Powering Medical Homecare Equipment

Statistics say that we are all living longer (on average), with the best figure achieved by Japanese women at over 87 years, based on 2019 data [1]. Ironically, though, we are also living unhealthier lifestyles, with rates of obesity and chronic illness such as diabetes and heart disease being on the rise. The result is that there is an increasing number of older and unfit people requiring ongoing medical treatment, which puts a strain on healthcare systems.

To alleviate the burden on institutional medical services and improve quality of life, the trend to provide more treatment in home settings has emerged. This has become increasingly effective, with technology facilitating the use of more sophisticated and portable equipment, supported by ‘telehealth’, the remote, electronic provision of health-related services and monitoring. It is now big business and is predicted to be worth over $500B globally by 2028 [2].

We often think of industrial or professional medical environments as being ‘harsh’, with exacting cleanliness and safety standards applied to equipment; however, the operating conditions are at least well defined. In a home setting, there is a host of other variables that can affect the performance of medical equipment, and device designers are required to anticipate these in their risk assessments. Apart from the obvious domestic temperature and humidity variations, equipment can be incorrectly used by insufficiently trained users and carers in an environment that includes children and pets. There may be spilled liquids, household dust, food debris, pet hair, and medical waste also present. The electrical supply may not have an effective ground connection, and excessive voltage dips, spikes, and surges may be present. Moreover, radiated and conducted electromagnetic interference from other household equipment could also affect operation. Operating complex medical equipment may be confusing and difficult for someone who is old or ill.

To address these concerns, medical electrical (ME) equipment in the home setting must meet specific safety, performance, and EMC standards. The top-level document for medical equipment safety and essential performance is IEC 60601-1, and this is supported by the collateral standard IEC 60601-1-11 “Requirements for medical electrical equipment and medical electrical systems used in the home healthcare environment.” Currently, the standard is dated to 2015 with amendment A1:2021.

Particular requirements of IEC 60601-1-11, additional to those in the professional healthcare environment, include the ability of mains-powered equipment to operate with 15% drops in supply voltage from nominal or 20%, if the equipment is intended for life support or resuscitation. In such cases, there must also be a mechanism for maintaining the essential performance of the equipment for a “sufficient” amount of time after the total loss of mains power as well as alarms to indicate the hazardous situation. In practice, this means that this class of equipment must have battery backup with “state-of-health” monitoring and alarms. If the equipment operates on a DC supply, there are also extra requirements to withstand voltage variations and 30 second dips.

A more far-reaching requirement is that AC-powered homecare ME equipment must now be Class II, with no need for a functional earthing. This means that it must be double insulated (Figure 1). The standard still allows Class I ME equipment with a metallic case and protective earthing but only as part of a hard-wired “fixed” installation. Even then, there are stringent requirements for verifying the integrity of the ground connection before use by a qualified installer with additional safety labelling.

To address the potential conducted and radiated EMI emissions problem in a home setting, IEC 60601-1-11 requires all equipment to comply with CISPR 11 (latest edition 2015/AMD2:2019) Class B levels. In hospital environments, Class A is the minimum, which is less rigorous than Class B. Among other changes, immunity to radiated RF must also be enhanced from 3V/m to 10V/m in home settings, as it is more likely for other household equipment to interfere. Additionally, as a new requirement, device basic safety and essential performance must be maintained during the specified levels of interference.

There are many other requirements of IEC 60601-1-11, including environmental, mechanical strength and accessibility, water and particulate ingress, maintenance, labelling, documentation, and more. As ever, a device manufacturer must examine the standards in detail, assess the possible hazards, and address them during the product design stage.

In homecare medical devices, there will most likely also be requirements for on-board non-isolated switching converter power modules to generate various internal power rails. Although the medical standards do not relate to these parts directly, the application will be typically battery-powered for either normal use or as back-up. So, battery lifetime is important. Any DC/DC conversion should, therefore, be as efficient as possible, and perfect solutions can be found in RECOM’s wide range of non-isolated parts in all form factors and power levels.

[1] https://www.nippon.com/en/japan-data/h00788/
[2] https://www.researchandmarkets.com/reports/5450245