or protein coatings are being explored for use with nitinol as well as many other biomaterials. [8]

Current research/further reading

Related Research Articles

<span class="mw-page-title-main">Rust</span> Type of iron oxide

Rust is an iron oxide, a usually reddish-brown oxide formed by the reaction of iron and oxygen in the catalytic presence of water or air moisture. Rust consists of hydrous iron(III) oxides (Fe2O3·nH2O) and iron(III) oxide-hydroxide (FeO(OH), Fe(OH)3), and is typically associated with the corrosion of refined iron.

<span class="mw-page-title-main">Corrosion</span> Gradual destruction of materials by chemical reaction with its environment

Corrosion is a natural process that converts a refined metal into a more chemically stable oxide. It is the gradual deterioration of materials by chemical or electrochemical reaction with their environment. Corrosion engineering is the field dedicated to controlling and preventing corrosion.

In physical chemistry and engineering, passivation is coating a material so that it becomes "passive", that is, less readily affected or corroded by the environment. Passivation involves creation of an outer layer of shield material that is applied as a microcoating, created by chemical reaction with the base material, or allowed to build by spontaneous oxidation in the air. As a technique, passivation is the use of a light coat of a protective material, such as metal oxide, to create a shield against corrosion. Passivation of silicon is used during fabrication of microelectronic devices. Undesired passivation of electrodes, called "fouling", increases the circuit resistance so it interferes with some electrochemical applications such as electrocoagulation for wastewater treatment, amperometric chemical sensing, and electrochemical synthesis.

<span class="mw-page-title-main">Anodizing</span> Metal treatment process

Anodizing is an electrolytic passivation process used to increase the thickness of the natural oxide layer on the surface of metal parts.

Plating is a finishing process in which a metal is deposited on a surface. Plating has been done for hundreds of years; it is also critical for modern technology. Plating is used to decorate objects, for corrosion inhibition, to improve solderability, to harden, to improve wearability, to reduce friction, to improve paint adhesion, to alter conductivity, to improve IR reflectivity, for radiation shielding, and for other purposes. Jewelry typically uses plating to give a silver or gold finish.

<span class="mw-page-title-main">Biocompatibility</span> Biologically compatible substance

Biocompatibility is related to the behavior of biomaterials in various contexts. The term refers to the ability of a material to perform with an appropriate host response in a specific situation. The ambiguity of the term reflects the ongoing development of insights into how biomaterials interact with the human body and eventually how those interactions determine the clinical success of a medical device. Modern medical devices and prostheses are often made of more than one material so it might not always be sufficient to talk about the biocompatibility of a specific material. Even the same materials, such as diamond-like carbon coatings, may show different levels of biocompatibility based on the manufacturing conditions and characteristics.

<span class="mw-page-title-main">Pitting corrosion</span> Form of insidious localized corrosion in which a pit develops at the anode site

Pitting corrosion, or pitting, is a form of extremely localized corrosion that leads to the random creation of small holes in metal. The driving power for pitting corrosion is the depassivation of a small area, which becomes anodic while an unknown but potentially vast area becomes cathodic, leading to very localized galvanic corrosion. The corrosion penetrates the mass of the metal, with a limited diffusion of ions.

<span class="mw-page-title-main">Superalloy</span> Alloy with higher durability than normal metals

A superalloy, or high-performance alloy, is an alloy with the ability to operate at a high fraction of its melting point. Key characteristics of a superalloy include mechanical strength, thermal creep deformation resistance, surface stability, and corrosion and oxidation resistance.

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Phosphorylcholine is the hydrophilic polar head group of some phospholipids, which is composed of a negatively charged phosphate bonded to a small, positively charged choline group. Phosphorylcholine is part of the platelet-activating factor; the phospholipid phosphatidylcholine and sphingomyelin, the only phospholipid of the membrane that is not built with a glycerol backbone. Treatment of cell membranes, like those of RBCs, by certain enzymes, like some phospholipase A2, renders the phosphorylcholine moiety exposed to the external aqueous phase, and thus accessible for recognition by the immune system. Antibodies against phosphorylcholine are naturally occurring autoantibodies that are created by CD5+/B-1 B cells and are referred to as non-pathogenic autoantibodies.

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Nickel titanium, also known as nitinol, is a metal alloy of nickel and titanium, where the two elements are present in roughly equal atomic percentages. Different alloys are named according to the weight percentage of nickel; e.g., nitinol 55 and nitinol 60.

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<span class="mw-page-title-main">Cobalt-chrome</span> Alloy of cobalt and chromium used in medical implants

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NiTiNOL 60, or 60 NiTiNOL, is a Nickel Titanium alloy discovered in the late 1950s by the U. S. Naval Ordnance Laboratory. Depending upon the heat treat history, 60 NiTiNOL has the ability to exhibit either superelastic properties in the hardened state or shape memory characteristics in the softened state.

<span class="mw-page-title-main">Titanium biocompatibility</span>

Titanium was first introduced into surgeries in the 1950s after having been used in dentistry for a decade prior. It is now the metal of choice for prosthetics, internal fixation, inner body devices, and instrumentation. Titanium is used from head to toe in biomedical implants. One can find titanium in neurosurgery, bone conduction hearing aids, false eye implants, spinal fusion cages, pacemakers, toe implants, and shoulder/elbow/hip/knee replacements along with many more. The main reason why titanium is often used in the body is due to titanium's biocompatibility and, with surface modifications, bioactive surface. The surface characteristics that affect biocompatibility are surface texture, steric hindrance, binding sites, and hydrophobicity (wetting). These characteristics are optimized to create an ideal cellular response. Some medical implants, as well as parts of surgical instruments are coated with titanium nitride (TiN).

Materials that are used for biomedical or clinical applications are known as biomaterials. The following article deals with fifth generation biomaterials that are used for bone structure replacement. For any material to be classified for biomedical applications, three requirements must be met. The first requirement is that the material must be biocompatible; it means that the organism should not treat it as a foreign object. Secondly, the material should be biodegradable ; the material should harmlessly degrade or dissolve in the body of the organism to allow it to resume natural functioning. Thirdly, the material should be mechanically sound; for the replacement of load-bearing structures, the material should possess equivalent or greater mechanical stability to ensure high reliability of the graft.

Biomaterials exhibit various degrees of compatibility with the harsh environment within a living organism. They need to be nonreactive chemically and physically with the body, as well as integrate when deposited into tissue. The extent of compatibility varies based on the application and material required. Often modifications to the surface of a biomaterial system are required to maximize performance. The surface can be modified in many ways, including plasma modification and applying coatings to the substrate. Surface modifications can be used to affect surface energy, adhesion, biocompatibility, chemical inertness, lubricity, sterility, asepsis, thrombogenicity, susceptibility to corrosion, degradation, and hydrophilicity.

<span class="mw-page-title-main">Surface chemistry of neural implants</span>

As with any material implanted in the body, it is important to minimize or eliminate foreign body response and maximize effectual integration. Neural implants have the potential to increase the quality of life for patients with such disabilities as Alzheimer's, Parkinson's, epilepsy, depression, and migraines. With the complexity of interfaces between a neural implant and brain tissue, adverse reactions such as fibrous tissue encapsulation that hinder the functionality, occur. Surface modifications to these implants can help improve the tissue-implant interface, increasing the lifetime and effectiveness of the implant.

References

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  3. "Passivation of Stainless Steel", http://www.iftworldwide.com/white_paper/passivation.pdf Archived 2018-02-17 at the Wayback Machine
  4. "The Basics of the Electropolish Process", http://www.harrisonep.com/services/electropolishing/default.html
  5. Thierry B, Winnik FM, Merhi Y, Silver J, Tabrizian M. Bioactive coatings of endovascular stents based on polyelectrolyte multilayers. Biomacromolecules. 2003; 4: 1564-1571.
  6. 1 2 O’Brien B, Carroll WM, Kelly MJ. Passivation of nitinol wire for vascular implants a demonstration of the benefits. Biomaterials. 2002; 23: 1739-1748.
  7. Tepe G, Schmehl J, Wendel HP, Schaffner S, Heller S, Gianotti M, Claussen CD, Duda SH. Reduced thrombogenicity of nitinol stents – in vitro evaluation of different surface modifications and coatings. Biomaterials. 2006; 27: 643-650.
  8. Brassack, I. Bottcher, H. Hempel, U. "Biocompatibility of Modified Silica-Protein Composite Layers." Journal of Sol-Gel Science and Technology. December, 2000. Vol. 19, Issues 1-3.