Biomaterial surface modifications: Difference between revisions

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.<ref name=biomaterial>{{cite journal |doi=10.1007/BF00680113 |pmid=8052058 |title=Biomaterials for abdominal wall hernia surgery and principles of their applications |year=1994 |last1=Amid |first1=P. K. |last2=Shulman |first2=A. G. |last3=Lichtenstein |first3=I. L. |last4=Hakakha |first4=M. |journal=Langenbecks Archiv für Chirurgie |volume=379 |issue=3 |pages=168–71|s2cid=22297566 }}</ref> 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, [[Sterilization (microbiology)|sterility]], [[asepsis]], [[Thrombosis|thrombogenicity]], susceptibility to [[corrosion]], degradation, and [[hydrophile|hydrophilicity]].

Plasma modification is one way to alter the surface of biomaterials to enhance their properties. During plasma modification techniques, the surface is subjected to high levels of excited gases that alter the surface of the material. Plasma's are generally generated with a [[Radio frequency|radio frequency (RF)]] field. Additional methods include applying a large (~1KV) DC voltage across electrodes engulfed in a gas. The plasma is then used to expose the biomaterial surface, which can break or form chemical bonds. This is the result of physical collisions or chemical reactions of the excited gas molecules with the surface. This changes the surface chemistry and therefore surface energy of the material which affects the adhesion, biocompatibility, chemical inertness, lubricity, and sterilization of the material. The table below shows several biomaterial applications of plasma treatments.<ref>{{cite webjournal |last=Loh |first=Ih-Houng |workjournal=AST Technical Journal |title=Plasma Surface Modification In Biomedical Applications |year=1999 |volume=10 |issue=1 |pages=24–30 |pmid=10344871 |url=http://www.astp.com/PDFs/PSBiomed.pdf |url-status=dead |archiveurl=https://web.archive.org/web/20080514091530/http://www.astp.com/PDFs/PSBiomed.pdf |archivedate=2008-05-14 }}</ref>

| Biosensor || Sensor Membranes, Diagnostic biosensors || PC, Cellulose,[[Cuprophane]], PP, PS || Immobilization of biomolecules, non-fouling surfaces

[[File:Argon plasma used for polymer surface functionalization prior to bonding.Argon plasma used for polymer surface functionalization prior to bonding.png|125 × 240 pixels.0px|thumb|right|Argon plasma used for polymer surface functionalization prior to bonding.]]

Guide wires are an example of an application for biomedical coatings. Guide wires are used in [[percutaneous coronary intervention|coronary angioplasty]] to correct the effects of [[coronary artery disease]], a disease that allows plaque build up on the walls of the arteries. The guide wire is threaded up through the femoral artery to the obstruction. The guide wire guides the balloon catheter to the obstruction where the catheter is inflated to press the plaque against the arterial walls.<ref name=angioplasty>{{cite web |url=https://www.nlm.nihmedlineplus.gov/medlineplus/ency/anatomyvideos/000096.htm |title= Percutaneous transluminal coronary angioplasty (PTCA) |last1= Gandelman |first1= Glenn |date= March 22, 2013 |work= Medline Plus |accessdateaccess-date=19 May 2013}}</ref> Guide wires are commonly made from stainless steel or [[Nickel Titanium|Nitinol]] and require polymer coatings as a surface modification to reduce friction in the arteries. The coating of the guide wire can affect the trackability, or the ability of the wire to move through the artery without kinking, the tactile feel, or the ability of the doctor to feel the guide wire's movements, and the thrombogenicity of the wire.

Hydrophilic coatings can reduce friction in the arteries by up to 83% when compared to bare wires due to their high surface energy.<ref name=friction>{{cite journal |pmid=8485751 |year=1993 |last1=Schröder |first1=J |title=The mechanical properties of guidewires. Part III: Sliding friction |volume=16 |issue=2 |pages=93–7 |journal=CardiovascularCardioVascular and Interventional Radiology |doi=10.1007/BF02602986|s2cid=7941986 }}</ref> When the hydrophilic coatings come into contact with bodily fluids they form a waxy surface texture that allows the wire to slide easily through the arteries. Guide wires with hydrophilic coatings have increased trackability and are not very thrombogenic; however the low coefficient of friction increases the risk of the wire slipping and perforating the artery.<ref name=techniques>{{cite journal |first1=Andrejs |last1=Erglis |first2=Inga |last2=Narbute |first3=Dace |last3=Sondore |first4=Alona |last4=Grave |first5=Sanda |last5=Jegere |title=Tools & Techniques: coronary guidewires |journal=EuroIntervention |url=http://www.pcronline.com/eurointervention/tools-and-techniques/coronary-guidewires/download_pdf.php |pmid=20542813 |year=2010 |volume=6 |issue=1 |pages=168–9 |doi=10.4244/eijv6i1a24 |url-access=subscription }}</ref>

[[Category:BiologyBiomaterials]]