Smartphone-Based Biosensor Devices for Healthcare: Comparison
Please note this is a comparison between Version 3 by Conner Chen and Version 5 by Conner Chen.

Electrochemical biosensors are undoubtedly the most popular among POC devices due to their high sensitivity, simplicity, low cost, and reliability. The development of these electrochemical devices has continued to grow exponentially since Clark designed the first enzymatic glucose biosensor, which was then improved and became the most commercialized healthcare biosensor. Electrochemical biosensors that use smartphones received great attention as they use a friendly semi-automated user interface with minimum extra tailored hardware. They can also be used at home, offering an interesting, cost-effective alternative.

  • POC devices
  • electrochemical biosensors
  • paper-based biosensors
  • optical biosensors
  • regulations
  • commercial biosensors

1. Introduction

When one thinks of POC devices, the literature always refers to the development of low-cost health care technology with low-income populations in mind or places with difficult access. However, in recent years, and more so in the present pandemic context, it can be seen that having POC devices everywhere would greatly help the management and care of patients and health personnel.
Different disciplines can converge into POC devices development, such as chemistry, biology, physics, and engineering; their combination gives rise to an interesting variety of sub-disciplines, such as biosensors, biochips, and microfluidics. When microfluidics is combined with biosensors, the possibilities become limitless. The integration of both technologies provides the possibility of miniaturized devices, an important and highly sought feature for the development of POC devices. Rackus and collaborators propose a Venn diagram, an interesting scheme that summarizes this concept [1]. They show how these sub-disciplines overlap and work together, and they argue, quite appropriately, that the overlapping of these three fields gives rise to point-of-care systems. However, if electrochemistry is changed by optical or other types of biosensors, this combination is an interesting example of how they are combining to form new application areas, which reveals great opportunities to develop POC devices. Figure 1 show this idea by modifying the first Venn diagram proposed by Rackus et al. It also includes the use of new materials, such as paper-based chips, new fabrication procedures, and different analytical methods.
Figure 1. Generalization of the Venn diagram proposed by Rackus et al. [1]. It shows the interaction of biosensors, microfluidics, and different technologies and analytical methods, which gives rise to POC devices.
On the other hand, in the last decade, there was an explosion of smartphone-based biosensors [2][3][4]. The ubiquity of smartphones throughout the world has brought about new opportunities to bring POC devices near the patients for portable healthcare monitoring, taking advantage of the characteristics of computing power, network connectivity, battery, and cameras of these devices. This can help both patients and physicians for the faster, more efficient and reliable resolution of any health problem that may arise at home or outside the context of healthcare centers. In addition, the widespread connectivity options of the current wireless telecommunication infrastructure make the smartphone a ubiquitous platform worthy of using in order to develop biosensing and diagnostics platforms, especially for point-of-care and telemedicine applications. POC devices help to bring diagnoses closer to the patient by providing faster and more frequent feedback with the physicians [5]. The latter is the raison d’être of smart POC biosensors.
Wearable biosensors are also important to consider but deserve special consideration, so they will only be considered if there are any special cases. Readers who are interested in this particular topic can refer to very complete and excellent reviews in the bibliography such as those of Ray et al. [6]; Kim et al. (2015 and 2018) [7][8]; Ajami and Teimouri [9]; Bandodkar et al. [10]; Nag et al. [11]; Tamsin [12]; Rodrigues et al. [13]; Chung et al. [14]; Lee et al., to name only a few.
Electrochemical biosensors are undoubtedly the most popular among POC devices due to their high sensitivity, simplicity, low cost, and reliability. The development of these electrochemical devices has continued to grow exponentially since Clark designed the first enzymatic glucose biosensor [15], which was then improved and became the most commercialized healthcare biosensor. In the last five years, electrochemical biosensors that use smartphones received great attention as they use a friendly semi-automated user interface with minimum extra tailored hardware. They can also be used at home, offering an interesting, cost-effective alternative. A very interesting review by Sun and Hall presents a study on the different technologies used in electrochemical smartphone-based biosensors in terms of the voltage sources used, the power required in each case, and the resolution and detection limit characteristics [5].
Optical biosensors also showed significant growth in recent years, even more so with the use of smartphones that allow their use as transmitters or receivers of optical signals. On the other hand, the introduction of paper as a substrate for the development of analytical systems proved to be the most chosen in recent years. This type of substrate allows for the implementation of both electrochemical and optical biosensors.
Microfluidic paper-based analytical devices (µPAD) applied to biosensing technologies were widely developed since their first proposal by the Whitesides group in 2007 [16]. Paper possess networks of hydrophilic/hydrophobic micro channels, which make quantitative analysis possible for their potential application in biochemical environments in healthcare. Furthermore, focusing on the point-of-care approach, paper-based sensing devices were connected with optical or colorimetric reactions in order to obtain rapid and on-site results. However, paper also presents some limitations, such as reproducibility and repeatability, and the measurements are more difficult to automate. These limitations impact the quality of the results, mainly regarding naked-eye detections where the operator may have subjective interpretation on different results. In order to tackle these limitations for paper-based optical devices and improve their outcome, in recent years, these devices were combined with smartphone technologies to capture, analyze, and quantify analytical measurements, having a better and more robust performance [17].

2. Current State of Art and Trends in Smartphone-Based Sensors Field

Both scientific research articles and patent databases were consulted in order to elucidate the current state of the art trends in smartphone-based sensors technologies. Technologies were segmented into three categories: (A) electrochemical sensors, (B) optical sensors, and (C) paper-based sensors. Figure 2 show the trends in each technology, expressed in numbers of published papers related to smartphone-based sensors.
Figure 2. Publications trend of smartphone-based biosensors over the years by type of technology.
As can be seen in Figure 2, in the last five years, the popularity of smartphone-based sensors, measured as the number of publications, increased in general and is doubtless linked to the rapid evolution and development of smartphones due to their processing power and the better performance of their tools such as cameras and light sensors [18][19]. It can be seen that electrochemical and optical sensors were featured in most of the publications until approximately 2016, but further and near 2020 and 2021, paper-based sensors mainly occupy the major scene in this field. This evolution trend can be explained due to the type of strategy used by researchers when profiting the smartphone features. Electrochemical sensors use smartphones not only as point-of-care potentiometric devices and signal processing but also as the power source of the whole biosensor. Optical devices generally need specific appliances, hardware, and a complex isolated environment in order to achieve good results. Some of these drawbacks favor paper-based electrochemical proposals due to their cheaper fabrication and simpler setups to achieve comparable results to pure electrochemical devices. As for pure optical sensors, a fairly stable development can be observed over the years reviewed. This could be due to the complexity of the optical systems required, which have apparently been replaced by paper-based optical sensors that take advantage of the advent of better cameras, improved light sensors, and more powerful image processing systems in smartphones [20].
When analyzing overall patent applications by filtering in a wider time window, a very interesting response can be seen regarding patent applications with the search pattern “biosensor + smartphone + point-of-care” or “biosensor + smartphone + poc”. As can be seen in Figure 3, there is a systematic increase in patents from 2010 to around 2016 and then a sharp decrease until 2021. It is interesting to see how smart devices became popular until 2016, but the significant decrease in recent years is striking.
Figure 3. (a) Patent applications “biosensor + smartphone + poc(point-of-care)”; (b) Patent applications for electrochemical, paper-based, and optical smartphone based biosensors.
Figure 3b show the same data but discriminates between the different types of biosensors. The same trend can be observed. The large increase in patent applications in this area in the first half of the decade until 2016 correlates with the advancement of smartphone technology, but it is surprising why, in the second half, they declined rapidly. Perhaps the “Theranos effect” may have played a role that was not minor. On the other hand, frequently, patent applications are carried out with laboratory validations, but later, moving on to the technology implementation stage and application with real samples becomes more difficult. Another fact to consider is that some publications on biosensors are developed on devices that are already widely used, such as those of glucose, for example, and the novelty to make them smart is not enough to achieve a technology replacement by the users. It is expected that the publications of the last years will be delayed since the development of new devices and innovation in the area has grown a lot and, as is known, patents are filed first. Therefore, in this case, the patent applications decreased in recent years.
Another interesting fact is that this effect is not evident for electrochemical sensors. Despite their popularity, they are much less prevalent.

3. Overview of Reviewed Technologies by Type of Sensors and Commercial Stage

Biosensors were classified as electrochemical, optical, and paper-based biosensors.

3.1. Electrochemical Smartphone-Based Biosensors

The integration of electrochemical POC devices with smartphones is a very promising strategy due to the great improvement of the advantages of each technology. Electrochemical biosensors have high sensitivity and specificity, with the possibility of simple and fast quantitative measurements, all features that can be enhanced with the use of smartphones.
Numerous strategies are used in the development of this type of device, using, for example, smartphones as the electrochemical analyzer or simply to power external dongles. This is an important feature to take into account, that is, the way the measurement module is integrated into the smartphone [5]. There are wired peripherals, for example, through the USB with OTG (On-The-Go) protocol (a kind of device communication standard), which limits its use depending on the model and brand of the phone or the ones that use the audio headphone port. The wireless peripherals (where the connection is via Bluetooth and near-field communication (NFC)) have the benefits that the measurement electrodes can be integrated near the patient, even being wearable, and the smartphones can be a potential source of energy, signal processing, and are convenient devices for data readout in wearables [21]. The case of internal dedicated hardware is another method of integration with the smartphone, and although there are some examples of them [22][23], the main problem is that developments of this type are made for a particular type of smartphone and therefore are restricted only to that particular type and brand of phone [5].
Considering the most recent reports on this topic, some examples of electrochemical biosensors that use smartphones are here presented. Table 1 presents the selected publications of the last six years considering the publications that have patents or patent applications, which gives an indication of which technologies would go to the next stage of the application and use in patients. As can be seen, only one-third of the selected publications have application or granted patents.
Table 1. Smartphone-based electrochemical biosensors compared with benchtop techniques.
Application Biosensor Type Evaluated in Real Samples? Pat. Nº, Year, State Improvements of Smart Sensor vs. Benchtop Techniques Refs.
Secretory leukocyte protease inhibitor (SLPI) but can be applied to different applications Immunological No. Tested in solutions of different concentrations of the biomarker secretory leukocyte protease inhibitor (SLPI) US11166653B2, 2016/2021 [24] Electronic module containing a low-power potentiostat that interfaces efficiently with a wide variety of phones through the audio jack to obtain power and communicate. The system uses a microcontroller. Total power consumption: 6.9 mW. Compared with a commercial potentiostat: current from ±300 pA to ±20 µA with a 100 kΩ gain. It can be used to obtain voltammograms. The platform can be used with different brands of smartphones and allows the use of electrochemical biosensors for different applications. [25][26]
US20210087614A1, 2019 Pending [27]
Blood β-ketone (blood β-hydroxybutyrate) Enzymatic: β-hydroxybutyrate dehydrogenase method Yes. Tested in finger blood   Electrochemical dongle, which is powered by the smartphone through an OTG. It takes chronoamperometric measurements of blood ketone. Linear regression coefficient of 0.987 for a range of 0 to 4 mmol/L of blood β-hydroxybutyrate. The authors were able to demonstrate that the preciseness and stability of the measured data are highly reliable and applicable for clinical use. [28]
For protein detection: bull serum albumin (BSA) and thrombin Immunological for BSA detection and Enzymatic for Thrombin detection No. Tested with solutions of different concentrations of BSA and thrombin   Portable transducer and a handheld detector connected via Bluetooth to the smartphone. The detector can perform electrochemical impedance spectroscopy (EIS) (10 Hz to 10 kHz). The system can detect very low concentrations of BSA (1.78 µg/mL) and thrombin (2.97 ng/mL). They related the charge transfer resistance (Rct) with the concentration of BSA or thrombin. The smartphone delivers control commands, receive data signals, and display the Nyquist graph. A designed Android App serves as an interactive interface between the users and the biosensor system. It allows the use of other electrochemical biosensors. [29]
Glucose concentration Enzyme-carbon composite pellets No. Tested with solutions of different glucose concentrations US20210270766A1, 2018 Pending [30] Electrochemical sensor strips consist of carbon electrodes and a second part is composed of the carbon paste GOx biosensor, which can be replaced in each measurement. The biosensor is a compact carbon/GOx/rhodium pill. Measurement compartment: 3D-fabricated smartphone case with a permanently-attached passive sensor strip and a compartment where the biosensor magnetic pellet is placed for each measurement. They developed a portable potentiostat (Texas Instruments CC2541 BLE System on-Chip) communicated wirelessly with the smartphone. Android-based smartphone application developed. [31]
Alcohol in whole blood samples Enzymatic: two enzymes are used, HRP and alcohol oxidase Yes. Tested with whole blood   The system combines a three-electrode microfluidic chip with a secondary compact PCB module as a µPotentiostat. Chronoamperometric and CV measurements. Communicated with the smartphone via USB. The novelty of the system is the reusable biosensor concept. Two enzymes, HRP and alcohol oxidase, are immobilized via in situ electrodeposition of a calcium alginate hydrogel for selective ethanol detection. A constant potential of 0 V was applied between WE and Pt RE. The smartphone acts as a simple graphical interface and for cloud connectivity. [32]
Cancer biomarker microRNAs (miRNAs) Genetic: Tris(2-carboxyethyl)phosphine hydrochloride (TCEP)-treated ssDNA probe drop casted onto an rGO/Au composite-modified WE No. Tested with miR-21 spiked artificial saliva   The system presents a circuit board as the potentiostat, powered through smartphone On-The-Go (OTG) port and a graphene oxide/gold composite-modified electrode as the biosensor. The circuit board communicates via Bluetooth with the smartphone. A specially designed Android application shows the results. The detection is facilitated via a synthetic ssDNA probe immobilized onto the GO/Au electrode. Good linearity (r2 = 0.99) for the detection of 1×10−4 M to 1×10−12 M of [miR-21]. The sample must be incubated at 40 °C for 1 h for hybridization before electrochemical measurement. [33]
Reactive oxygen species (ROS) for COVID-19 detection MWCNTs on the tip of steel needles of 3 electrodes Yes. Tested in Fresh sputum or bronchoalveolar lavage

fluids
US11181499B2, 2017/2021 [34] The system includes a previously patented

electrochemical ROS/H2O2 system consisting of an electrochemical readout board (+/− 0.8 mV, 100 mV s−1, and a

sensing disposable sensor. The group presented an application Patent in 2020 for the electrochemical approach to detect COVID-19, which was granted in 2021.
[35]
US11047824B2, 2020/2021 [36]
RNA from SARS-CoV-2 virus Genetic: The sequences were provided by the Chinese Center for Disease Control and Prevention (CDC) Yes. Tested with extracts from SARS-CoV-2-confirmed patients and recovered patients   It is an ultrasensitive electrochemical biosensor for the detection of the RNA of SARS-CoV-2 by using a smartphone. They used a super sandwich-type recognition strategy without the need for nucleic acid amplification and reverse transcription. For this biosensor, only two copies (10 μL) of SARS-CoV-2 were required per assay to detect a positive sample. Calibrated with concentrations between 10−17–10−12 M, LOD: 3 aM. LOD of the clinical specimen: 200 copies/mL, which was the lowest LOD among the published RNA measurement of SARS-CoV-2 at this moment [37]
The SARS-CoV-2 outbreak, which rapidly evolved into a worldwide pandemic, is an example of a very important event, where smart POC biosensors have become of vital importance to manage the disease and avoid oversaturate health services. Some authors presented interesting mini-reviews of the development of POC biosensors for the detection of COVID-19, where numerous biosensors reported in the bibliography were analyzed and proposed to be perfectly applied in the detection of this new disease with the adequate adaptation of bioreceptors [38][39][40][41][42]. In this sense, electrochemical and optical biosensors would be the best suited to implement COVID-19 POC detection [38]. POC biosensors can provide valuable data for the effective assessment of clinical progress of the symptoms and to provide alertness on the severity or critical trends of infection. Moreover, if these devices are associated with smartphones or direct communication systems with health centers, unnecessary transfers could be avoided, and it would be possible to act more quickly on patients with a poor evolution. Table 1 reflect two examples of smartphone-based electrochemical biosensors for this application. Reliable biosensors that patients can buy in a pharmacy and make the determination at home will be very useful. Moreover, it seems convenient to develop biosensors to determine other useful parameters that, together with pulse oximetry determinations, avoid the unnecessary transfer of patients to hospitals or health care centers. Examples of these are the biosensor proposed by Miripour et al. for the detection of ROS species [35] or that of Baraket et al., who already in 2017, proposed a biosensor for the detection of cytokines [43]. Non-cytokine protein biomarkers such as C-reactive protein and D-dimer (a small protein fragment present in the blood after a blood clot is degraded by fibrinolysis, which is elevated in patients with COVID-19) or other biomarkers that can also be found in whole blood, serum, urine, saliva, or sweat, can also be used as important biomarkers for monitoring the disease at home. The connection of these biosensors to smartphone systems would allow not only remote control by doctors but also the protection of all health personnel and the general population.
Taking into account all applications of electrochemical smartphone-based pure electrochemical biosensors, it can be seen from Table 1 that only one-third of the reviewed papers were found to have patents or related ones. This may be due to many factors, from little practice of patenting in the countries where the works come from to difficulty in the effective transfer of technology to the market, or the lack of clinical importance of the detected analytes from a POC detection point of view.

3.2. Optical Smartphone-Based Biosensors

The following examples illustrate some of the most remarkable proposals regarding this area, presented in the literature between 2015–2020. The use of microscopy in order to achieve optical detection of biosensing and diagnostic devices is the most common strategy since it provides reliable information and on-site results compatible with point-of-care devices. Nevertheless, microscopy devices are high-quality performance equipment that present some inescapable requirements such as proper infrastructure for its size, high qualified operators, and sometimes high-cost supplies. On the other hand, image analysis for the transduction and quantification of radiation emission or color amount cast by analyte recognition demands using dedicated software in order to obtain information from a sample. For several years, most of these informatics tools were only driven on personal computers or specific equipment, but with the explosive development of mobile applications and rapid enhancement of the mobile processors and computing capacity, the analyzing tools are nowadays within easy reach.
In order to keep using the benefits of microscopy techniques, using image analysis tools, and looking forward to the point-of-care approach, these authors used convenient smartphone features to sense and diagnose biological analytes. Table 2 illustrate some of the most remarkable proposals regarding this area, presented in the literature in the mentioned period.
Table 2. Smartphone-based optical biosensors compared with benchtop techniques.
Application Biosensor Type Evaluated in Real Samples? Pat. Nº, Year, State Improvements of Smart Sensor vs. Benchtop Techniques Ref.
H2O2 , Glucose and Catechol biosensor Enzymatic: GOX and tyrosinase over poly(aniline-co-anthranilic acid) Yes. Food and pharmaceutical samples   Polymeric substrate material and image processing software provided a great correlation with benchtop techniques and higher LOD. [44]
HIV and Hepatitis B biosensor DNA/RNA-linked biosensor Yes. Plasma samples WO2014089700A1, 2013 Pending [45] They were able to detect between 103 to 109 copies/mL over a 20µL sample and differentiate patients with HIV from those with HBV on the mono-infection assay and multiplexed detection of both of them in a co-infection assay. The results were quite well-correlated compared to benchtop equipment measurements. [46]
Hemoglobin and HIV biosensor Immunosensor Yes. Blood samples WO2016025698A1, 2014 Pending [47] It consists of a combined pure optical assay and an immunoassay at the same time, and in the same device, without a difficult procedure for handling samples and reagents. The results are in good agreement with their commercial equivalents supported by smartphone technologies. [48]
E. coli and S. typhimurium biosensor Immunosensor No   For the first time, a device capable of detecting two genetically related bacteria within a single sample drop is reported, with a LOD of 10−2 CFU/mL, in a fairly short time (12 min), and with a good consistency in comparison with the results obtained in laboratory experiments. [49]
Zika, Dengue, Chikungunya detector DNA/RNA-linked biosensor No. Tested in artificial blood, urine, and saliva samples US20160025630A1, 2014 Pending [50] Detection technique that involves quenching of unincorporated amplification signal reporters (QUASR). Distinctively to other reported LAMP detection modalities, QUASR offers very bright signals, reduces the detection of false-positive amplification, and offers the ability to multiplex two or more targets per reaction. These features can highly reduce reagent costs and dilution needs when sample volume is limiting. A personalized smartphone application (app) controls the isothermal heating module and a LED excitation module via Bluetooth. The app processes images through a novel detection algorithm for multiplexed QUASR assay signals with greater accuracy than conventional image analysis software. [51]
HIV1-p17, hemagglutinin (HA), and dengue virus type I detector Bioluminiscent reporter Yes. Blood plasma samples WO2019038375A1, 2018 Pending [52] The design shows to be an attractive analytical platform for point-of-care antibody detection that dispenses with liquid handling steps that are related to the major issues in immunoassays. [53]
Inflammation and cell viability biosensors Bioluminiscent reporters No. Simulated proinflammatory and toxic samples. US20120045835A1, 2009 Pending [54] A limit of detection for tumor necrosis factor (TNFα) of 0.15 ± 0.05 ng/mL was achieved. This proposal promises to be a useful platform to preliminary screen environmental samples or other types of compounds for on-site detection. [55]
Hemoglobin sensor Label-free detection No. Simulated samples. US8861086B2, 2014 [56] It stands out for its compact size, portability, low cost, the efficiency of optical spectroscopy for quantitative measurement, and ease of data collection, management, and computation. [57]
US20160296118A1, 2015 Pending [58]
Bovine immunoglobulinG (IgG) Immunosensor No. Spiked buffer solution of IgG protein US20190025330A1, 2917 Pending [59] In addition to the ability to detect immunoglobulins G, the device can be applied to the sensing of other analytes by properly functionalizing the gold film. The results and sensitivity obtained were comparable to commercial SPR instruments, so being a portable SPR system, it makes it an extremely useful device. [60]
Chloride, sodium, and zinc in sweat Fluorescence Yes. Sweat US20210145352A1, 2018 Pending [61] Through an ultrathin, skin-compatible adhesive layer, the device allows sweat to be collected and distributed to different areas with fluorescent reagents. The device makes it possible to quantitatively determine, in a simple and low-cost device, several biomarkers of sweat at the same time. [62]
Prostatespecific antigen (PSA) Fluorescence No. Spiked solution with PSA US20120141746A1, 2009 Pending [63] The device allows, through simple steps, to quantify different concentrations of PSA by means of fluorescence measurement with a smartphone. This sends the data to the cloud for processing and gives a result in about 1 min. It is not a practical device since it needs an objective lens (magnification 40×) to be able to capture the images with the smartphone. [64]
JP2008128677A, 2006 Pending [65]
WO2017141503A1, 2016 Pending [66]
The great variety of optical biosensors reported in the bibliography saw their possibilities grow with the incorporation of smartphones as reading devices, actuators, image processors, or connections with the cloud. This incorporation made them very promising devices. In the present case, almost 100% of the publications are supported by patents, so most of them are nearer to a commercial prototype. On the other hand, only a few examples of smartphone-based optical biosensors were presented in Table 2 following the mentioned criteria, since most of the reports correspond to paper-based POC devices, which have even more possibilities and will be treated in the following section of this work.

3.3. Paper-Based Biosensors That Uses Smartphones

In recent years, paper has become an alternative for advanced microfluidic devices, being used as a platform for various analytical and bioanalytical techniques. Within the large volume of POC devices for health care that exists in the market, paper-based biosensors are the most chosen by end-users. Qualities such as their price and their robustness have allowed paper-based POC biosensors to distinguish themselves from other biosensors systems. A market analysis performed by “Grand View Research, USA”, evidenced that the participation of said diagnostic devices in 2016 was approximately $2.2 billion, and it was predicted that its participation would reach $8.35 thousand million for the year 2022 [67]. Together with qualities such as portability, functionalization and modification, lower cost, ease of manufacturing and transportation, profitability, and biodegradability, these devices recently achieved the SAFE status (affordable, sensitive, specific, easy to use, fast and robust, without equipment, deliverable to all end-users) for POC diagnostics in miniaturized environments [67][68] .
Depending on the complexities of fluid handling and precision, paper-based biosensors are classified into dipstick, side-flow assay (LFA), and µPAD, the last one being the only one capable of making a quantitative diagnosis. Due to all the aforementioned benefits of paper-based devices and to allow them to make quantitative or semi-quantitative estimates [69], research was promoted in recent years on their use as POC assisted by smartphones, strips readers, dedicated electronic devices, signal processing modules, etc. In this way, the development of high-quality peripheral-assisted diagnostic devices and the possibility of generating, at a lower cost, authenticated and organized records for future reference are also promoted [67][70].
In this sense, the use of smartphones is a leader over other smart devices for paper-based biosensors due to their easy handling, adjustment, and simplicity for end-users. The joint work of major smartphone manufacturers and healthcare giants has resulted in an overwhelming emergence of smartphone-based diagnostic devices for general health and fitness in this area [67]. In this way, among the paper-based devices that use intelligent technology, there are those that perform determinations by electrochemiluminescence, electrochemistry, and the most popular, optical measurements.

References

  1. Rackus, D.G.; Shamsi, M.H.; Wheeler, A.R. Electrochemistry, biosensors and microfluidics: A convergence of fields. Chem. Soc. Rev. 2015, 44, 5320–5340.
  2. Zarei, M. Portable biosensing devices for point-of-care diagnostics: Recent developments and applications. TrAC-Trends Anal. Chem. 2017, 91, 26–41.
  3. Kang, M.; Park, E.; Cho, B.H.; Lee, K. Recent patient health monitoring platforms incorporating internet of things-enabled smart devices. Int. Neurourol. J. 2018, 22, 76–82.
  4. El-Miedany, Y. Telehealth and telemedicine: How the digital era is changing standard health care. Smart Homecare Technol. TeleHealth 2017, 4, 43–51.
  5. Sun, A.C.; Hall, D.A. Point-of-Care Smartphone-based Electrochemical Biosensing. Electroanalysis 2019, 31, 2–16.
  6. Ray, T.R.; Choi, J.; Bandodkar, A.J.; Krishnan, S.; Gutruf, P.; Tian, L.; Ghaffari, R.; Rogers, J.A. Bio-integrated wearable systems: A comprehensive review. Chem. Rev. 2019, 119, 5461–5533.
  7. Kim, J.; Campbell, A.S.; Wang, J. Wearable non-invasive epidermal glucose sensors: A review. Talanta 2018, 177, 163–170.
  8. Kim, J.; Campbell, A.S.; de Ávila, B.E.F.; Wang, J. Wearable biosensors for healthcare monitoring. Nat. Biotechnol. 2019, 37, 389–406.
  9. Ajami, S.; Teimouri, F. Features and application of wearable biosensors in medical care. J. Res. Med. Sci. 2015, 20, 1208–1215.
  10. Bandodkar, A.J.; Jia, W.; Wang, J. Tattoo-Based Wearable Electrochemical Devices: A Review. Electroanalysis 2015, 27, 562–572.
  11. Nag, A.; Mukhopadhyay, S.C.; Kosel, J. Wearable Flexible Sensors: A Review. IEEE Sens. J. 2017, 17, 3949–3960.
  12. Tamsin, M. Wearable Biosensor Technologies. Int. J. Innov. Sci. Res. 2015, 13, 697–703.
  13. Rodrigues, D.; Barbosa, A.I.; Rebelo, R.; Kwon, I.K.; Reis, R.L.; Correlo, V.M. Skin-integrated wearable systems and implantable biosensors: A comprehensive review. Biosensors 2020, 10, 79.
  14. Chung, M.; Fortunato, G.; Radacsi, N. Wearable flexible sweat sensors for healthcare monitoring: A review. J. R. Soc. Interface 2019, 16, 20190217.
  15. Clark, L.C.; Lyons, C. Electrode systems for continuous monitoring in cardiovascular surgery. Ann. N. Y. Acad. Sci. 1962, 102, 29–45.
  16. Martinez, A.W.; Phillips, S.T.; Butte, M.J.; Whitesides, G.M. Patterned Paper as a Platform for Inexpensive, Low-Volume, Portable Bioassays. Angew. Chem. 2007, 119, 1340–1342.
  17. Liu, J.; Geng, Z.; Fan, Z.; Liu, J.; Chen, H. Point-of-care testing based on smartphone: The current state-of-the-art (2017–2018). Biosens. Bioelectron. 2019, 132, 17–37.
  18. Halpern, M.; Zhu, Y.; Reddi, V.J. Mobile CPU’s rise to power: Quantifying the impact of generational mobile CPU design trends on performance, energy, and user satisfaction. In Proceedings of the 2016 IEEE International Symposium on High Performance Computer Architecture (HPCA), Barcelona, Spain, 12–16 March 2016; pp. 64–76.
  19. Ginny; Kumar, C.; Naik, K. Smartphone Processor Architecture, Operations, and Functions: Current State-of-the-Art and Future Outlook: Energy Performance Trade-Off. J. Supercomput. 2021, 77, 2411–2502.
  20. Wang, H.; Heintzmann, R.; Diederich, B. The power in your pocket-uncover smartphones for use as cutting-edge microscopic instruments in science and research. Adv. Opt. Technol. 2021, 10, 89–108.
  21. Steinberg, M.D.; Kassal, P.; Steinberg, I.M. System Architectures in Wearable Electrochemical Sensors. Electroanalysis 2016, 28, 1149–1169.
  22. Sun, A.; Venkatesh, A.G.; Hall, D.A. A Multi-Technique Reconfigurable Electrochemical Biosensor: Enabling Personal Health Monitoring in Mobile Devices. IEEE Trans. Biomed. Circuits Syst. 2016, 10, 945–954.
  23. Guo, J. Uric acid monitoring with a smartphone as the electrochemical analyzer. Anal. Chem. 2016, 88, 11986–11989.
  24. Hall, D.; Sun, A.C. Reconfigurable, Multi-Technique Electrochemical Portable Biosensor. U.S. Patent No. 11,166,653, 9 November 2021.
  25. Sun, A.C.; Yao, C.; Ag, V.; Hall, D.A. An efficient power harvesting mobile phone-based electrochemical biosensor for point-of-care health monitoring. Sens. Actuators B Chem. 2016, 235, 126–135.
  26. Aronoff-Spencer, E.; Venkatesh, A.G.; Sun, A.; Brickner, H.; Looney, D.; Hall, D.A. Detection of Hepatitis C core antibody by dual-affinity yeast chimera and smartphone-based electrochemical sensing. Biosens. Bioelectron. 2016, 86, 690–696.
  27. Hall, D.; Hsu, C.-L.; Sun, A.; Zhao, Y.; Aronoff-Spencer, E. Electrochemical Biosensor Array Devices, Systems, and Methods for Point-of-Care Detection. U.S. Patent Application No. 16/976,464, 25 March 2021.
  28. Guo, J. Smartphone-Powered Electrochemical Dongle for Point-of-Care Monitoring of Blood β-Ketone. Anal. Chem. 2017, 89, 8609–8613.
  29. Zhang, D.; Lu, Y.; Zhang, Q.; Liu, L.; Li, S.; Yao, Y.; Jiang, J.; Liu, G.L.; Liu, Q. Protein detecting with smartphone-controlled electrochemical impedance spectroscopy for point-of-care applications. Sens. Actuators B Chem. 2016, 222, 994–1002.
  30. Raman, K.; Salahandish, R.; Wang, G.; Bhat, S.; Vastarey, N.S.; Kapoor, A.S. Portable Electrochemical-Sensor System for Analyzing User Health Conditions and Method Thereof. U.S. Patent Application No. 17/261,476, 2021.
  31. Bandodkar, A.J.; Imani, S.; Nuñez-Flores, R.; Kumar, R.; Wang, C.; Mohan, A.M.V.; Wang, J.; Mercier, P.P. Re-usable electrochemical glucose sensors integrated into a smartphone platform. Biosens. Bioelectron. 2018, 101, 181–187.
  32. Aymerich, J.; Márquez, A.; Terés, L.; Muñoz-Berbel, X.; Jiménez, C.; Domínguez, C.; Serra-Graells, F.; Dei, M. Cost-effective smartphone-based reconfigurable electrochemical instrument for alcohol determination in whole blood samples. Biosens. Bioelectron. 2018, 117, 736–742.
  33. Shin Low, S.; Pan, Y.; Ji, D.; Li, Y.; Lu, Y.; He, Y.; Chen, Q.; Liu, Q. Smartphone-based portable electrochemical biosensing system for detection of circulating microRNA-21 in saliva as a proof-of-concept. Sens. Actuators B Chem. 2020, 308, 127718.
  34. Abdolahad, M.; Miripour, Z.S.; NajafiKhoshnoo, S. Real-time and label free analyzer for in-vitro and in-vivo detecting of cancer. US Patent No. US 20,180,299,401 A1, 18 October 2018.
  35. Miripour, Z.S.; Sarrami-Forooshani, R.; Sanati, H.; Makarem, J.; Taheri, M.S.; Shojaeian, F.; Eskafi, A.H.; Abbasvandi, F.; Namdar, N.; Ghafari, H.; et al. Real-time diagnosis of reactive oxygen species (ROS) in fresh sputum by electrochemical tracing; correlation between COVID-19 and viral-induced ROS in lung/respiratory epithelium during this pandemic. Biosens. Bioelectron. 2020, 165, 112435.
  36. Abdolahad, M.; Miripour, Z.S.; Koloukhi, H.S.; Zanjani, F.Z.S.; Ghafari, H.; Habashi, N.N. Electrochemical Approach for COVID-19 Detection. U.S. Patent No. 10,845,336, 24 November 2020.
  37. Zhao, H.; Liu, F.; Xie, W.; Zhou, T.C.; OuYang, J.; Jin, L.; Li, H.; Zhao, C.Y.; Zhang, L.; Wei, J.; et al. Ultrasensitive supersandwich-type electrochemical sensor for SARS-CoV-2 from the infected COVID-19 patients using a smartphone. Sens. Actuators B Chem. 2021, 327, 128899.
  38. Choi, J.R. Development of Point-of-Care Biosensors for COVID-19. Front. Chem. 2020, 8, 517.
  39. Gowri, A.; Ashwin Kumar, N.; Suresh Anand, B.S. Recent advances in nanomaterials based biosensors for point of care (PoC) diagnosis of Covid-19 — A minireview. TrAC-Trends Anal. Chem. 2021, 137, 116205.
  40. Cui, F.; Zhou, H.S. Diagnostic methods and potential portable biosensors for coronavirus disease 2019. Biosens. Bioelectron. 2020, 165, 112349.
  41. Abad-Valle, P.; Fernández-Abedul, M.T.; Costa-García, A. Genosensor on gold films with enzymatic electrochemical detection of a SARS virus sequence. Biosens. Bioelectron. 2005, 20, 2251–2260.
  42. Mahshid, S.S.; Flynn, S.E.; Mahshid, S. The potential application of electrochemical biosensors in the COVID-19 pandemic: A perspective on the rapid diagnostics of SARS-CoV-2. Biosens. Bioelectron. 2021, 176, 112905.
  43. Baraket, A.; Lee, M.; Zine, N.; Sigaud, M.; Bausells, J.; Errachid, A. A fully integrated electrochemical biosensor platform fabrication process for cytokines detection. Biosens. Bioelectron. 2017, 93, 170–175.
  44. Hosu, O.; Lettieri, M.; Papara, N.; Ravalli, A.; Sandulescu, R.; Cristea, C.; Marrazza, G. Colorimetric multienzymatic smart sensors for hydrogen peroxide, glucose and catechol screening analysis. Talanta 2019, 204, 525–532.
  45. Chan, W.; Ming, K. Wireless communication device-based detection system. WIPO Application Patent WO2014/089700 A1, 19 June 2014.
  46. Ming, K.; Kim, J.; Biondi, M.J.; Syed, A.; Chen, K.; Lam, A.; Ostrowski, M.; Rebbapragada, A.; Feld, J.J.; Chan, W.C.W. Integrated quantum dot barcode smartphone optical device for wireless multiplexed diagnosis of infected patients. ACS Nano 2015, 9, 3060–3074.
  47. Guo, T.; Sia, S.; Xie, S.; Meng, F.; Yeager, K. Diagnostic devices, systems, and methods. WIPO Application Patent WO 2016/025698 A1, 18 February 2016.
  48. Guo, T.; Patnaik, R.; Kuhlmann, K.; Rai, A.J.; Sia, S.K. Smartphone dongle for simultaneous measurement of hemoglobin concentration and detection of HIV antibodies. Lab Chip 2015, 15, 3514–3520.
  49. Nicolini, A.M.; Fronczek, C.F.; Yoon, J.Y. Droplet-based immunoassay on a “sticky” nanofibrous surface for multiplexed and dual detection of bacteria using smartphones. Biosens. Bioelectron. 2015, 67, 560–569.
  50. Jensen, M.; Srivastava, N.; Yue, M.; Priye, A.; Nagle, R. Analytical Instrument Systems. US Application Patent No. 776,567, 14 March 2014.
  51. Priye, A.; Bird, S.W.; Light, Y.K.; Ball, C.S.; Negrete, O.A.; Meagher, R.J. A smartphone-based diagnostic platform for rapid detection of Zika, chikungunya, and dengue viruses. Sci. Rep. 2017, 7, 44778.
  52. Tenda, K.; Arts, R.; Citterio, D.; Tomimuro, K.; Merkx, M. Detection device for bioluminescent detection of biomarkers from a biological fluid sample using luminescent sensing protein. WIPO Application Patent WO 2019038375 A1, 28 February 2019.
  53. Arts, R.; Den Hartog, I.; Zijlema, S.E.; Thijssen, V.; Van Der Beelen, S.H.E.; Merkx, M. Detection of Antibodies in Blood Plasma Using Bioluminescent Sensor Proteins and a Smartphone. Anal. Chem. 2016, 88, 4525–4532.
  54. Michelini, E.; Roda, A.; Dolci, L.; Cevenini, L.; Mezzanotte, L. Portable device based on immobilized cells for the detection of analytes. US Application Patent No. 045,835 A1, 23 February 2012.
  55. Michelini, E.; Calabretta, M.M.; Cevenini, L.; Lopreside, A.; Southworth, T.; Fontaine, D.M.; Simoni, P.; Branchini, B.R.; Roda, A. Smartphone-based multicolor bioluminescent 3D spheroid biosensors for monitoring inflammatory activity. Biosens. Bioelectron. 2019, 123, 269–277.
  56. Liu, Z.; Yang, C.; Shi, K.; Edwards, P. Compact spectrometer including a diffractive optical element with dual dispersion and focusing functionality. US Patent No. US 8,861,086 B2, 14 October 2014.
  57. Edwards, P.; Zhang, C.; Zhang, B.; Hong, X.; Nagarajan, V.K.; Yu, B.; Liu, Z. Smartphone based optical spectrometer for diffusive reflectance spectroscopic measurement of hemoglobin. Sci. Rep. 2017, 7, 12224.
  58. Edwards, P.; Liu, Z. Mobile reflectance optical spectroscopy device and process of using and assembling mobile reflectance optical spectroscopy device. US Application Patent No. US 2016/0296118 A1, 13 October 2016.
  59. Varghese, J.; Campagna, J.; Bilousova, T.; Spilman, P.; Heinzelman, P.; Hatami, A.; Alam, M. 3D-exoquant method for the analysis of surface molecules and quantification of tissue-specific exosomes in biological fluids. US Application Patent No. US 20190025330 A1, 24 January 2019.
  60. Liu, Y.; Liu, Q.; Chen, S.; Cheng, F.; Wang, H.; Peng, W. Surface plasmon resonance biosensor based on smart phone platforms. Sci. Rep. 2015, 5, 12864.
  61. Rogers, J.; Reeder, J.; Bandodkar, A.; Kim, S.; Sekine, Y.; Choi, J.; Ray, T.; Hourlier-Fargette, A.; Gutruf, P.; Lee, K.; et al. Epidermalsensing systems for optical redout, visualization and analysis of biofluids. US Application Patent No. US20210145352 A1, 20 May 2021.
  62. Sekine, Y.; Kim, S.B.; Zhang, Y.; Bandodkar, A.J.; Xu, S.; Choi, J.; Irie, M.; Ray, T.R.; Kohli, P.; Kozai, N.; et al. A fluorometric skin-interfaced microfluidic device and smartphone imaging module for: In situ quantitative analysis of sweat chemistry. Lab Chip 2018, 18, 2178–2186.
  63. Sandhu, A. Method of forming and visualizing latent image. US Application Patent No. US 20120141746 A1, 7 June 2012.
  64. Sharma, J.; Ono, T.; Yukino, R.; Miyashita, H.; Hanyu, N.; Handa, H.; Sandhu, A. Smartphone based platform for real-time sharing of medical diagnostics information by optical detection of functionalized fluorescent magnetic nanoparticles. Biomed. Phys. Eng. Express 2019, 5, 35014.
  65. Sandhu, A. Marker for biosensor, biosensor, and marker detection method for biosensor. Japanise Application Patent No. JP2008128677A, 5 June 2008.
  66. Sandhu, A.; Sharma, J.; Takamura, T.; Yukino, R.; Hanyu, N.; Yasuno, H.; Hama, N.; Tanaka, T.; Handa, H. Biosensing method and device using magnetic particles. WIPO Application Patent No. WO2017141503 A1, 24 August 2017.
  67. Mahato, K.; Srivastava, A.; Chandra, P. Paper based diagnostics for personalized health care: Emerging technologies and commercial aspects. Biosens. Bioelectron. 2017, 96, 246–259.
  68. Tian, T.; Wei, X.; Jia, S.; Zhang, R.; Li, J.; Zhu, Z.; Zhang, H.; Ma, Y.; Lin, Z.; Yang, J. Integration of target responsive hydrogel with cascaded enzymatic reactions and microfluidic paper-based analytic devices (mPADs) for point-of-care testing (POCT). Biosens. Bioelectron. 2015, 77, 537–542.
  69. Carvalhal, R.F.; Kfouri, M.S.; De Piazetta, M.H.O.; Gobbi, A.L.; Kubota, L.T. Electrochemical detection in a paper-based separation device. Anal. Chem. 2010, 82, 1162–1165.
  70. Martinez, A.W.; Phillips, S.T.; Carrilho, E.; Thomas, S.W.; Sindi, H.; Whitesides, G.M. Simple telemedicine for developing regions: Camera phones and paper-based microfluidic devices for real-time, off-site diagnosis. Anal. Chem. 2008, 80, 3699–3707.
More