Healthcare Hygiene magazine February_2020 | Page 8

under the microscope By Rodney E. Rohde, PhD, MS, SM(ASCP)CM SVCM, MBCM, FACSc Walking Through the Microscopic Valley of Death H ave you ever stopped and thought about how fortunate we are to live during this time? I am talking about the advancement of healthcare in general and medical procedures/devices in particular. Take a moment to consider how an artificial hip or knee may have changed a loved one’s life. What about the diagnostic medical devices utilized for visualizing possible life-threatening conditions or disease? Truly, I think we all probably take these wonders of medical science for granted. Globally, medical devices have prolonged our lives, as well as improved the quality of life for millions. Most of us probably think of replacement knees and hips, vascular stents and pacemakers as representative of these engineering marvels. Endoscopes and catheters, used for diagnostic and therapeutic procedures, are categorized as medical devices too since they are placed into the body and retain their original form. To clarify, a needle that is inserted into the body is classified as a medical device, but the solution injected through that needle is specifically classified as a pharmaceutical. Given that medical devices enter the body, the need to be free of contamination is paramount for patient safety. Berkshire Corporation, via U.S. Food and Drug Admin- istration (FDA) guidelines, explains contaminants and their removal well. Prior to the introduction of the device into the body (whether temporarily for diagnostic purposes or permanently for therapeutic purposes), we want it to be as free of contaminants as possible. Medical device contaminants can include traces of lubricants, oils, and other processing residues (e.g. polymers, adhesives), viables (microorganisms), and non-viables, such as particles and fibers. In the manufacturing process, medical devices are packaged and then terminally sterilized as the last step. The sterilization procedure does not remove contaminants; it only ensures that any viables left on the device cannot proliferate further–any residual surface contamination left on the device before sterilization remains after the process and can pose a risk to patient safety. Fortunately, simple wiping techniques employed with proper wipers and solvents prior to packaging and sterilization can produce a clean medical device. The FDA Center for Devices and Radiological Health (CDRH) Microbiology and Infection Control states that with the increased use of medical devices and their promise to improve quality of life, preventing device-associated infection is a top public health priority. Every medical device is prone to microbial colonization and biofilm formation, resulting inevitably in device failure and patient harm. In addition, the association of colonized devices with development of drug resistant organisms is a serious 8 and under-investigated area of importance. The Medical Device Biofouling and Biofilms Research Program addresses medical-device failure and patient harm caused by the combined effects of biofouling, colonization, and biofilms. Rather than study these phenomena as individual events, the research uses sophisticated high-throughput microfluidic approaches to assess how variables such as biofouling, cleaning and material properties affect bacterial adhesion and biofilm progression. The group uses optical and electron microscopy, surface plasmon resonance (SPR), and other biosensing and surface analysis methods to study biomolecular interactions at the interface of device, host and microorganism. In laymen’s terms, this group is trying to determine the best way(s) to understand not only what invisible inhabitants are found in the microscopic valley of death (aka surfaces), but how to best remove (clean and sterilize) them. Some of the current research areas addressed include: —Bacterial interactions with soft medical device materials (contact lenses, dermal fillers, ophthalmic surgical devices — Development of better test methods and endpoint measurements for antimicrobial device technologies (wound dressings, catheters) — Biofilm specific diagnostics (optical coherence tomography, biomarkers) — Detection of biofouling and biofilm on reprocessed devices (endoscopes, surgical tools) — Influence of material, device design, roughness, and presence of soil on cleanability — Performance testing of one-way valves Intended to prevent cross-contamination and infections in patients — Reprocessing flexible endoscopes — Chemically defined clinically relevant test soils for cleaning validation of reusable medical devices While medical advances and devices have advanced the health of civilization in ways we never fathomed, let us not forget that the microorganisms have outpaced human advancement every step of the way, including finding ways to survive the microscopic valley and surfaces of arguably every niche known.  Rodney E. Rohde, PhD, MS, SM(ASCP)CM SVCM, MBCM, FACSc, serves as chair and professor of the Clinical Laboratory Science Program at Texas State; associate director for the Translational Health Research Initiative; as well as associate dean for research in the College of Health Professions. Follow him on Twitter @RodneyRohde / @TXST_CLS, or on his website: http://rodneyerohde.wp.txstate.edu/ february 2020 • www.healthcarehygienemagazine.com