Bioresorbable stent


In medicine, a stent is any device which is inserted into a blood vessel or other internal duct to expand it to prevent or alleviate a blockage. Traditionally, such devices are fabricated from metal mesh and remain in the body permanently or until removed through further surgical intervention. A bioresorbable stent serves the same purpose, but is manufactured from a material that may dissolve or be absorbed in the body.

Background

The use of metal drug-eluting stents presents some potential drawbacks. These include a predisposition to late stent thrombosis, prevention of late vessel adaptive or expansive remodeling, hindrance of surgical revascularization, and impairment of imaging with multislice CT.
To overcome some of these potential drawbacks, several companies are pursuing the development of bioresorbable scaffolds or bioabsorbable stents. Like metal stents, placement of a bioresorbable stent will restore blood flow and support the vessel through the healing process. However, in the case of a bioresorbable stent, the stent will gradually resorb and be benignly cleared from the body, enabling a natural reconstruction of the arterial wall and restoration of vascular function.
Studies have shown that the most critical period of vessel healing is largely complete by approximately three to nine months. Therefore, the goal of a bioresorbable or “temporary” stent is to fully support the vessel during this critical period, and then resorb from the body when it is no longer needed.

Base materials

Bioabsorbable scaffolds, or naturally dissolving stents, that have been investigated include base materials that are either metals or polymers. While polymer-based scaffolds had a strong presence at first, they have meanwhile lost some appeal due to safety concerns and focus is now shifted more towards metallic magnesium-based scaffolds.

Metal based

Metal stent candidates are iron, magnesium, zinc and their alloys.
Iron stents were shown using an in vivo evaluation method based on the murine abdominal aorta to generate an iron oxide-filled cavity in the vascular wall. This behavior significantly narrowed the lumen and generated a potential site for rupture of the endothelium after stent degradation.
Magnesium-based scaffolds have been approved for use in several countries around the world. The only commercially available magnesium-based scaffold consists of a magnesium alloy, approximately 95% of which resorbs within one year of implantation. Thousands of commercially available magnesium-based scaffolds have been implanted. Promising clinical results suggest that magnesium-based scaffolds seem to be a viable option in delivering against the drawbacks of permanent stents. While degrading harmlessly, it has been shown to possess a functional degradation time of about 30 days in vivo. This is much short of the three-to-six month window desired for bioabsorbable stents. Thus, much attention has been given to drastically reducing the rate of magnesium corrosion by alloying, coating, etc. Many novel methods have surfaced to minimize the penetration rate and hydrogen evolution rate. One of the most successful has involved the creation of bioabsorbable metallic glasses via rapid solidification. Other, alternative solutions have included the development of magnesium–rare-earth alloys, which benefit from the low cytotoxicity of RE elements. Coatings and sophisticated materials processing routes are currently being developed to further decrease the corrosion rate. However a number of issues remain limiting the further development of Mg biomaterials in general.
Recently, zinc was shown to exhibit outstanding physiological corrosion behavior, meeting a benchmark penetration rate of 20 micrometers per year. This contribution also asserts that zinc alloys generally meet or exceed mechanical behavior benchmarks. While promising, this material is relatively new, so further work is required to prove that zinc is a feasible base material for a stent.

Polymer-based

Polymer-based stents have been approved for use in some countries around the world. These are based on poly, chosen because it is able to maintain a radially strong scaffold that breaks down over time into lactic acid, a naturally occurring molecule that the body can use for metabolism. Other polymers in development include tyrosine poly carbonate and salicylic acid.
An example of a naturally dissolving stent is the 'Absorb' stent 'produced by Abbott that has several design components and features: base scaffold: a poly polymer similar to that in dissolvable stitches is shaped into a tube made up of zigzag hoops linked together by bridges; drug-eluting layer': a mixture of poly-D, L-lactide and everolimus; 'markers': a pair of radio-opaque platinum markers at the ends that allow the device to be visualized during angiography; 'delivery system': a balloon delivery system.
Recently however, Polymer-based scaffolds, in particular Poly-L-Lactide Acid scaffolds, have raised serious concerns on the scaffold performance particularly in terms of safety which led to the commercial discontinuation of the main representative Absorb.

Clinical research

Clinical research has shown that resorbable scaffolds, or naturally dissolving stents, offer comparable efficacy and safety profile to drug-eluting stents. Specifically, the Magmaris resorbable magnesium scaffold has reported a favorable safety profile with low target lesion failure and scaffold thrombosis rates. These clinical results are comparable to thin-strutted drug-eluting stents in similar patient populations.
The Absorb naturally dissolving stent has also been investigated in single-arm trials and in randomized trials comparing it to a drug-eluting stent. Early and late major adverse cardiac events, revascularizations, and scaffold thromboses have been uncommon and similar to the Xience DES, a market leader in the drug eluting stent category. Studies in real-world patients are ongoing.
Imaging studies show that the Absorb naturally dissolving stent begins to dissolve from six to 12 months and is fully dissolved between two and three years after it is placed in the artery. Two small platinum markers remain to mark the location of the original PCI. The artery is able to dilate and contract, called vasomotion, similar to a healthy blood vessel at two years.