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Henkel Adhesive Technologies

Henkel Adhesive Technologies

Electrically conductive adhesives in the medical/bioscience market

Conductive adhesives enable electrical interconnections on disposable medical devices, offering flexibility and reliability. Isotropic and anisotropic options direct current flow and simplify manufacturing.
5 min.
A image displays close-up view of Electrically Conductive Adhesive.

In today’s world, reliability is critical when it comes to electronic devices. Technology companies continue to redefine the possibilities with their ability to shrink components and develop cutting-edge technologies within these devices. Electrically conductive adhesives (ECA’s) are becoming essential in the assembly and ruggedization of electronic devices, especially in the medical field. In an interview with Dr. Mark Currie, Senior Scientific Principal at Henkel, we explore more on this topic of ECA’s and their role in the production of electronics.

Electrically conductive adhesives have been available for several decades and provide an alternative to solder as an interconnect solution delivering electrical, mechanical and thermal performance. Solder is very rigid and less malleable and does not share the same flexible attributes as an ECA which is an interconnect hybrid solution of silver dispersed in a malleable polymer matrix. Furthermore, the application temperatures of ECA interconnects lies between 25⁰C and 200⁰C only (chemistry dependent) and can withstand continuous operating temperatures up to 175⁰C.

A image of component being placed onto ECA.

We posed the question, “why are ECA’s becoming the solution for more applications?” An important single question, with four answers to provide context: process, reliability, sustainability, and macro technological breakthroughs.

Process: high density integration has allowed miniaturized solutions to become the norm. When considering a circuit board that is flexible, or contains components that are sensitive to temperature, the interconnect solution must accommodate these challenges. If process temperatures are too high for the board/component combination, CTE mismatches can yield warpage at the board or component levels, resulting in poor interconnect yields. If we consider ECA’s as the counter solution, we provide a low temperature interconnect option - with potentially fast cure times.

Reliability: CTE mismatch can lead to early false/true failures that may not be anticipated down the road. Using a technology solution that can embrace both low temperature process attachment, but high operating temperatures can only be beneficial to field applications.

Sustainability: all solutions must consider this impact. Two aspects of ECA’s that assist are the low temperature and potential fast curing chemistry options that reduce energy consumption.

Macro Technological Breakthrough: the macro drivers of today are causing the medical market to consider how we treat patients. The miniaturization aspect, coupled with both 5G and IoT (Internet of Things) are solution enhancers in the medical market, that were not in scope a decade ago, and provide the biggest impact to the solutions being provided.

Let’s combine those answers and apply them to the medical industry. The past 18 months have provided everyone context to patient monitoring, but as we look into the future, smart technology embracing connectivity with 5G, we find remote patient monitoring in the medical (or bioscience) market and the application subject: sensors.

A image shows wearable wireless body network.

Sensors can be considered solutions that provide signals of a patient’s well-being. Four sensor categories are often referred to: Electrophysiological (EEG, ECoG); Physical (body temperature, skin hydration); Biomedical (blood glucose, sweat composition) and vitals (blood oxygen, blood pressure).

What are the consistent reliability metrics for all these sensor solutions? Indeed, all applications are small electronic assemblies, but they must absorb a patient’s chemical and physical body changes as they are all potentially “wearable”. For the finished assembly to absorb a patient’s movement, flexible circuit boards are commonly used. These boards can be temperature sensitive when being populated with components, and this particular property, combined with the mandatory interconnect flexibility, allows ECA’s to be the current dynamic trend in medical remote patient monitoring capitalizing on 5G and the Internet of Things (IoT).

Our first flexi-board “wearable” application example that embraces ECA’s is the glucose monitoring disposable patch. This patch is about the size of a silver dollar and the width of your finger and is comprised of very small and sensitive components that benefit from the low application and cure temperature of an ECA and its inherent flexibility.

This is a photo of an attractive and sporty young woman with medical device for glucose check on her arm stretching outdoors.

Another medical device that requires the flexibility and low curing temperature during assembly is the ECG sensor adhesive bandage used for continuous cardiac activity monitoring. In this application, reliability is essential and the correct chemistry choice of the ECA carrier system is paramount to absorb all motion stress.

Next, are hearing aids, which themselves are rigid and will not flex during their use. However, they are made up of softer plastics and contain other temperature sensitive components that could be damaged during the assembly process using traditional solutions.

Gait sensors can be placed in the shoe of a person to monitor their stride and diagnose a problem. These sensors need to bear the weight of the person and they need to be flexible to adjust to the shape of someone’s foot.

“Bioscience applications are clearly going to develop as technology evolves,” says Currie, “and closed loop remote patient feedback monitoring is very much now and the future, and ECA’s fit in as one key enabling technology solution”.

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