Introduction to Piezoelectric Perovskites
Page: 1-21 (21)
Author:
DOI: 10.2174/9789815256383124010003
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Abstract
Perovskite (Calcium titanium oxide), which was discovered in 1839 by
Perovski, a Russian mineralogist, has some favorable photophysical characteristics that
enable perovskite and its nanocrystals to be used in the field of biomedical research.
Presently, perovskites are being explored for various medical applications, including
X-ray detection and imaging, cancer treatment, orthopedic implants and as
antimicrobial agents. Advancements in nanocrystal research allowed the exploration of
perovskites for their antibacterial, antifungal and antiviral activity against Severe Acute
Respiratory Syndrome Corona Virus 2 (SARS-CoV-2). The antibacterial activity of
several perovskite nanoparticles was explored, and to mention a few, Cesium lead
bromide and zinc oxide perovskite nanoparticles showed activity against Escherichia
coli, while Lanthanum potassium ferrate and silver-based perovskites against
Staphylococcus aureus and Pseudomonas aeruginosa. This chapter will review the
potential research studies that explored the anti-microbial activity of perovskites and
their nanoparticles against bacteria, viruses, fungi and other microorganisms and
provide insight into the mechanisms by which these particles exert antimicrobial
action. Further, this chapter will discuss the potential biomedical applications of the
antimicrobial activity of perovskites.
Techniques for the Synthesis of Piezoelectric Perovskites
Page: 22-39 (18)
Author:
DOI: 10.2174/9789815256383124010004
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Abstract
Perovskite structures have strong piezoelectric properties, making them
suitable for a wide range of applications such as sensors, energy harvesting devices and
actuators. The chapter examines numerous synthesis procedures, including coprecipitation, hydrothermal, solid-state reaction, the Pechini process, sol-gel autocombustion, low temperature, and pulsed-laser decomposition. Each technique's
principles, benefits, limits, and special concerns are given, along with instances of
successful perovskite synthesis. Furthermore, the chapter examines current advances
and upcoming trends in the area, offering insights into the future direction of
piezoelectric perovskite synthesis.
Structural Analysis of Piezoelectric Perovskite Materials
Page: 40-59 (20)
Author:
DOI: 10.2174/9789815256383124010005
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Abstract
Perovskite (Calcium titanium oxide)was discovered in 1839 by Alekseevich
Perovski, a Russian mineralogist. Perovskites are materials with the same structure as
calcium titanium oxide (CaTiO3
) mineral or you can say that all the materials with the
same structure as CaTiO3
are perovskites. The basic structure of perovskite is ABX3
,
where the A-site is generally occupied by large twelve coordinated cations and B by
smaller, octahedrally coordinated cations, and X is a common anion, for instance,
Oxygen. A cation is divalent and B is tetravalent cation. Tilting of BO6
octahedra
through B-O-B linkage results in rhombohedral, orthorhombic and tetragonal
structures. The structure of perovskites can be modified by doping and altering
synthesis techniques, such as by changing pH value, calcination temperature, and
calefactive velocity. Perovskite materials have a wide range of applications in different
fields, such as solar cells, photodetectors, sensors, water purification, etc.
Ferroelectric and Piezoelectric Response of Perovskites
Page: 60-81 (22)
Author:
DOI: 10.2174/9789815256383124010006
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Abstract
Perovskite materials, with their unique properties and distinct crystal
structure, have proven themselves as one of the most promising materials for various
advanced technological applications. The exploration of ferroelectric and piezoelectric
materials has gained significant attention in the field of condensed matter physics and
materials science, and consequently, it is giving an edge to nanoengineered materials.
This book chapter presents a comprehensive exploration of the ferroelectric and
piezoelectric response exhibited by perovskite materials based on their crystal structure
and other governing properties. The chapter begins with an introduction to perovskite
structures, highlighting their crystallographic arrangement and the underlying
principles governing their ferroelectric and piezoelectric behaviors. Finally, the chapter
explores the diverse technological applications enabled by the unique ferroelectric and
piezoelectric properties of perovskites. It discusses their utilization in sensors,
actuators, energy harvesting devices, memory storage, and other emerging fields. The
chapter concludes with an outlook on future directions and challenges in the field. The
extensive study of the ferroelectric and piezoelectric response of perovskites will serve
as a valuable resource for researchers, engineers, and students seeking to understand
the underlying principles, characterization techniques, and potential applications of
perovskite material.
“Perovskite”: A Key Material for the Biomedical Industry
Page: 82-102 (21)
Author:
DOI: 10.2174/9789815256383124010007
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Abstract
Perovskite materials are well-known for their remarkable thermal,
optoelectronic, and magnetic capabilities. This chapter examines current advances in
the study of biological applications involving perovskites. This chapter looks at how
organic-inorganic hybrid perovskites can be used for X-ray detection and imaging. This
can be achieved by switching to Cs+
-cations or MA+/Cs+ alloyed motifs, which not
only widen the band gaps but also enhance the structural stability of perovskite
materials. The future research direction should focus on fabricating large-area and thick
2D perovskite absorbers on thin-film transistor arrays through compatible printing
(polycrystalline) and self-assembled (monocrystalline) methods to achieve X-ray
detectors and imagers with high sensitivities and responsivities. The detailed material
phases of La0.7Sr0.3Mn0.98Ti0.02O3
perovskite nanoparticles have not been unambiguously
elucidated due to inaccurate relative compositions of metal cations. Therefore,
insightful structural analysis of the material is needed for confirmation of the
magnetically thermally active phase. In the case of perovskite La2NiMnO6
nanoparticles, their ability to desorb BSA protein molecules has not been studied,
which is required to fully comprehend the binding/detachment dynamics of enzyme
reactions. Finally, the future research direction of CaTiO3
-based composites is to
further understand their structure-property relationships under more complicated
chemical environments with variations in temperature, pH, and pressure, given their
promising biocompatibility and cytotoxicity.
Perovskites as Biocompatible Materials
Page: 103-122 (20)
Author:
DOI: 10.2174/9789815256383124010008
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Abstract
Perovskite inorganic perovskite-type oxides are intriguing nanomaterials
with numerous uses in electrochemical sensing, fuel cells, and catalysis. Because they
are catalytic when employed as electrode modifiers, perovskites made at the nanoscale
have recently attracted a lot of attention. These oxides have stronger catalytic activity
than many compounds made of transition metals and even some oxides of precious
metals. They display desirable physical and chemical properties like electronic
conductivity, electrical activity, oxygen content variations, mobility of oxide ions
through the crystal lattice, thermal and chemical stability, and super-magnetic,
photocatalytic, thermoelectric, and dielectric properties. In oxygen reduction and
hydrogen evolution events, nano-perovskites have been used as catalysts because they
have strong electrocatalytic activity, low activation energy, and strong electron transfer
kinetics. Additionally, some perovskites provide good prospects for the production of
efficient anodic catalysts with high catalytic performance for direct fuel cells. They can
improve the performance of the catalytic process in terms of selectivity, sensitivity,
exceptional long-term stability, good repeatability, and interference-fighting capacity.
Impact of Perovskites on Cell Response
Page: 123-142 (20)
Author:
DOI: 10.2174/9789815256383124010009
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Abstract
This chapter investigates how perovskite materials affect animal cell
responsiveness and sheds light on possible biomedical uses. Perovskites are interesting
prospects for a variety of biomedical applications because of their distinctive physical
and chemical characteristics. The discussion of perovskites' interactions with cells
includes their uptake and internalization by cells, as well as how cells react to scaffolds
and substrates made of perovskites. The chapter also explores how the composition,
structure, surface chemistry, and stability of perovskites affect cell behavior and
response. Examining signaling cascades and intracellular destiny, mechanistic insights
into perovskite-cell interactions are considered. The chapter concludes by examining
existing and potential uses and risks involved with perovskite materials on tissues and
regeneration of cells, identifying difficulties and pointing the way forward for further
study. This chapter offers insightful information on how perovskites affect cell
responsiveness, opening the door for the creation of ground-breaking perovskite-based
biomedical solutions.
Anti-Microbial Activity of Perovskites
Page: 143-153 (11)
Author:
DOI: 10.2174/9789815256383124010010
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Abstract
Perovskites can be used to develop new drugs and materials to combat
antimicrobial resistance. These materials are useful in the field of biomedicine due to
their chemical properties. They can also be used in the treatment of cancer and other
diseases. Researchers are investigating the fate and behavior of perovskites in the
environment to assess any potential risks and develop appropriate disposal and
recycling methods. Perovskite materials have emerged as a new class of antimicrobial
agents with potential applications in various fields. Their unique crystal structure,
synthesis methods, and mechanisms of antimicrobial activity make them promising
alternatives or add-on agents to conventional antimicrobial agents. The antimicrobial
activity of perovskites presents new opportunities for addressing the challenges posed
by antimicrobial resistance. Continued research and development efforts are necessary
to optimize perovskite synthesis, enhance their stability, evaluate their toxicity, and
explore their practical applications in healthcare, water purification, food preservation,
textiles, and environmental remediation. In summary, the antimicrobial activity of
perovskite materials holds great promise in combating infectious diseases and
addressing the growing threat of antimicrobial resistance. Continued research and
technological advancements in this field can contribute to the development of effective
and sustainable antimicrobial strategies.
Bone Regeneration and Bone Growth Using Perovskites
Page: 154-174 (21)
Author:
DOI: 10.2174/9789815256383124010011
PDF Price: $15
Abstract
Perovskite materials are becoming more popular in biomedical applications,
notably bone tissue engineering and regenerative medicine. Their distinct physical
features, such as high dielectric constant, ambipolar charge transfer, and
ferroelectricity, make them ideal for bone regeneration. Perovskite-based scaffolds may
replicate bone tissue's extracellular matrix and encourage cell behavior, hence aiding
bone tissue regeneration. These materials have the potential to completely transform
bone defect and injury therapy in regenerative medicine. However, issues like
degradation, scalability, toxicity, device interaction, and cost must be solved before
they can be widely used. To overcome these challenges, it is necessary to improve
stability, scalability, and repeatability, reduce toxicity, achieve device compatibility,
reduce manufacturing costs, and develop standardized testing and safety norms. To
completely understand the biocompatibility and long-term effectiveness of perovskite
materials in bone treatment, further studies and development are required. Despite
these difficulties, perovskite materials offer promise in the treatment of bone
abnormalities and fractures by acting as scaffolds for bone regeneration, medication
delivery vehicles, and imaging agents. Overall, perovskite materials have the potential
to improve bone regeneration and advance musculoskeletal disease therapies.
Perovskites for Bone Replacement
Page: 175-193 (19)
Author:
DOI: 10.2174/9789815256383124010012
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Abstract
Similar to other transition metal oxides with the same formula, ABO3
,
perovskite has a cubic or nearly cubic structure. According to where the electron and
energy band gaps are located, perovskite materials can be divided into three categories,
with the third combining the first two. The first type has localized electrons while the
second type has delocalized energy-band states, and the third type is a transition
between the abovementioned two types. There are several types of perovskites,
including Layered Perovskite, Perovskite ABO3
, Double Perovskite, and Triple
Perovskite. The important characteristics relevant to oxide and oxide-like perovskite
crystals are insulator-metal transition, ionic conduction characteristics, dielectric,
superconducting, alteration of solid-state phenomenon, and metallic properties.
Recently, a number of perovskite applications, including those for random access
memories, actuators, tunable microwave displays, piezoelectric devices, transducers,
wireless communications, sensors, and capacitors, have been investigated.
Electrochromic, photochromic, and filtering devices all demonstrate perovskite's great
utility in surface acoustic wave signal processing.
Bone Tissue Engineering Using Perovskites in Regenerative Medicines
Page: 194-210 (17)
Author:
DOI: 10.2174/9789815256383124010013
PDF Price: $15
Abstract
Regeneration of damaged bone tissue can be accomplished by mimicking
the extracellular matrix (ECM) by generating porous topographic substrates. The
process of bone tissue regeneration is supported by incorporating natural proteins and
growth factors. The scaffolds developed for bone tissue regeneration support bone cell
growth and induce bone-forming cells by using natural proteins and growth factors.
Limitations associated with the referred approaches are improper scaffold stability,
insufficient cell adhesion, proliferation, differentiation and mineralization with less
expression of growth factor. Therefore, the use of engineered nanoparticles has been
rapidly increasing in bone tissue engineering applications. The electrospray technique
that produces nanomaterials has an advantage over other conventional methods as it
generates particle sizes in the micro/nanoscale range. The size and charge of the
particles are controlled by regulating the flow rate and electric voltage of the polymer
solution. The unique properties of nanoparticles are the large surface area to volume
ratio, small size and higher reactivity, making them a suitable substrate to be used in
the field of biomedical engineering. These nanomaterials are extensively used for drug
delivery as therapeutic agents, mimicking cellular components of extracellular matrix
and restoring and improving the functions of damaged organs. The controlled and
sustained release of encapsulated drugs, proteins, vaccines, growth factors, cells and
nucleotides from nanoparticles has been well-established in nanomedicine. The present
chapter provides insights into the preparation of nanoparticles by electrospraying and
illustrates the use of nanoparticles in drug delivery for the purpose of bone tissue
engineering.
Perovskite as Tooth-Filling Material in Secondary Tooth
Page: 211-229 (19)
Author:
DOI: 10.2174/9789815256383124010014
PDF Price: $15
Abstract
The incidence of dental problems is increasing owing to the modern
lifestyle, sticky food and poor dental hygiene. Root canal treatment is one of the most
common clinical practices in conservative dentistry. Despite the availability of various
GIC materials, strength and durability remain the most common concerns. The
mechanical properties of tooth filling material are compromised due to disturbances in
glass and liquid composition or powder/liquid ratio, glass particle size, pretreatment,
manual mixing. The intrinsic porosity is also influenced by reduced viscosity or
compared with proportionate liquid ratio, resulting in increased porosity in the cement
structure. The availability of nanoparticles, specifically that of perovskites, opens a
new dimension. Since they are relatively smaller in size, they can offer stronger
binding and cementing properties.
Neurotrauma and Neurodegenerative Treatment Using Perovskites
Page: 230-241 (12)
Author:
DOI: 10.2174/9789815256383124010015
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Abstract
Neurodegenerative disease (ND) is a progressive neurological condition that
leads to damage to the neuronal connection essential for various sensory, motor and
cognitive functions. Neurotrauma (NT) is an external injury to the brain or spinal cord.
The incidence and prevalence of ND and NT are alarmingly increasing owing to
several factors such as food intake, modern lifestyle, increased life expectancy and
several other comorbid conditions. The identification of novel materials that can cross
the BBB and delay or deny the onset and progress of neuropathophysiology of ND is
essential. Perovskite, a nanomaterial with some specific characteristics such as
semiconducting, photoemitting, photothermal, ferromagnetic and cations exchange
properties, fosters the need for further exploration in the treatment of NDs and
neurotrauma (NT). With subsequent research, the toxic side effects of perovskite are
also minimized with the synthesis of lead-free perovskite. Various computational
models, such as neuro-morphic networking, are used to explore the ability of
perovskites to facilitate neural synapsis in NDs and NT. Potential identification of the
novel pathway of ND directs in modifying the strategic intervention of ND. Initial
findings regarding the application of perovskites in the treatment of NDs and NT have
shown promising outcomes that need further exploration.
Perovskite for Antifouling Treatment
Page: 242-258 (17)
Author:
DOI: 10.2174/9789815256383124010016
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Abstract
Fouling is a significant issue in wastewater treatment processes, leading to
reduced efficiency and increased operational costs. Perovskite materials have emerged
as a promising solution for antifouling treatment in wastewater systems due to their
unique properties and versatile applications. This book chapter provides an overview of
the recent advancements in perovskite-based antifouling strategies and highlights the
challenges that need to be addressed for their practical implementation. Traditional
antifouling strategies often involve the use of toxic chemicals that have detrimental
effects on marine ecosystems. Therefore, there is a growing need for environmentally
friendly and sustainable alternatives. In recent years, perovskite materials have
emerged as a promising candidate for antifouling treatments due to their unique
physicochemical properties. The use of perovskite materials in antifouling applications
primarily relies on two approaches: photodynamic and photocatalytic mechanisms.
Photodynamic antifouling involves the generation of reactive oxygen species (ROS)
upon exposure to light, which can effectively disrupt and prevent the attachment and
growth of fouling organisms. On the other hand, photocatalytic antifouling employs
perovskite materials as catalysts to trigger chemical reactions that degrade fouling
organisms or their adhesion mechanisms. By harnessing their unique properties,
perovskite-based coatings have demonstrated significant antifouling capabilities.
Continued research and development efforts are necessary to overcome technical
challenges and evaluate the long-term effectiveness and environmental implications,
ultimately paving the way for the practical application of perovskite-based antifouling
treatments in diverse marine industries.
Perovskite Sensors to Monitor Physical Health
Page: 259-279 (21)
Author:
DOI: 10.2174/9789815256383124010017
PDF Price: $15
Abstract
Due to its one-of-a-kind qualities, such as high sensitivity, cheap cost, and
simplicity of manufacture, perovskite sensors have shown a lot of potential in the field
of monitoring a person's physical health. This is especially true in light of recent
research. This is due to the fact that producing perovskite sensors is a straightforward
and low-cost process. In this chapter, an investigation is conducted into the potential
uses of perovskite sensors in the realm of medical care. The application of perovskite
sensors in the monitoring of vital signs, the detection of biomarkers, and the
incorporation of such capabilities into wearable devices is receiving a lot of attention at
the moment. This article delves further into the fundamentals of how perovskite sensors
function, the many methods of their manufacture, as well as the difficulties and
opportunities associated with using these sensors in medical settings. This chapter will
throw light on the prospects that have surfaced in the area of perovskite sensors for
monitoring physical health, as well as the improvements that have been achieved in the
field of perovskite sensors. This chapter will shed light on the advances that have been
made, which is the primary goal of the chapter.
Bionic Prosthesis Using Perovskite Materials
Page: 280-303 (24)
Author:
DOI: 10.2174/9789815256383124010018
PDF Price: $15
Abstract
Bionic prosthesis have revolutionized the field of medical science by
providing individuals with limb loss the ability to regain functionality and
independence. Traditional prosthetic materials, such as metals and plastics, have
limitations in terms of weight, durability, and biocompatibility. The emergence of
perovskite materials has opened up new possibilities for developing advanced bionic
prosthesis. This chapter explores the application of perovskite materials in bionic
prosthesis, highlighting their unique properties and potential advantages. It also
discusses the challenges and future directions for utilizing perovskite materials in the
development of next-generation bionic prosthesis.
Perovskite-Based Bio-Implantable Energy Harvesters
Page: 304-320 (17)
Author:
DOI: 10.2174/9789815256383124010019
PDF Price: $15
Abstract
Energy harvesters based on perovskite nanomaterials have garnered
significant attention in academia and industry because of their ability to transform
mechanical and thermal energies into electric power. These materials have a great deal
of promise for capturing body-induced and human activity-induced energy to power
implantable and portable low-power devices. This book chapter builds upon previous
works that have explored innovative materials and nanotechnologies for fabricating
ferroelectric generators. We give a brief overview of flexible piezoelectric and
pyroelectric energy harvesters' material selection procedure and reasonable
microstructure design. We also stress the unique abilities of perovskite materials as
energy collectors in biomedical applications, which include both conventional
ferroelectrics and recently developed ferroelectric biomaterials. Additionally, we
discuss the newest integration structures of hybrid generators with ferroelectric
nanomaterials, which significantly enhance the functionalities of the energy harvesters,
particularly for biological and implantable applications.
Issues Perovskites Encounter in the Biomedical Industry
Page: 321-344 (24)
Author:
DOI: 10.2174/9789815256383124010020
PDF Price: $15
Abstract
Within the context of the medical field, this chapter explores the possible
uses of perovskite materials, piezoelectric nanogenerators (PENGs), piezoelectric
biomaterials, and metal halide nanocrystals. As a result of their one-of-a-kind qualities,
perovskite materials have recently gained attention as possible candidates for use in
medical diagnostics, treatments, and imaging methods. However, before their broad
application in the biomedical sector, difficulties relating to biocompatibility, stability,
biodegradability, integration with current technologies, and scalability need to be
overcome. PENGs provide self-powered health monitoring devices and may be utilized
as a power source for microdevices and bio-implants, bypassing the limits of current
power sources. PENGs are also capable of being employed as a power source for other
applications. Theranostic methods, tissue regeneration, and drug delivery systems are
all potential uses for piezoelectric biomaterials like BT, ZnO, and nanoparticles based
on BFO. Nanocrystals made of metal halides, such as CsPbX3, have extraordinary
light-harvesting capabilities that make them ideal for use in photonic-based biomedical
applications. These applications include multi-photon excitation for cellular imaging
and photoactivated treatment. Additional study is required to fully investigate the
capabilities of these materials and find solutions to the obstacles that stand in the way
of their clinical use. Some of these obstacles include biocompatibility, biodegradability,
and tissue accumulation.
Future Prospects of Piezoelectric Perovskite Materials
Page: 345-362 (18)
Author:
DOI: 10.2174/9789815256383124010021
PDF Price: $15
Abstract
Piezoelectric perovskite materials have emerged as a promising class of
materials due to their unique combination of piezoelectric properties, mechanical
stability, and wide bandgap. This abstract presents an overview of the future prospects
of piezoelectric perovskite materials, focusing on their potential applications and
ongoing research efforts. The future prospects of piezoelectric perovskite materials lie
in their application in various fields, including energy harvesting, sensors, actuators,
and piezoelectric devices. These materials have the ability to convert mechanical
energy into electrical energy and vice versa, offering opportunities for self-powered
systems and wireless sensing applications. Additionally, their compatibility with
flexible substrates opens up possibilities for the development of wearable and flexible
electronics. One avenue of research focuses on lead-free perovskite materials,
addressing the environmental concerns associated with lead-based perovskites.
Extensive efforts have been made to explore alternative compositions, such as bismuthbased perovskites, which show promising piezoelectric properties. The development of
lead-free perovskite materials will contribute to the sustainability and wider adoption of
piezoelectric devices. Another area of interest is the integration of perovskite materials
with other technologies, such as nanogenerators and energy storage systems. By
combining piezoelectric perovskites with other functional materials, synergistic effects
can be achieved, leading to enhanced performance and efficiency in energy conversion
and storage. Furthermore, ongoing research is focused on improving the synthesis
methods, understanding the fundamental mechanisms underlying the piezoelectric
behavior, and optimizing the performance of piezoelectric perovskite materials.
Advanced characterization techniques, including in-situ measurements and modeling
approaches, are being employed to gain deeper insights into the material properties and
enhance their performance.
Introduction
Biomedical Applications of Perovskites: The Era of Bio-Piezoelectric Systems focuses on recent developments in the area of piezoelectric systems and their biomedical applications. A compilation of 19 edited chapters covers different piezoelectric materials, device designs, and their use cases. Readers will be familiarized with the many perovskite materials being used in research and development as well as the role they play in designing novel medical devices and biomaterials. Key Features - systematically explains the piezoelectric perovskite materials starting from their introduction, their structure and synthesis techniques - explains the key materials used in devices such as pacemakers and nanogenerators - highlights a range of applications including bone regeneration and growth, bone replacement, tissue engineering, dental science, neurotrauma and neurodegenerative disease treatment and bionic prosthesis - discusses future challenges and the roadmap for piezoelectric perovskite materials - Presents scientific references for advanced reading