The Significance and Growth of Antimicrobial Technology in Medical Devices

09/27/2021

The antimicrobial technology remolds the usage of medical devices, helping in safe and secure treatments. However, the interaction of medical devices is risky as reuse in different bodies internally and externally. Therefore, it is necessary to make sure to clean it and protect it from microbes. The wide range of growth of microbes can lead the human body to death. Is it that serious? Let's understand the whole concept by having a detailed reading.

Antimicrobial Technology

Antimicrobial technology helps to retrain from the interaction of microbes such as bacteria, mildew, mold. In addition, it helps to remove the microbes from the substance that is overused in different hands-on multiple times. Especially in hospitals, doctors use the same medical devices to treat patients. To make them clean, they use different types of sterilized methods to make them bacteria-free. Antimicrobial technology makes it more comprehensive and practical to do so. 

The chemicals provide a higher level of medical devices protection than antibacterial agents. The compound of broad-spectrum antimicrobial efficacy makes them ideal for usage in hygiene-sensitive areas, including institutions, hospitals, cafeterias, and pool areas. Antimicrobial protection prevents the formation of germs that cause stains and odors, which can harm a product's aesthetic and structural properties. 

Now the recent study shows that antimicrobial technology saves life by protecting from infectious bacteria. The increasing demand for antimicrobial plastic and coating in the healthcare industry is the new effort we see to minimize hospital errors.

Research on Antimicrobial Technology

The issue is not particular for specific hospitals, but it is general and expected in every healthcare institution. Infection is a concern with every operation, but medical equipment like hip replacements and catheters may be particularly problematic. Biofilms, which are groupings of microbes that cling to surfaces, can coat medical equipment like these. When bacteria form biofilms, treating related illnesses becomes considerably more difficult. Long-term and recurrent infections might result, necessitating repeated antibiotic treatments at an irregular dosage. This method of treatment is harmful to patients and can permit bacteria to develop, resulting in resistance. It also causes Candida and Clostridium difficile Pseudomonas pathogens in "normal flora" areas such as the gut and skin, where bacteria are exposed to selection pressure. 

Andrew Hook and colleagues identified a novel family of biofilm-resistant plastics in a recent study. Furthermore, Roger Bayston has devised a method for impregnating silicone catheters with several antimicrobials. Avoiding a broader spectrum of infections with long-lasting action is a significant improvement over prior antimicrobial impregnation methods. Medical equipment might be made considerably stronger and resilient to biofilms by merging these approaches, but several obstacles are overcome. The goal of this study is to find answers to four essential questions:

  • Is the best loading technique affected by the insertion of a coating?
  • Are these gadgets immune compatible, according to preliminary tests?
  • Is it possible to regulate the pace at which antimicrobials are released by altering the coating's qualities?
  • Is it possible to provide antimicrobials via an anti-adhesive coating?

Findings and Results

Infections caused by medical devices, notably catheters, on which most of the prior research has concentrated, are a chronic problem for doctors and patients. Our present treatment methods are ineffective, require a high amount of antimicrobials, and enhance the risk of microorganism susceptibility. Combating biofilm development on medical devices might help us achieve several goals: 

  • minimize the number of infections among patients; 
  • reduce our antibacterial usage to prevent the spread of resistance.
  • Prolong the life of medical instruments;

If acceptable, the combined method may be extended to additional devices such as central venous catheters and wound drains, endotracheal and nasogastric tubes, and urine catheter consumers for which there is no suitable replacement.

Integrating antimicrobial additives   

The manufacturing of antimicrobial plastic by integrating antimicrobial additives, discover the new and effective use of it. It is directly manufactured by adding additives to medical devices and equipment. This technology is highly recommended to all devices and main touching points, including buttons, handles, machine surroundings, stretchers, wheelchairs, etc. Chlorhexidine or Ammonium compounds are examples of antimicrobial agents that can be used in antimicrobial-treated goods. 

The antimicrobials materials such as silver ions are used to make antimicrobials addictive. Silver ion is a foolproof effective ion for healthcare applications with outstanding efficiency. In addition, it is a widely used antimicrobial agent because of its shown efficacy in preventing the formation of dangerous bacteria.

Silver is now utilized in a variety of medical equipment, including catheters and wound treatment. Additives have different forms like powder, liquid, and masterbatch pallets. You can use them according to the suitable products. Also, it depends on the production process of your products. An antimicrobial surface technology, a particular silver-containing zeolite reacts with dampness in the atmosphere, releasing silver ions that prevent biological membrane development and oxygen. Meddling with cell development reduces the number of bacteria that accumulate between cleanings. 

Benefits of Antimicrobial Technology

Once the antimicrobial is employed in the medical devices, it is all set to fight bacteria, fungus, mold, mildew, and other viruses. It is no doubt carefree technology that widely emphasizes the protection of patients and their health. Doctors and surgeons also feel comfortable reusing the devices. They know the integrated antimicrobial technology saves their time to think whether the device is clean or not with any microbes.

To safeguard equipment and medical devices also increases the lifetime, escape from stains, odors, and other unnecessary changes. Medical devices are expensive but worth investing in. You have to take care if you want to run long-term. Those medical devices that contain antimicrobial technology make it possible to retain them for years.

For instance, the number of microorganisms on a plastic surface covered with our technologies may be decreased by up to 86 percent in 15 minutes and up to 99.99 percent in 24 hours. As a result, patients will take advantage of it, and doctors also diagnose the patient's situations in less time with accuracy. 

The Market growth of Antimicrobial Medical Devices

Everything that benefits the consumer helps to grow the market. Same for antimicrobial technology, as the demand increases in the healthcare industry, it is expected that the market growth will rise as time goes. Antimicrobial plastic's compound yearly growth rate is approximately 10.1%, from $36.9 billion in 2020 to $59.8 billion by 2025. Furthermore, according to Grand View Research, the market would grow at an annual rate of 8.2% from 2020 to 2027. Healthcare is reported to have dominated the market, with medical devices accounting for over 45 percent of current manufacturing. According to MarketsandMarkets and Grand View Research studies, the healthcare end-use category contributed to more than 31 percent of worldwide sales in 2019.

Furthermore, according to a ReportLinker report on global coatings for medical devices, the antimicrobial component will sprout at a 6.3 percent compound annual growth rate (CAGR) to reach $5.3 billion by 2026 (the total global market for coatings for medical devices is expected to reach $14 billion by 2026, growing at a CAGR of 5.8 percent). 

The diversity of BioCote's healthcare industry partners – and the types of goods they manage – has increased in recent years. For example, they collaborate with producers of breathing networks, aerosol treatment devices, ventilators, and vaginal dilators, catheters, and endoscopes.

Manufacturers of disposable or surgical gloves and staff pagers are among the other suppliers. We also work with companies that make antimicrobial bedding, diagnostic tables, and patient stretchers, as well as supportive and affordable restroom products. 

Other most frequent surfaces, such as doorknobs, levers, buttons, flooring, wall cladding, and lights, typically use antimicrobial technology.  

What are the Benefits of Antimicrobial-Treated Products in Medical Facilities?

All patients and staff contact surfaces, including handrails, doorknobs, and medical gadgets. Because they act as transmission locations for contagions, these materials can pose a substantial health concern. On the other hand, Antimicrobial-treated surfaces can inhibit the development of germs and prevent the spread of dangerous pathogens. 

This decreases the chance of a Healthcare-Associated Infection by reducing patient and staff interaction with different viruses and bacteria. In addition, because silver-based antimicrobials have lower toxicity than abrasive chemical cleansers, they pose less danger to employees. 

Bottom line

Meditech is getting stronger day by day, and it will remain ongoing to serve the human world. Although there is a long way to go in the healthcare industry, researchers tirelessly work together to better treat humans with maximum efficiency. Antimicrobial technology is a fast-growing field, and antimicrobial solutions will soon be in high demand in the healthcare business. When used in conjunction with frequent washing with a mild solution and proper hygiene practices, antimicrobial-treated products can be practical tools in battling Healthcare-Associated Infections. 

As antibiotic-resistant bacteria and other microbes develop resistance to the medications now used to treat ailments, the need for antimicrobial coatings is rising and will keep rising. Moreover, it might pave the way for potentially exciting new approaches to combat infections caused by biomedical equipment and devices.