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1. Automatic detection of foreign body objects in neurosurgery using a deep learning approach on intraoperative ultrasound images: From animal models to first in-human testing

Author

Haley G. Abramson, Eli J. Curry, Griffin Mess, Rasika Thombre, Kelley M. Kempski-Leadingham, Shivang Mistry, Subhiksha Somanathan, Laura Roy, Nancy Abu-Bonsrah, George Coles, Joshua C. Doloff, Henry Brem, Nicholas Theodore, Judy Huang, and Amir Manbachi

Subjects
Surgery
Abstract

Objects accidentally left behind in the brain following neurosurgical procedures may lead to life-threatening health complications and invasive reoperation. One of the most commonly retained surgical items is the cotton ball, which absorbs blood to clear the surgeon’s field of view yet in the process becomes visually indistinguishable from the brain parenchyma. However, using ultrasound imaging, the different acoustic properties of cotton and brain tissue result in two discernible materials. In this study, we created a fully automated foreign body object tracking algorithm that integrates into the clinical workflow to detect and localize retained cotton balls in the brain. This deep learning algorithm uses a custom convolutional neural network and achieves 99% accuracy, sensitivity, and specificity, and surpasses other comparable algorithms. Furthermore, the trained algorithm was implemented into web and smartphone applications with the ability to detect one cotton ball in an uploaded ultrasound image in under half of a second. This study also highlights the first use of a foreign body object detection algorithm using real in-human datasets, showing its ability to prevent accidental foreign body retention in a translational setting.

Published
2022

2. DESIGN OF AN ULTRASOUND PROBE HOLDER TO MINIMIZE MOTION ARTIFACT DURING SONOGRAPHY

Author

Molly Acord, Betty Tyler, Nicholas Theodore, Ana Ainechi, Smruti Mahapatra, Fariba Aghabaglou, Tarana Parvez Kaovasia, Sufia Ainechi, Eli J. Curry, and Amir Manbachi

Subjects
Functional imaging, Artifact (error), Ultrasound probe, business.industry, Computer science, Ultrasound, business, Intraoperative imaging, Article, Biomedical engineering
Abstract

Standard diagnostic ultrasound imaging procedures heavily rely on a sonographer for image acquisition. Given the ultrasound probe is manually manipulated by the sonographer, there is a potential for noise artifacts like blurry acquired images caused by involuntary hand movements. Certain surgical procedures can also cause patients to exhibit involuntary “jumping” movements while on the operating table leading to further deterioration in ultrasound image quality. In this study, we attempt to mitigate these problems by fabricating a 3D-printed ultrasound probe holder. Due to the lightweight nature of the device, it can attach to surgical retractors without influencing the functionality of the retractor. Therefore, the 3D printed probe holder not only reduces relative motion between the probe and the patient, but also reduce the need for a sonographer during complex surgeries.

Published
2022

3. Transdermal microneedles for the programmable burst release of multiple vaccine payloads

Author

Tyler D Gavitt, Avi Patel, Roxana Piotrowska, Thanh D. Nguyen, Neha Mishra, Eli J. Curry, Nicholas Farrell, Steven M. Szczepanek, Khanh Thi My Tran, Arlind B Mara, Lindsey Brown, and Shawn Kilpatrick

Subjects
0301 basic medicine, Single administration, Immune protection, Poor compliance, business.industry, Biomedical Engineering, Medicine (miscellaneous), Bioengineering, Pharmacology, Computer Science Applications, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Bolus (medicine), Immune system, Preclinical testing, Medicine, business, 030217 neurology & neurosurgery, Biotechnology, Transdermal, Alternative strategy
Abstract

Repeated bolus injections are associated with higher costs and poor compliance and can hinder the implementation of global immunization campaigns. Here, we report the development and preclinical testing of patches of transdermal core-shell microneedles-which were fabricated by the micromoulding and alignment of vaccine cores and shells made from poly(lactic-co-glycolic acid) with varying degradability kinetics-for the preprogrammed burst release of vaccine payloads over a period of a few days to more than a month from a single administration. In rats, microneedles loaded with a clinically available vaccine (Prevnar-13) against the bacterium Streptococcus pneumoniae induced immune responses that were similar to immune responses observed after multiple subcutaneous bolus injections, and led to immune protection against a lethal bacterial dose. Microneedle patches delivering preprogrammed doses may offer an alternative strategy to prophylactic and therapeutic protocols that require multiple injections.

Published
2020

4. Exercise-induced piezoelectric stimulation for cartilage regeneration in rabbits

Author

Yang Liu, Godwin Dzidotor, Thinh T. Le, Tra Vinikoor, Kristin Morgan, Eli J. Curry, Ritopa Das, Aneesah McClinton, Ellen Eisenberg, Lorraine N. Apuzzo, Khanh T. M. Tran, Pooja Prasad, Tyler J. Flanagan, Seok-Woo Lee, Ho-Man Kan, Meysam T. Chorsi, Kevin W. H. Lo, Cato T. Laurencin, and Thanh D. Nguyen

Subjects
Cartilage, Articular, Cartilage, Tissue Engineering, Tissue Scaffolds, Osteoarthritis, Animals, Regeneration, General Medicine, Rabbits, Chondrogenesis
Abstract

More than 32.5 million American adults suffer from osteoarthritis, and current treatments including pain medicines and anti-inflammatory drugs only alleviate symptoms but do not cure the disease. Here, we have demonstrated that a biodegradable piezoelectric poly(L-lactic acid) (PLLA) nanofiber scaffold under applied force or joint load could act as a battery-less electrical stimulator to promote chondrogenesis and cartilage regeneration. The PLLA scaffold under applied force or joint load generated a controllable piezoelectric charge, which promoted extracellular protein adsorption, facilitated cell migration or recruitment, induced endogenous TGF-β via calcium signaling pathway, and improved chondrogenesis and cartilage regeneration both in vitro and in vivo. Rabbits with critical-sized osteochondral defects receiving the piezoelectric scaffold and exercise treatment experienced hyaline-cartilage regeneration and completely healed cartilage with abundant chondrocytes and type II collagen after 1 to 2 months of exercise (2 to 3 months after surgery including 1 month of recovery before exercise), whereas rabbits treated with nonpiezoelectric scaffold and exercise treatment had unfilled defect and limited healing. The approach of combining biodegradable piezoelectric tissue scaffolds with controlled mechanical activation (via physical exercise) may therefore be useful for the treatment of osteoarthritis and is potentially applicable to regenerating other injured tissues.

Published
2022

5. Biodegradable nanofiber-based piezoelectric transducer

Author

Ritopa Das, Meysam T. Chorsi, Jeffrey Baroody, Elise M Santorella, Asiyeh Golabchi, Thanh D. Nguyen, M. Daniela Morales-Acosta, X. Tracy Cui, Brian Ko, Eli J. Curry, Thinh T. Le, Khanh Thi My Tran, Jianlin Feng, I-Ping Chen, Debayon Paul, Lixia Yue, Xiaonan Xin, David W. Rowe, Joel S. Pachter, Emily R Borges, Qian Wu, and Kai Ke

Subjects
Materials science, Transducers, Nanofibers, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Drug Delivery Systems, Electricity, Tissue engineering, Absorbable Implants, Pressure, Ultrasonics, Monitoring, Physiologic, Multidisciplinary, Tissue Engineering, Equipment Design, Prostheses and Implants, Micro-Electrical-Mechanical Systems, 021001 nanoscience & nanotechnology, Pressure sensor, Piezoelectricity, 0104 chemical sciences, Transducer, Nanofiber, Physical Sciences, Drug delivery, Ultrasonic sensor, Electronics, 0210 nano-technology, Actuator
Abstract

Piezoelectric materials, a type of “smart” material that generates electricity while deforming and vice versa, have been used extensively for many important implantable medical devices such as sensors, transducers, and actuators. However, commonly utilized piezoelectric materials are either toxic or nondegradable. Thus, implanted devices employing these materials raise a significant concern in terms of safety issues and often require an invasive removal surgery, which can damage directly interfaced tissues/organs. Here, we present a strategy for materials processing, device assembly, and electronic integration to 1) create biodegradable and biocompatible piezoelectric PLLA [poly(l-lactic acid)] nanofibers with a highly controllable, efficient, and stable piezoelectric performance, and 2) demonstrate device applications of this nanomaterial, including a highly sensitive biodegradable pressure sensor for monitoring vital physiological pressures and a biodegradable ultrasonic transducer for blood–brain barrier opening that can be used to facilitate the delivery of drugs into the brain. These significant applications, which have not been achieved so far by conventional piezoelectric materials and bulk piezoelectric PLLA, demonstrate the PLLA nanofibers as a powerful material platform that offers a profound impact on various medical fields including drug delivery, tissue engineering, and implanted medical devices.

Published
2019

6. Design and Fabrication of a Focused Ultrasound Device for Minimallyinvasive Neurosurgery: Reporting a Second, Miniaturized and Mrcompatible Prototype with Steering Capabilities

Author

Tarana Parvez Kaovasia, Tim Xiong, Mark G. Luciano, Molly Acord, Kyle P. Morrison, Nao J. Gamo, Fariba Aghabaglou, Eli J. Curry, Betty Tyler, and Amir Manbachi

Subjects
medicine.medical_specialty, Fabrication, Computer science, business.industry, Ultrasound, Mr compatible, medicine, Neurosurgery, business, Article, Focused ultrasound, Biomedical engineering
Abstract

Many surgeons are faced with inoperable or only partially operable brain lesions, such as tumors. Even when surgery is feasible, patient outcomes are greatly affected by blood loss or infection. This has led many physicians toward non- or minimally-invasive surgery, which demands specialized toolkits. Focused ultrasound has great potential for assisting in such procedures due to its ability to focus a few centimeters away from the surface of the transducer. In a prior study, we developed a focused ultrasound prototype that could fit within a BrainPath trocar, specifically made for minimally invasive brain surgery. Here, we present the design and fabrication of a second prototype that reduces size, is MR-compatible, and has electronic steering capabilities.

Published
2021

7. A Miniature Laser Speckle Contrast Imager for Monitoring the Neuromodulatory Effect of Transcranial Ultrasound Stimulation

Author

Fariba Aghabaglou, Amir Manbachi, Yinuo Zeng, Nicholas Theodore, Nitish V. Thakor, Junfeng Sun, Molly Acord, Eli J. Curry, Shanbao Tong, Tarana Parvez Kaovasia, and Peng Miao

Subjects
business.industry, media_common.quotation_subject, Ultrasound, Stimulation, Blood flow, Article, Neuromodulation (medicine), Transcranial Doppler, Speckle pattern, Cerebral blood flow, Medicine, Contrast (vision), business, Biomedical engineering, media_common
Abstract

Transcranial focused ultrasound stimulation is a neuromodulation technique that is capable of exciting or suppressing the neural network. Such neuro-modulatory effects enable the treatment of brain diseases non-invasively, such as treating stroke. The neuro-modulatory effect on cerebral hemodynamics has been monitored using laser speckle contrast imaging in animal studies. However, the bulky size and stationary nature of the imaging system constrains the application of this imaging technique on research that requires the animal to have different body positions or to be awake. We present the design of a system that combines a miniature microscope for laser speckle contrast imaging and transcranial focused ultrasound stimulation, as well as, test its capability to monitor cerebral hemodynamics during stimulation and compare the result with a benchtop imaging system.

Published
2021

8. Automatic detection of cotton balls during brain surgery: where deep learning meets ultrasound imaging to tackle foreign objects

Author

Shenandoah Robinson, Yohannes Tsehay, Jeong Hun Kim, Betty Tyler, Molly Acord, Christina Diana Ghinda, Henry Brem, Judy Huang, Ana Ainechi, Venkat Kuppoor, Smruti Mahapatra, Jennifer K. Son, Aliaksei Pustavoitau, Amir Manbachi, Nicholas Theodore, Eli J. Curry, Manish Balamurugan, Fariba Aghabaglou, Kathryn Chung, and Tarana Parvez Kaovasia

Subjects
medicine.medical_specialty, Handheld ultrasound, business.industry, Computer science, Deep learning, Ultrasound, Cotton balls, Article, Object detection, Textilomas, Surgery, medicine, Ultrasound imaging, Ball (bearing), Artificial intelligence, business, human activities, psychological phenomena and processes
Abstract

Cotton balls are a versatile and efficient tool commonly used in neurosurgical procedures to absorb fluids and manipulate delicate tissues. However, the use of cotton balls is accompanied by the risk of accidental retention in the brain after surgery. Retained cotton balls can lead to dangerous immune responses and potential complications, such as adhesions and textilomas. In a previous study, we showed that ultrasound can be safely used to detect cotton balls in the operating area due to the distinct acoustic properties of cotton compared with the acoustic properties of surrounding tissue. In this study, we enhance the experimental setup using a 3D-printed custom depth box and a Butterfly IQ handheld ultrasound probe. Cotton balls were placed in variety of positions to evaluate size and depth detectability limits. Recorded images were then analyzed using a novel algorithm that implements recently released YOLOv4, a state-of-the-art, real-time object recognition system. As per the radiologists’ opinion, the algorithm was able to detect the cotton ball correctly 61% of the time, at approximately 32 FPS. The algorithm could accurately detect cotton balls up to 5mm in diameter, which corresponds to the size of surgical balls used by neurosurgeons, making the algorithm a promising candidate for regular intraoperative use.

Published
2021

9. The development of Smart Hospital Assistant: integrating artificial intelligence and a voice-user interface for improved surgical outcomes

Author

Amir Manbachi, Fariba Aghabaglou, Japesh Patel, Eli J. Curry, Jeong Hun Kim, Brian Y. Hwang, Nicholas Theodore, Yohannes Tsehay, Jeff Ehresman, Richard Um, Rajiv R Iyer, Ana Ainechi, Betty Tyler, Smruti Mahapatra, and Jonathan Liu

Subjects
Multimedia, business.industry, Computer science, Health technology, Surgical operation, computer.software_genre, Remote assistance, Article, Patient safety, Voice user interface, Smart hospital, Health care, Operating time, business, computer
Abstract

Efficiency and patient safety are top priorities in any surgical operation. One effective way to achieve these objectives is automating many of the logistical and routine tasks that occur in the operating room. Inspired by smart assistant technology already commonplace in the consumer sector, we engineered the Smart Hospital Assistant (SHA), a smart, voice-controlled virtual assistant that handles natural speech recognition while executing a plurality of functions to aid surgery. Simulated surgeries showed that the SHA reduced operating time, optimized surgical staff resources, and reduced the number of major touch points that can lead to surgical site infections. The SHA not only shows its potential in the operating room, but also in other healthcare environments that may benefit from having virtual smart assistant technology.

Published
2021

11. Biodegradable Piezoelectric Force Sensor

Author

Horea T. Ilieş, Prashant K. Purohit, Kevin W.-H. Lo, Jianlin Feng, Meysam T. Chorsi, Cato T. Laurencin, Thanh D. Nguyen, Lixia Yue, Chia-Ling Kuo, Eli J. Curry, Qian Wu, Kai Ke, Albert N. Miller, Kinga S. Wrobel, Insoo Kim, and Avi Patel

Subjects
Materials science, Piezoelectric sensor, Polyesters, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Force sensor, Mice, Electricity, Absorbable Implants, Pressure, Animals, Humans, Electronics, Monitoring, Physiologic, Multidisciplinary, 021001 nanoscience & nanotechnology, Biocompatible material, Pressure sensor, Piezoelectricity, Biomechanical Phenomena, 0104 chemical sciences, Physical Sciences, Drug delivery, 0210 nano-technology, Internal forces, Biomedical engineering
Abstract

Measuring vital physiological pressures is important for monitoring health status, preventing the buildup of dangerous internal forces in impaired organs, and enabling novel approaches of using mechanical stimulation for tissue regeneration. Pressure sensors are often required to be implanted and directly integrated with native soft biological systems. Therefore, the devices should be flexible and at the same time biodegradable to avoid invasive removal surgery that can damage directly interfaced tissues. Despite recent achievements in degradable electronic devices, there is still a tremendous need to develop a force sensor which only relies on safe medical materials and requires no complex fabrication process to provide accurate information on important biophysiological forces. Here, we present a strategy for material processing, electromechanical analysis, device fabrication, and assessment of a piezoelectric Poly-l-lactide (PLLA) polymer to create a biodegradable, biocompatible piezoelectric force sensor, which only employs medical materials used commonly in Food and Drug Administration-approved implants, for the monitoring of biological forces. We show the sensor can precisely measure pressures in a wide range of 0-18 kPa and sustain a reliable performance for a period of 4 d in an aqueous environment. We also demonstrate this PLLA piezoelectric sensor can be implanted inside the abdominal cavity of a mouse to monitor the pressure of diaphragmatic contraction. This piezoelectric sensor offers an appealing alternative to present biodegradable electronic devices for the monitoring of intraorgan pressures. The sensor can be integrated with tissues and organs, forming self-sensing bionic systems to enable many exciting applications in regenerative medicine, drug delivery, and medical devices.

Published
2018

12. 3D nano- and micro-patterning of biomaterials for controlled drug delivery

Author

Thanh D. Nguyen, Eli J. Curry, Atta D Henoun, and Albert N. Miller

Subjects
Drug, Materials science, media_common.quotation_subject, Microfluidics, Pharmaceutical Science, 3D printing, Biocompatible Materials, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Drug Delivery Systems, Nano, DNA origami, media_common, Drug Carriers, business.industry, 021001 nanoscience & nanotechnology, Controlled release, 0104 chemical sciences, Printing, Three-Dimensional, Drug delivery, 0210 nano-technology, business, Drug carrier
Abstract

Recently, there has been an emerging interest in controlling 3D structures and designing novel 3D shapes for drug carriers at nano- and micro-scales. Certain 3D shapes and structures of drug particles enable transportation of the drugs to desired areas of the body, allow drugs to target specific cells and tissues, and influence release kinetics. Advanced nano- and micro-manufacturing methods including 3D printing, photolithography-based processes, microfluidics and DNA origami have been developed to generate defined 3D shapes and structures for drug carriers. This paper reviews the importance of 3D structures and shapes on controlled drug delivery, and the current state-of-the-art technologies that allow the creation of novel 3D drug carriers at nano- and micro-scales.

Published
2017

13. Biodegradable piezoelectric force sensor (Rising Researcher Paper)

Author

Thanh D. Nguyen and Eli J. Curry

Subjects
Materials processing, Computer science, Nanotechnology, Electronics, Internal forces, Biocompatible material, Piezoelectricity, Pressure sensor, Force sensor
Abstract

Measuring vital physiological pressures is important for monitoring health status, preventing the buildup of dangerous internal forces in impaired organs, and enabling novel approaches of using mechanical stimulation for tissue regeneration. Pressure sensors are often required to be implanted and directly integrated with native soft biological systems. Therefore, the devices should be flexible and at the same time, biodegradable, to avoid invasive removal surgery that can damage directly-interfaced tissues. Despite recent achievements in degradable electronic devices, there is still a tremendous need to develop a force sensor which only relies on safe medical materials and requires no complex fabrication process to provide accurate information on important bio-physiological forces. Here, we present a new strategy for material processing, electromechanical analysis, device fabrication, and assessment of a new piezoelectric Poly-L-lactide (PLLA) polymer to create a biodegradable, biocompatible piezoelectric force-sensor which only employs medical materials used commonly in FDA-approved implants, for the monitoring of biological forces

Published
2019

14. Biodegradable Piezoelectric Sensor

Author

Thanh D. Nguyen and Eli J. Curry

Subjects
Materials processing, Computer science, Piezoelectric sensor, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Biocompatible material, 01 natural sciences, Pressure sensor, Force sensor, 0104 chemical sciences, Electronics, 0210 nano-technology, Internal forces
Abstract

Measuring vital physiological pressures is important for monitoring health status, preventing the buildup of dangerous internal forces in impaired organs, and enabling novel approaches of using mechanical stimulation for tissue regeneration. Pressure sensors are often required to be implanted and directly integrated with native soft biological systems. Therefore, the devices should be flexible and at the same time, biodegradable, to avoid invasive removal surgery that can damage directly-interfaced tissues. Despite recent achievements in degradable electronic devices, there is still a tremendous need to develop a force sensor which only relies on safe medical materials and requires no complex fabrication process to provide accurate information on important bio-physiological forces. Here, we present a new strategy for material processing, electromechanical analysis, device fabrication, and assessment of a new piezoelectric Poly-L-lactide (PLLA) polymer to create a biodegradable, biocompatible piezoelectric force-sensor which only employs medical materials used commonly in FDA-approved implants, for the monitoring of biological forces.

Published
2019

15. Transdermal microneedles for the programmable burst release of multiple vaccine payloads

Author

Khanh T M, Tran, Tyler D, Gavitt, Nicholas J, Farrell, Eli J, Curry, Arlind B, Mara, Avi, Patel, Lindsey, Brown, Shawn, Kilpatrick, Roxana, Piotrowska, Neha, Mishra, Steven M, Szczepanek, and Thanh D, Nguyen

Subjects
Vaccines, Drug Delivery Systems, Needles, Vaccination, Animals, Administration, Cutaneous, Rats
Abstract

Repeated bolus injections are associated with higher costs and poor compliance and can hinder the implementation of global immunization campaigns. Here, we report the development and preclinical testing of patches of transdermal core-shell microneedles-which were fabricated by the micromoulding and alignment of vaccine cores and shells made from poly(lactic-co-glycolic acid) with varying degradability kinetics-for the preprogrammed burst release of vaccine payloads over a period of a few days to more than a month from a single administration. In rats, microneedles loaded with a clinically available vaccine (Prevnar-13) against the bacterium Streptococcus pneumoniae induced immune responses that were similar to immune responses observed after multiple subcutaneous bolus injections, and led to immune protection against a lethal bacterial dose. Microneedle patches delivering preprogrammed doses may offer an alternative strategy to prophylactic and therapeutic protocols that require multiple injections.

Published
2019

16. Biodegradable nanofiber bone-tissue scaffold as remotely-controlled and self-powering electrical stimulator

Author

Casey Bednarz, Jayla Millender, Shunyi Li, Kevin W.-H. Lo, Joemart Contreras, Guleid Awale, Thinh T. Le, Thanh D. Nguyen, Eli J. Curry, Ritopa Das, Sharareh Emadi, Yang Liu, David W. Rowe, and Xiaonan Xin

Subjects
Bone growth, Scaffold, Materials science, Renewable Energy, Sustainability and the Environment, Biomaterial, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Bone tissue, 01 natural sciences, 0104 chemical sciences, medicine.anatomical_structure, Tissue engineering, Nanofiber, medicine, General Materials Science, Electrical and Electronic Engineering, Stem cell, 0210 nano-technology, Bone regeneration, Biomedical engineering
Abstract

Electrical stimulation (ES) has been shown to induce and enhance bone regeneration. By combining this treatment with tissue-engineering approaches (which rely on biomaterial scaffolds to construct artificial tissues), a replacement bone-graft with strong regenerative properties can be achieved while avoiding the use of potentially toxic levels of growth factors. Unfortunately, there is currently a lack of safe and effective methods to induce electrical cues directly on cells/tissues grown on the biomaterial scaffolds. Here, we present a novel bone regeneration method which hybridizes ES and tissue-engineering approaches by employing a biodegradable piezoelectric PLLA (Poly(L-lactic acid)) nanofiber scaffold which, together with externally-controlled ultrasound (US), can generate surface-charges to drive bone regeneration. We demonstrate that the approach of using the piezoelectric scaffold and US can enhance osteogenic differentiation of different stem cells in vitro, and induce bone growth in a critical-sized calvarial defect in vivo. The biodegradable piezoelectric scaffold with applied US could significantly impact the field of tissue engineering by offering a novel biodegradable, battery-free and remotely-controlled electrical stimulator.

Published
2020

17. Piezoelectric Biomaterials for Sensors and Actuators

Author

Hamid T. Chorsi, Horea T. Ilieş, Thanh D. Nguyen, Jeffrey Baroody, Eli J. Curry, Ritopa Das, Prashant K. Purohit, and Meysam T. Chorsi

Subjects
Materials science, New materials, Nanotechnology, Biocompatible Materials, 02 engineering and technology, Biosensing Techniques, 010402 general chemistry, 01 natural sciences, Electricity, Microsystem, General Materials Science, Organic Chemicals, Monitoring, Physiologic, Microelectromechanical systems, Tissue Engineering, Mechanical Engineering, Micro-Electrical-Mechanical Systems, 021001 nanoscience & nanotechnology, Biocompatible material, Piezoelectricity, 0104 chemical sciences, Mechanics of Materials, Inorganic Chemicals, 0210 nano-technology, Actuator, Microfabrication
Abstract

Recent advances in materials, manufacturing, biotechnology, and microelectromechanical systems (MEMS) have fostered many exciting biosensors and bioactuators that are based on biocompatible piezoelectric materials. These biodevices can be safely integrated with biological systems for applications such as sensing biological forces, stimulating tissue growth and healing, as well as diagnosing medical problems. Herein, the principles, applications, future opportunities, and challenges of piezoelectric biomaterials for medical uses are reviewed thoroughly. Modern piezoelectric biosensors/bioactuators are developed with new materials and advanced methods in microfabrication/encapsulation to avoid the toxicity of conventional lead-based piezoelectric materials. Intriguingly, some piezoelectric materials are biodegradable in nature, which eliminates the need for invasive implant extraction. Together, these advancements in the field of piezoelectric materials and microsystems can spark a new age in the field of medicine.

Published
2018

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