GR1010504B - Self-sterilizing heat-activated surface/film for the rapid killing of pathogens - Google Patents

Abstract

The invention relates to a new self-disinfecting, thin and flexible surface (film) that bears built-in heating elements allowing said film to heat up and return to room temperature in a very short time, immediately eliminating pathogenic organisms. This invention is realized by application of the film to high-use surfaces coming in contact with the skin, such as door handles, knobs, furniture, medical instruments, carts, hospital equipment or even protection masks that are susceptible to contamination.

Description

TITLE

SELF-STERILIZING, HEAT-ACTIVATED SURFACE/FILM FOR RAPID KILL OF PATHOGENS

DESCRIPTION

Technical Field

The technical field of the invention is films, surfaces that can be disinfected by heating. The invention refers to a new self-disinfecting, thin and flexible surface (film/film) that has built-in heating elements that allow it to heat up and return to room temperature in a very short time with the immediate effect of eliminating infections transmitted to the community CAIs (Community-Acquired Infections (CAIs)) and HAIs (Hospital Acquired Infections - HAIs), caused by direct contact with contaminated surfaces. This is achieved by applying a rapid, thermal shock to the pathogens on its surface, killing them. This invention is applied by surface application (film placement/embedding) to high-use tactile or skin contact surfaces such as door handles and knobs, furniture, medical instruments, carts and equipment, hospital equipment or even masks protection that are susceptible to contamination. The rapid return of the temperature to the ambient temperature allows use without the risk of burns.

Prior art

Community-Acquired Infections (CAIs) - such as COVID-19 - are infections acquired by the general population in a non-medical setting. CAIs pose a major global risk since they are not limited to a health care setting and can easily spread to congested places through direct (person-to-person) or indirect (via contaminated surfaces or objects) transmission. The recent experience of COVID-19 has revealed the magnitude of the problem and forced governments to take extreme hygiene measures. Surface disinfection has become an undeniable requirement not only in healthcare settings but also in high-traffic areas, including supermarkets, restaurants, public transport, gyms and communal areas.

In addition to CAIs, Hospital Acquired Infections (HAIs), are infections that affect patients and health care personnel in hospitals and other health care facilities that are not present on admission [Haque et al., 2018], HAIs they are a constant threat as they are responsible for millions of deaths worldwide every year. The prevalence of HAIs is extraordinary: of every 100 hospitalized patients, 7 patients in developed and 10 patients in developing countries will acquire at least one healthcare-associated infection (WHO, fact sheet on HAIs). The prevalence of HAIs in Greek hospitals is ~9% (Gikas et al. 2002), one of the highest rates in the European Union (Cassini et al., 2018). Slightly lower rates exist in the USA and other developed countries (Klevens et al., 2007) (Martone W. et al., 1992). According to the European Center for Disease Prevention and Control, more than 4 million episodes of HAIs are reported each year in Europe (World Health Organization, 2011), corresponding to ~40,000 deaths. In addition to morbidity and mortality, CAIs and HAIs cause a prolonged medical stay and a marked increase in the annual cost of medical care.

The spread of CAIs and HAIs through indirect transmission is caused by viruses, bacteria, and microorganisms that are transferred from a contaminated surface to a person. In a health care facility, the presence of contaminated surfaces (eg door handle, medical instruments, etc.) is very common. These pathogens can survive for a long time on surfaces and even colonize temporarily on workers' hands (Weber D. et al., 2010). The risk of developing such an infection is higher in low- and middle-income countries mainly due to poor sanitation (WHO, 2011).

Two main criteria are used to assess the microbiological status of contaminated surfaces (Dancer SJ, 2004): (i) the presence of a specific pathogen marker and (ii) the total number of colonies in Colony Forming Units per cm<2> of surface area (CFU/ cm<2>). Scientific trials have established a limit of less than 5 CFU/cm<2> on all hand contact surfaces in order to minimize HAIs (Dancer S.J., 2004). Chemical methods of decontamination with liquid disinfectants and foams - such as hand washing and frequent surface cleaning - are the gold standard. In fact, most organisms can persist for a long time on surfaces - from a few days to a few months (Kramer A. et al., 2006) - and it is impractical to perform frequent cleaning to keep surfaces disinfected. Thus, according to surveys in many healthcare facilities, more than half of the surfaces examined were found to be insufficiently clean. The World Health Organization (WHO) maintains that effective hand hygiene is the most important practice to prevent HAIs (Pittet D. et al., 2016). While current practices focus on improving hygiene protocols and specifically hand hygiene, several research efforts have been made to develop and implement new disinfection technologies (Humphreys H., 2014). Ultraviolet light (UV) has been proposed for the disinfection of contaminated surfaces (Casini B. et al., 2019) (Chang J. et al., 1985). Ultraviolet light has been shown to contribute to a radical reduction in the survival of micro-organisms and bacteria. This technology requires the use of powerful UV lamps that must be installed in hospital rooms. A major disadvantage of UV light is its reduced effectiveness in disinfecting shaded surfaces, which has led to the limited practical use of this technology (Andersen B. et al., 2006). In addition, UV exposure cannot be used in high traffic areas or in public areas, e.g. corridors and waiting rooms, as staff and patients cannot be exposed to UV light. An improved variation of the above technology is the use of surface coatings with UV light (Foster HA et al., 2011) (Hwang et al., 2020). These coatings produce cytotoxic substances and cause a marked decrease in the survival of microbial colonies. However, they do not sufficiently affect all different types of pathogens and are difficult to apply in a clinical setting as they require a constant source of photoactivation.

Coatings impregnated with metals, such as silver or copper, have also been studied as self-sterilizing surfaces and have been shown to be effective for up to several hours (Schmidt M. et al., 2012). However, these metal surfaces must be coated with corrosion inhibitors that reduce the effectiveness of their antimicrobial action. A similar approach based on coatings containing quaternary ammonium silyloxide and titanyloxide moieties was shown to effectively reduce the number of CFU/cm<2> for weeks (Tamini A. et al., 2014). This claim remains highly questionable as the validation process was combined with normal cleaning procedures and even in the second week of use, some of these coatings were found to not meet the critical threshold of less than 5 CFU/cm<2>. More recently, surfaces with geometric micropatterns have been proposed as a potential solution to prevent microbial attachment (Xu et al., 2017). Several geometries consisting of micropillars or microchannels have been developed (Mann E. et al., 2014) but no clinical validation of this technology nor pathogen reduction rate has been reported.

The above technologies have been applied in various uses such as the 'PullClean' door handle (Altitude Medical Incorporated). It's a low-tech handle that incorporates a hand sanitizer — contained in a single-use container — into a door handle. The downside of this product is that it relies on the individual's willingness to use it, making it difficult to predict its effectiveness. Moreover, it is difficult to imagine how such a handle can be integrated into every surface of a hospital or public space. Accordingly, the application of UV radiation to doorknobs has been reported, but with difficulty in application due to the fact that the radiation must not come into contact with the user, the high cost of installation and operation (energy-consuming) and the requirement for a special configuration of the surrounding area.

Heating technologies have been implemented to disinfect surfaces using metal heating resistors below or integrated with the surface. The main problems of this application are the high thickness of the film that contains the heating elements, the lack of flexibility of the film, the high current consumption that makes it prohibitive on large surfaces and the significant time required for the surface to return to room temperature as a result it is only suitable for applications where it does not come into frequent contact with the skin. Heating systems for use in the disinfection of medical instruments (CN104622542B, CN204484251) have been reported for the purpose of transmitting heat to other media to sterilize them. Heating elements have been used in door handles CN108543103A, CN111852182, but they do not solve the problem of rapid heating and cooling to prevent burns since the whole handle is heated, while the user is forced to wait for a long time until it cools down.

Summary of the invention

The invention discloses a thin and flexible film (film) (hereafter film) (Figure 1) which has micro-heaters integrated in its body or on its surface which can instantly heat the surface, and which is then cooled within seconds at ambient temperature and results in the reduction of CAIs and HAIs by applying a rapid, thermal shock to the pathogens on its surface, killing them. The film consists of a thin layer (layer 1) of non-conductive material that provides mechanical support and thermal insulation and a second layer (layer 2) that incorporates the microsensors and provides direct heating of the surface by applying an appropriate voltage. Optionally the film consists of an additional layer of non-electrically conductive material, which provides protection for the skin when touched. The film has electrodes that are connected to the microsensors. By applying an appropriate electrical voltage, the film is heated by activating the micro-heaters (Figure 2) and thus the pathogens on the surface of layer 2 or 3 are killed as soon as the micro-heaters are activated. The small thickness of the film and the technology used to manufacture it allow its temperature to quickly change from a temperature that kills pathogens to ambient temperature in a few seconds so that it can be used in applications that require periodic contact with users.

In some implementations this film is placed / embedded on high touch surfaces such as door handles and knobs, furniture, medical carts and equipment or even protective masks.

Description of the figures

Figure 1. (A) Implementation where the film (1) is placed on top of a door handle (2) and is connected by a cable (3) to a source of electricity. (B) Embodiment where the film, consisting of 3 layers (1,2,3), in section. Layer 1 is <500 µm thick and is made of low thermal conductivity material. Layer 2 is 0.1-5 µm thick and is electrically conductive. Layer 3 is 1-100 μm thick and is made of a non-electrically conductive material, preferably of high thermal conductivity and mechanical strength. A microheater array (III) provides local, ultra-fast heating. The film also incorporates touch sensors (I) and grooves (II). (C) The film (1) placed on a high frequency touch surface (2) which must be kept disinfected.

Figure 2. (A) Top view of the membrane in one embodiment, showing a microheater array architecture consisting of 6X3 modules. In this embodiment, each unit of the array is ~2 mm x 2 mm. The design is flexible as it can easily be scaled in size to cover different sized areas. Symbols indicate: I: Terminal, II: Microheater array, III: Grooves. (B) The aluminum is connected to a power source (I) and to a microcontroller (II) to precisely control its activation. The images do not show the touch sensors that have been used in some implementations.

Figure 3. In some embodiments, the film fabrication process consists of 4 steps: (I) Layer 2 Deposition, (II) Pattern Transfer to Layer 2, (III) Layer 3 Deposition, (IV) Selective Material Removal from Layer 1 In this particular embodiment, the membrane consists of 3 layers as indicated by the different coloring. In this particular embodiment step IV is used to make the grooves in the substrate (layer 1) that allow the foil to attach to non-flat surfaces as well as to minimize heat loss.

Figure 4.

(A) The 2D heat transfer model used to simulate the thermal performance of the film composed of 4 materials: I: LAYER 1 (silicon), II: LAYER 2 (silica), III: Air, IV: High frequency surface touch (at ambient temperature).

(B) The time-dependent temperature profile of the top layer (layer 2) for different substrate thicknesses (100–500 μm) when a 1 s electrical pulse is applied. The arrow shows the duration of heating/disinfection.

Detailed description and examples

The function of the film is based on the application of voltage so that the built-in micro-heaters rapidly increase their temperature to 60-150°C instantly killing pathogens on its surface. Due to the small thickness of the film (in some embodiments the microheaters are less than 200 nm thick), heat is localized only to the top layer of the film, and the heat dissipation and heat transfer rates are extremely fast (in ms).

In one embodiment, this film consists of a thin layer (layer 1) of non-conductive material that provides mechanical support and thermal insulation and of a second layer (layer 2) that incorporates the microsensors and provides direct heating of the surface by applying an appropriate voltage. In some embodiments the layer 1 has a thickness of less than 500 µm to be flexible while in some embodiments it is made of polymer or silicon or glass. Layer 2 is in some embodiments 0.1 to 5 µm thick and is made of a metal or a semiconductor or a conductive polymer. In some embodiments layer 2 also incorporates touch sensors.

In some embodiments the film consists of an additional layer of non-electrically conductive material such as glass or polymer which provides protection for the skin upon contact.

In addition, in some embodiments layer 1 is grooved on the side not in contact with layer 2, the grooves are optional and have a dual role: they make this layer flexible and provide thermal insulation as the trapped air in them has a low thermal conductivity. Implementations with the three layers are shown in Figure 1B.

In some embodiments, the microheaters are distributed uniformly in the layer 2 to ensure homogeneous heating of the surface 2 and/or 3 in the event of their activation.

Pathogens on the surface of layer 3 are killed when the microheaters are activated by applying voltage to their tips. The heating can be instantaneous while due to the small thickness of the film its surface returns to ambient temperature in a few seconds or in fractions of a second as soon as the voltage is cut off. The function of the film to disinfect its surface requires a power supply and optionally a microcontroller that determines the time of voltage application and the intensity of the supply (determines the maximum temperature that the film will reach).

In one embodiment the membrane system operation sequence is as follows, voltage is applied to the ends of the membrane to which the micro-heaters (with electrodes) are connected, they are activated, the disinfection temperature is reached very quickly (in tens of msec), while after a short certain time interval (in some implementations 300-500 ms) the micro-heaters are turned off allowing the film surface to reach room temperature in fractions of a second (in ms). In another embodiment the heating of the film is activated by the contact of the surface of the film with the skin or with another surface so that the sequence of operation is as follows: (1) the microheaters are initially deactivated, (2) the person touches the upper surface of film, (3) the film detects this event through the built-in touch sensors and activates the micro-heaters immediately after the person stops touching the surface, (4) the disinfection temperature is reached very quickly (in tens of msec), (3) after certain time interval (eg 300-500 ms) the micro-heaters are switched off allowing the film to reach room temperature in fractions of a second (in ms). According to tests, it is possible to complete this thermal cycle in less than one second.

The concept of rapid heating and cooling is widely used in the food processing industry (eg ultra-pasteurization of milk), but has never been applied to surface disinfection. For example, E.Coli bacteria become inactive in 0.4 seconds when heated to 72°C (Sorqvist et al., 2003), while hepatitis A viruses are instantly inactivated at 85°C (Bidawid et al., 2000) in the literature there is full list of inactivation times and temperatures for common bacteria and viruses, see 'BOIL WATER' Technical Brief from WHO, 2015) while different temperature and time parameters are applied for different pathogens.

Implementation

The design of the film was based on recent advances in flexible, wearable electronics (Kim et al. 2012) and flexible, MicroElectroMechanical Systems (MEMS) sensors (Xu et al., 2003) as various microfabrication processes have been developed to create flexible MEMS devices. - micro heaters.

In one embodiment, as shown in Fig. 2, integrated micro-heaters (meander type) are used to provide uniform heating throughout the area. This particular design shows an array of 18 microheaters connected in series with the number varying depending on the surface area of the film.

In different implementations the micro-heater array is powered by a DC or AC power supply, by a battery or even by an energy recovery mechanism from the environment. An electronic microcontroller is optionally used to control the duration and electrical power of the actuation.

In a prototype developed in one embodiment, standard microfabrication processes are used, used to make microheater devices - MEMS. Figure 3 shows the 4 steps of the process followed. In some implementations, materials established in the MEMS field have been used. For layer 2, in some implementations we used metal and preferably Al, Cr/Au, ITO or polysilicon. For layer 3 in some embodiments, a thermally stable plastic and preferably parylene, or SiO 2 , or silicon nitride were used.

To mass produce the film (to reduce costs), a roll-to-roll production process using only metal and plastic materials or processes used to manufacture PCB boards in the electronics industry were used in some embodiments. The production process of the film by standard microfabrication processes, used to make MEMS microheater devices follows the steps:

A layer of conductive material (layer 2) which constitutes the microheaters is deposited uniformly on a thermally non-conductive substrate, while in some embodiments a coating of a protective electrically non-conductive material layer is placed. In some embodiments, grooves are created in the substrate to allow it to be attached to non-flat surfaces as well as to minimize heat loss.

To mass produce the film and to reduce costs, we used in some implementations roll-to-roll manufacturing processes where only metals and plastic materials are used while in other implementations we applied processes used to manufacture PCB boards in the electronics industry. Roll-to-roll processing is a process of manufacturing electronic devices on a flexible roll usually made of plastic or glass. The desired design is transferred to the roll by photolithography or printing techniques. The following two tables (table 1 and table 2) summarize the two methodologies (with reference to the respective materials) by which the membrane can be manufactured.

Table 1. Film production steps with microfabrication/MEMS processes applied in different implementations

Table 2. Production steps of the interfacial film in different implementations

sia Roll-to-Roll (Roll-to-Roll) that were applied

* ITO is a transparent metal/oxide. It is suitable for applications where functionality and aesthetics are important (eg glass doors, mirrors).

Functional confirmation with simulations

A 2D heat transfer simulation (in COMSOL) was performed to demonstrate its operation computationally. The aim was to demonstrate theoretically that a simple thermal cycle consisting of a heating phase, a disinfection phase (steady state/temperature) and a cooling phase can be completed in about one second. We aim for the duration of a single thermal cycle to be 1 s. Practically - the period between two successive activations - membrane touches is expected to be at least a few seconds.

The COMSOL model (using commercially available software for simulations of physical processes, known in the literature) (Joyti B. et al., 2016) consists of a substrate (layer 1) of silicon of various thicknesses (100 - 500 μm) and a SiO2 film ( glass) (layer 2) 5 μm thick with built-in microheaters on which the pathogens are hypothetically deposited (Figure 4A) In the simulation, the density of the SiO2 film (layer 2 in Figure 3A) is 2500 [kg/m<3>], the thermal conductivity is 1.4 [W/mK] and the thermal capacity is 750 [J/kgK], The density of silicon (layer 1) is 2320 [kg/m<3>], the thermal conductivity is 1.49 [W/mK] and the heat capacity is 678 [J/kgK], Dynamic viscosity, density, thermal conductivity and thermal conductivity of air are used according to the COMSOL database.

We assumed that the heat is transferred to the air by free convection and that the bottom of the silicon substrate is connected to a brush (e.g. to the door handle). We also assumed that the glass film is heated uniformly. We simulated the time-dependent temperature of the glass film when an electrical pulse activates the microheaters for 1 second. The results confirm the following (figure 4B): 70 ms and 400 ms are needed to reach the 100 µm and 500 µm thick silicon substrates - from room temperature - to the target temperature of 150°C respectively. A similar time response was obtained during the cooling phase. The decontamination phase (where the temperature is constant) lasted ~800 ms and ~200 ms for the 100 µm and 500 µm silicon substrates respectively. It should be emphasized that very short response times are expected, since heat transfer rates at the microscale are extremely fast. Previous studies suggest that such brief heat shocks are sufficient to instantly kill any pathogens deposited on contaminated surfaces (Parry JV et al., 1984).

The electrical power required to complete a complete thermal cycle was ~ 10<9>x 10<11>W/m<3> (depending on substrate thickness). This means, for a door handle (0.01 m<2> total area), a typical car battery will last thousands of cycles. For surfaces that are used very frequently (eg hospitals), it may be advisable to connect the heating system to the film with an AC supply. If the target temperature is lower (eg 100°C), then the power consumption will be significantly reduced. It should be mentioned that in the unlikely event that someone touches it while it is still warm, the temperature of human skin will not rise significantly. This is due to the large heat capacity of human tissue compared to the heat capacity of the membrane. The above results demonstrate the operating range of the film and provide an estimate of its expected thermal performance.

The use of the film warmer is intended to significantly improve hygiene and thereby minimize the transmission of HAIs and CAIs. It can be integrated into existing surfaces without making their use difficult. Thus, a heating device based on said film is scalable in size and versatile in design, and can have many uses on surfaces in contact with users such as being placed over a hospital door handle, on a taxi door handle, on a stair railing in a concert hall, on the floor, on surgical instruments and medical instruments to ensure the removal of pathogens. The speed of heating and returning to room temperature make it safe for use by the public. Potentially low manufacturing costs and minimal maintenance also make it an ideal solution for use on any high touch frequency surface.

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41. CN104622542B, (WANG YANJUN, 2/15/2017

42.CN204484251U, (WANG YANJUN), 7/22/2015

43.CN108543103A, (ZHOU ZHIYI), 9/18/2018

44.CN1 11852182, (ZHOU ZHIYI), 10/30/2020

Claims (5)

New set of claims 1 A method of fabricating a film comprising a thermally stable and electrically insulating substrate and an array of connected micro-heaters, which are embedded in the surface of the substrate and are less than 5 µm thick, and which film is configured to be heated by applying current to array of micro-heaters, and which method includes at least the step of uniformly depositing, on a thermally non-conductive substrate, a layer of conductive material which can be heated by applying voltage to the micro-heaters, and where the coatings and depositions of the materials are made with the roll to roll method. 2. Use of a heated film, which is manufactured by the manufacturing method of claim 1 or by another method, which includes a thermally stable and electrically insulating substrate and an array of connected micro-heaters, which are embedded in the surface of the substrate and have a thickness of less than 5 mm, and which film is configured to be heated by applying current to the array of micro-heaters, for disinfecting surfaces from pathogenic microorganisms. 3 Use of a heating element which consists of at least one layer of the heated film, which is manufactured by the manufacturing method of claim 1 or by another method, and which heated film includes a thermally stable and electrically insulating substrate and an array of connected microheaters the which are embedded in the surface of the substrate and are less than 5 mm thick, which is configured to be heated by applying current to the array of micro-heaters, and a power source which power source is a battery and/or constant power supply and/or alternative source such as solar panels or from a tribological source or by inductive coupling or a combination thereof, configured so that said heated film is heated by the application of electrical voltage from the current source, for surface disinfection by heating the film to temperatures of 50- 150 °C and then cooling it to ambient temperature by turning off the voltage supply, in one or more repetitions. 4. Use of the heating element according to claim 3 for the disinfection of surfaces in contact with the human skin or through touch such as door handles, stair railings, the floor, surgical instruments, medical masks and medical instruments 5. Use of the heating element according to claims 3 or 4 wherein the application surface is a door handle, in which the film is applied to its surface and which is configured so that upon detection by a touch sensor of its use it is momentarily heated and cooled at ambient temperature within 1-3 sec and preferably in less than 1 sec to disinfect the heated surface of