Multifunctional Pacemaker Lead for Cardiac Energy Harvesting and Pressure Sensing

Dong, Lin; Closson, Andrew B.; Jin, Congran; Nie, Yuan; Cabe, Andrew; Escobedo, Daniel; Huang, Shicheng; Trase, Ian; Xü, Zhe; Chen, Zi; Feldman, Marc D.; Zhang, John X. J.

doi:10.1002/adhm.202000053

Cited by 30 publications

(21 citation statements)

References 54 publications

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“…Among the three polymers, PVDF and its copolymers have been widely studied. Their high piezoelectric response is increasingly being used in an extensive range of technological applications, such as energy generation and storage [ 5 ], monitoring and control [ 6 ], biomedicine [ 7 ], sensors and actuators [ 8 ], and smart scaffolds [ 9 , 10 ]. In particular, piezoelectric materials applications involving interfaces with biological systems represent an exciting area of rapid development [ 11 , 12 ].…”

Section: Introductionmentioning

confidence: 99%

Development of Highly Crystalline Polylactic Acid with β-Crystalline Phase from the Induced Alignment of Electrospun Fibers

et al. 2021

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Polylactic acid (PLA) is one of the known synthetic polymers with potential piezoelectric activity but this property is directly related to both the crystalline structure and crystalline degree. Depending on the process conditions, PLA can crystallize in three different forms: α-, β-, and γ- form, with β-crystalline phase being the piezoelectric one. To obtain this crystalline structure, transformation of α to β is required. To do so, the strategies followed so far consisted in annealing or/and stretching of previously obtained PLA in the form of films or fibers, that is, additional post-processing steps. In this work, we are able to obtain PLA fibers with high macromolecular alignment, as demonstrated by SEM, and in the β polymorph, as detected by X-ray diffraction (XRD) without the requirement of post-processing. For that, PLA fibers were prepared by using an electrospinning coupled to a drum collector. This set up and the optimization of the parameters (voltage flow-rate, and drum collector speed) induced molecular stretching giving rise to uniaxially oriented and highly aligned fibers.

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Section: Introductionmentioning

confidence: 99%

Development of Highly Crystalline Polylactic Acid with β-Crystalline Phase from the Induced Alignment of Electrospun Fibers

et al. 2021

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“…However, this also requires additional security to protect the system from unwanted intrusion [ 66 ]. Sensors such as pressure, oxygen saturation in addition to ECG can be used to optimize the operation of the system [ 67 , 68 ].…”

Section: Long Term Implantsmentioning

confidence: 99%

In-Vivo Microsystems: A Review

French

2020

Sensors

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In-vivo sensors yield valuable medical information by measuring directly on the living tissue of a patient. These devices can be surface or implant devices. Electrical activity in the body, from organs or muscles can be measured using surface electrodes. For short term internal devices, catheters are used. These include cardiac catheter (in blood vessels) and bladder catheters. Due to the size and shape of the catheters, silicon devices provided an excellent solution for sensors. Since many cardiac catheters are disposable, the high volume has led to lower prices of the silicon sensors. Many catheters use a single sensor, but silicon offers the opportunity to have multi sensors in a single catheter, while maintaining small size. The cardiac catheter is usually inserted for a maximum of 72 h. Some devices may be used for a short-to-medium period to monitor parameters after an operation or injury (1–4 weeks). Increasingly, sensing, and actuating, devices are being applied to longer term implants for monitoring a range of parameters for chronic conditions. Devices for longer term implantation presented additional challenges due to the harshness of the environment and the stricter regulations for biocompatibility and safety. This paper will examine the three main areas of application for in-vivo devices: surface devices and short/medium-term and long-term implants. The issues of biocompatibility and safety will be discussed.

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“…Numerous research studies have focused on reducing the power consumption of the micro-electromechanical system (MEMS) and microelectronics for wearable biomedical sensors. Table 1 shows the operating features of wearable biomedical monitoring devices, such as (1) electrocardiogram (ECG) which is used for cardiac activity, (2) electroencephalography (EEG) which measures brain activity, (3) pulse oximeter which monitors oxygen saturation, (4) blood pressure sensor which is utilized to take blood pressure readings, (5) glucometer which is needed for sugar measurement, (6) hearing aid which is necessary for deaf people, and (7) pacemaker which is implanted in heart patients [6] to control an abnormal heart rhythm. Typically, the power requirements for wearable biomedical devices range from 0.003 to 500 mW, which can easily be produced by energy harvesting technology.…”

Section: Introductionmentioning

confidence: 99%

Experimentation of a Wearable Self‐Powered Jacket Harvesting Body Heat for Wearable Device Applications

Khan

2021

Journal of Sensors

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The development of special wearable/portable electronic devices for health monitoring is rapidly growing to cope with different health parameters. The emergence of wearable devices and its growing demand has widened the scope of self-powered wearable devices with the possibility to eliminate batteries. For instance, the wearable thermoelectric energy harvester (TEEH) is an alternate to batteries, which has been used in this study to develop four different self-powered wearable jacket prototypes and experimentally validated. It is observed that the thermal resistance of the cold side without a heat sink of prototype 4 is much greater than the rest of the proposed prototypes. Besides that, the thermal resistance of prototype 4 heat sinks is even lower among all proposed prototypes. Therefore, prototype 4 would have a relatively higher heat transfer coefficient which results in improved power generation. Moreover, an increase in heat transfer coefficient is observed with an increase in the temperature difference of the cold and hot sides of a TEEH. Thus, on the cold side, a heat flow increases which benefits heat dissipation and in turn reduces the thermal resistance of the heat sink. Besides that, the developed prototypes on people show that power generation is also affected by factors like ambient temperature, person’s activity, and wind breeze and does not depend on the metabolism. A different mechanism has been explored to maximize the power output within a 16.0 cm2 area, in order to justify the wearability of the energy harvester. Furthermore, it is observed that during the sunlight, any material covering the TEEH would improve the performance of prototypes. Prototypes are integrated into jacket and studied extensively. The TEEH system was designed to produce a maximum delivering power and power density of 699.71 μW and 43.73 μW/cm2, respectively. Moreover, the maximum voltage produced is 62.6 mV at an optimal load of 5.6 Ω. Furthermore, the TEEH (prototype 4) is connected to a power management circuit of ECT310 and LTC3108 and has been able to power 18 LEDs.

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Multifunctional Pacemaker Lead for Cardiac Energy Harvesting and Pressure Sensing

Cited by 30 publications

References 54 publications

Development of Highly Crystalline Polylactic Acid with β-Crystalline Phase from the Induced Alignment of Electrospun Fibers

Development of Highly Crystalline Polylactic Acid with β-Crystalline Phase from the Induced Alignment of Electrospun Fibers

In-Vivo Microsystems: A Review

Experimentation of a Wearable Self‐Powered Jacket Harvesting Body Heat for Wearable Device Applications

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