The Rising Pulse Field Ablation Market Driven By Increasing Adoption For Complex Cardiac Ablations

Pulsed field ablation is a minimally invasive procedure that is used to treat cardiac arrhythmias through applying electromagnetic pulses for ablating heart tissues. It delivers high electric fields which selectively target and ablate cardiac tissues without damaging surrounding structures.This reduces risk of complications like blood clots, and charring as compared to radiofrequency ablation.The procedure is generally preferred for complex ablations involving ablation of critical structures like the pulmonary veins, mitral isthmus and cavotricuspid isthmus line. The rising prevalence of cardiovascular diseases and increasing focus on early treatment and management of complex cardiac arrhythmias is driving the demand for pulsed field ablation globally.

The Pulsed Field Ablation Market is estimated to be valued at US$ 3.52 Bn in 2024 and is expected to exhibit a CAGR of 7.8% over the forecast period of 2024 to 2031.

Key Takeaways

Key players operating in the pulsed field ablation market are Medtronic, Boston Scientific, Johnson & Johnson (Biosense Webster), Abbott Laboratories, Kardium. Key players are focusing on developing advanced pulsed field ablation catheters and systems with improved navigation, precision and safety. The growing adoption of minimally invasive cardiac ablation procedures for treating arrhythmias is a major factor boosting demand. Technological advancements including incorporation of 3D catheter tracking and visualization is allowing pulsed field ablation to be utilized for more complex ablations with improved outcomes.

Market Trends

One of the key trends witnessed in the pulsed field ablation market is the development of pulsed field ablation catheters and system with irrigated tip technology. Irrigated tip ablation helps in overcoming challenges of steam pops and charring by maintaining tip-tissue interface. This improves safety and efficacy of ablation. Another trend is the increasing integration of pulsed field ablation with robotic navigation systems. Robotic pulsed field ablation allows electrophysiologists to perform complex ablations more precisely with improved ergonomics. This is expected to drive adoption.

Market Opportunities

Rising focus on emerging economies in Asia Pacific and Latin America presents significant growth opportunities due to increasing healthcare expenditure and focus on early treatment of cardiovascular diseases in these regions. Growing popularity of minimally invasive cardiac procedures also provides scope for pulsed field ablation adoption. Development of pulsed field ablation solutions suitable for pediatric cardiac ablations further aids in expanding indications.

Impact Of COVID-19 On Pulsed Field Ablation Market Growth

The COVID-19 pandemic has significantly impacted the growth of the pulsed field ablation market. During the initial lockdown phases in 2020, elective medical procedures like pulsed field ablation were postponed to avoid unnecessary exposure and prioritize urgent treatments. This led to a decline in the demand for pulsed field ablation products as their usage was limited only for emergency cases.

As restrictions eased in mid-2020, market players started instilling heightened safety measures like sanitization, social distancing and use of personal protective equipment during pulsed field ablation procedures to prevent infection spread. However, hospitals continued to maintain selective treatment approach and capacity limits due to resource constraints and priority cases. This hampered the market recovery during the remainder of 2020 and through 2021.

Gradually as vaccination drives were rolled out on a mass scale from late-2021 to 2022, confidence levels of patients as well as healthcare facilities improved. More resources were diverted for non-COVID care and pulsed field ablation procedures regained lost momentum. Market players focused on expanding operational capabilities and setup virtual or hybrid care models to bridge care gaps. Various government bodies and private organizations also ramped up investments to cater to postponed medical needs and overcome backlogs. These measures helped strengthen the adoption of pulsed field ablation in the post-COVID period. Going forward, market players need to invest in healthcare infrastructure development, supply chain resilience, workforce training programs and innovations to sustain gains achieved in the recovery phase. Telehealth can play a bigger role to provide affordable and accessible care. Sustained vaccination efforts and streamlined infection control protocols will further aid unhindered growth in the future.

North America Pulsed Field Ablation Market Growth

In terms of value, North America contributed the largest share to the Pulsed Field Ablation Market in 2022. Presence of advanced healthcare infrastructure and universal health coverage aided early market penetration across the US and Canada. Favorable reimbursement policies increased affordability of pulsed field ablation procedures.

Rising prevalence of atrial fibrillation, an arrhythmia commonly treated with pulsed field ablation, drove the regional market. According to estimates, over 6 million Americans were likely to be diagnosed with atrial fibrillation by 2030. This high disease burden attracted public and private investments towards innovative ablation treatments. In addition, presence of leading ablation device manufacturers in the US benefited regional market access. Patented product portfolios ensured price premiums and steady revenue stream. Moreover, developed economies with higher patient affordability and awareness levels enabled North America to maintain its dominance in the global landscape.

Fastest Growing Asia Pacific Pulsed Field Ablation Market Region

The Asia Pacific region is poised to witness the fastest growth in the pulsed field ablation market during the forecast period. This can be attributed to rising healthcare expenditures, rapid economic development and growing focus towards non-communicable disease management across developing countries. China, India and South Korea in particular are expected to fuel the regional market expansion due to their huge population bases and unmet medical needs. Escalating incidence rates of diabetes and hypertension, both leading risk factors for atrial fibrillation, have significantly escalated the patient pool requiring ablation treatment. Favorable government initiatives aimed at boosting healthcare access through universal coverage and infrastructure investments are also aiding the market growth. Various multinational medtech companies have directed their focus towards developing cost-effective ablation solutions tailored for this region. Emergence of regional generics manufacturing hubs has improved local availability while lowering overall treatment costs. All these factors are contributing to Asia Pacific emerging as the most lucrative market for pulsed field ablation globally.

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What Are The Key Data Covered In This Pulsed Field Ablation Market Report?

:- Market CAGR throughout the predicted period

:- Comprehensive information on the aspects that will drive the Pulsed Field Ablation Market's growth between 2024 and 2031.

:- Accurate calculation of the size of the Pulsed Field Ablation Market and its contribution to the market, with emphasis on the parent market

:- Realistic forecasts of future trends and changes in consumer behaviour

:- Pulsed Field Ablation Market Industry Growth in North America, APAC, Europe, South America, the Middle East, and Africa

:- A complete examination of the market's competitive landscape, as well as extensive information on vendors

:- Detailed examination of the factors that will impede the expansion of Pulsed Field Ablation Market vendors

FAQ’s

Q.1 What are the main factors influencing the Pulsed Field Ablation Market?

Q.2 Which companies are the major sources in this industry?

Q.3 What are the market’s opportunities, risks, and general structure?

Q.4 Which of the top Pulsed Field Ablation Market companies compare in terms of sales, revenue, and prices?

Q.5 Which businesses serve as the Pulsed Field Ablation Market’s distributors, traders, and dealers?

Q.6 How are market types and applications and deals, revenue, and value explored?

Q.7 What does a business area’s assessment of agreements, income, and value implicate?

*Note: 1. Source: Coherent Market Insights, Public sources, Desk research 2. We have leveraged AI tools to mine information and compile it

“A New Wave in Cardiac Care: Pulsed Field Ablation Market Analysis (2024-2033)”

Pulsed Field Ablation (PFA) is revolutionizing the treatment of atrial fibrillation, offering a safer, more precise alternative to traditional ablation methods. By using electrical pulses to selectively target and destroy abnormal heart tissue without damaging surrounding areas, PFA minimizes complications and speeds up recovery. As cardiac care advances, PFA is gaining momentum as the next big innovation in electrophysiology, providing hope for millions affected by irregular heart rhythms.

#PulsedFieldAblation #HeartHealth #AtrialFibrillation #CardiacInnovation #Electrophysiology #NextGenAblation #MinimallyInvasive #CardiacCare #MedicalBreakthrough #HeartRhythmTreatment

U.S. Assisted Living Facility Market Size, Trends, Statistics and Analysis, 2030

The U.S. assisted living facility market size was valued at USD 91.8 billion in 2022 and is expected to expand at a compound annual growth rate (CAGR) of 5.53% from 2023 to 2030. 

Major factor driving the market growth is the growing geriatric population seeking companionship, security, and assistance with daily activities, are residing in ALFs. The rise in the geriatric population due to increased life expectancy is expected to grow rapidly in the future. According to National Institute on Aging (NIA), globally, around 8.5% of the population is aged 65 and above. As per data published by Population Reference Bureau, the number of Americans aged 65 years & above is projected to reach 95 million by 2060, from 52 million in 2018.

Gather more insights about the market drivers, restrains and growth of the U.S. Assisted Living Facility Market

The rise in the geriatric population due to increased life expectancy is expected to grow rapidly in the future. According to National Institute on Aging (NIA), globally, around 8.5% of the population is aged 65 and above. As per data published by Population Reference Bureau, the number of Americans aged 65 years & above is projected to reach 95 million by 2060, from 52 million in 2018.

Technological developments for ALFs are expected to propel its U.S. market. The development of sophisticated & easy-to-use devices and services, such as Internet-enabled home monitors, telemedicine, and apps for mobile health, is likely to boost the market over the forecast period.

U.S. Assisted Living Facility Market Segmentation

Grand View Research has segmented the U.S. assisted living facility market report based on age and region:

Age Outlook (Revenue, USD Billion, 2017 - 2030)

• More than 85

• 75-84

• 65-74

• Less than 65

Region Outlook (Revenue, USD Billion, 2017 - 2030)

• West

• South

• Midwest

• Northeast

Browse through Grand View Research's Medical Devices Industry Research Reports.

• The global pulsed field ablation market size was estimated at USD 116.6 million in 2023 and is projected to grow at a CAGR of 37.7% from 2024 to 2030.

• The global retinal imaging devices market size was estimated at USD 3.74 billion in 2023 and is expected to grow at a CAGR 7.9% from 2024 to 2030.

Key Companies & Market Share Insights

The U.S. market for the assisted living facility is consolidated with a presence of a few large and various medium & small service providers. Sunrise Senior Living, Brookdale Senior Living, and Kindred Healthcare, LLC are some of the established ALF providers in the U.S. Service providers are taking initiatives such as the construction of new facilities to strengthen their market presence. For instance, in January 2021, Kindred Healthcare, LLC and Tampa General Hospital initiated the construction of a joint rehabilitation facility as per their joint venture in May 2020.

Some of the key players in the U.S. assisted living facility market include:

• Kindred Healthcare, LLC

• Brookdale Senior Living Inc.

• Sunrise Senior Living, LLC

• Atria Senior Living, Inc.

• Five Star Senior Living

• Capital Senior Living

• Merrill Gardens

• Integral Senior Living (ISL)

• Belmont Village, L.P.

• Gardant Management Solutions 

Order a free sample PDF of the U.S. Assisted Living Facility Market Intelligence Study, published by Grand View Research. 

Development of a Wireless Temperature Sensor Using Polymer-Derived Ceramics

A temperature sensor has been developed using an embedded system and a sensor head made of polymer-derived SiAlCN ceramics (PDCs). PDC is a promising material for measuring high temperature and the embedded system features low-power consumption, compact size, and wireless temperature monitor. The developed temperature sensor has been experimentally tested to demonstrate the possibility of using such sensors for real world applications.

1. Introduction

Accurate temperature measurements are crucial for many applications, such as chemical processing, power generation, and engine monitoring. As a result, development of temperature sensors has always been a focus of microsensor field. A variety of materials have been studied for temperature sensor applications, for example, semiconducting silicon and silicon carbide. Silicon based sensors are typically used at temperatures lower than 350°C due to accelerated material degradation at higher temperature [1, 2]. Silicon carbide based sensors are better than silicon based sensors in high temperature measurement and can be applied in temperatures up to 500°C [3–5].

Polymer-derived SiAlCN ceramics (PDCs) are another widely studied material that demonstrate properties such as excellent high temperature stability [6] as well as good oxidation/corrosion resistance [7]. PDCs have been considered as a promising material for measuring high temperature [8]. Our early works have showed that PDC sensor head can accurately measure high temperature up to 830°C [9] using data acquisition system from National Instruments. The cost and size of the sensor system must be significantly reduced before it can be deployed for real world applications. In this paper, we develop a temperature sensor using PDC and an embedded system. Comparing to the National Instruments data acquisition equipment used in the previous paper, the newly developed embedded sensor is much smaller (9.7 dm3 versus 0.3 dm3), lighter (5.97 kg versus 0.19 kg), and cheaper (approximately $8000 versus $170). A WiFi module is also added so the temperature measurement can be transmitted wirelessly. The embedded board and WiFi module used in this paper are commercially available. The experiments in this paper demonstrate the possibility of deploying PDC based sensors for real world applications.

2. Fabrication of the PDC Sensor Head

In this study, the PDC sensor head is fabricated by following the procedure reported previously [9]. In brief, 8.8 g of commercially available liquid-phased polysilazane (HTT1800, Kion) and 1.0 g of aluminum-tri-sec-butoxide (ASB, Sigma-Aldrich) are first reacted together at 120°C for 24 hours under constant magnetic stirring to form the liquid precursor for SiAlCN. The precursor is then cooled down to room temperature, followed by adding 0.2 g of dicumyl peroxide (DP) into the liquid under sonication for 30 minutes. DP is the thermal initiator which can lower the solidification temperature and tailor the electrical properties [10]. The resultant liquid mixture is solidified by heat-treatment at 150°C for 24 hours. The disk-shaped green bodies are then prepared by ball-milling the solid into fine powder of ~1 μm and subsequently uniaxially pressing. A rectangular-shaped sample is cut from the discs and pyrolyzed at 1000°C for 4 hours. The entire fabrication is carried out in high-purity nitrogen to avoid any possible contamination.

Pt wires are attached to the sensor head by two ceramic fasteners on the two mounting holes on the diagonal of the sensor head. To improve the conductivity, both mounting holes are coated with Pt plasma; see Figure 1.

To measure temperature using the PDC sensor, the processor needs to perform the following tasks: () supply voltage  to the circuit through DAC7724; () sample the circuit output  using AD7656 and convert the output to temperature measurement; and () transmit data to readers from the RS232 port.

The input signal  to the conversion circuit is a sinusoidal signal of ±10 V. The sinusoidal signal can bypass the parasitic capacitor in series to the PDC probe. The noise from the furnace coil can also be greatly subdued. The sensor output voltage  is approximately sinusoidal as well and its magnitude can be computed using Fast Fourier Transformation (FFT) or curve fitting using recursive least square method (RLSM) [11]. Comparing to FFT, RLSM is more computationally efficient but may have numerical instability because TMS320F28335 only supports IEEE 754 floating-point arithmetic. Here we prefer FFT for fast prototyping purpose because Texas Instruments provides FPU library that performs floating FFT routines on C2000 series microcontroller. Next we explain how the sensor works.

A high-priority interrupt service request (ISR1) based on a CPU timer continues reading a look-up-table and drives the DAC7724 to generate the input signal . The frequency of  is controlled by the frequency of ISR1. ISR1 also samples circuit output from AD7656 and adds the data to a 1024-point buffer if there is no FFT running. Once the buffer is filled up, ISR1 stops writing the buffer and the FFT routine starts. The FFT routine is implemented in another slower low-priority interrupt service (ISR2). Once the FFT routine is completed, ISR2 will give ISR1 the permission to clean and write the input buffer again. The magnitude from the FFT is used as the circuit output . The software flowchart is shown in Figure 4.

High temperature sensors capable of operating in harsh environments are needed in order to prevent disasters caused by structural or system functional failures due to increasing temperatures. Most existing temperature sensors do not satisfy the needs because they require either physical contact or a battery power supply for signal communication, and furthermore, neither of them can withstand high temperatures nor rotating applications. This paper presents a novel passive wireless temperature sensor, suitable for working in harsh environments for high temperature rotating component monitoring. A completely passive LC resonant telemetry scheme, relying on a frequency variation output, which has been applied successfully in pressure, humidity and chemical measurement, is integrated with a unique high-k temperature sensitive ceramic material, in order to measure the temperatures without contacts, active elements, or power supplies within the sensor. In this paper, the high temperature sensor design and performance analysis are conducted based on mechanical and electrical modeling, in order to maximize the sensing distance, the Q factor and the sensitivity. In the end, the sensor prototype is fabricated and calibrated successfully up to 235ºC, so that the concept of temperature sensing through passive wireless communication is proved.

This paper aims to develop a prototype for a web-based wireless remote temperature monitoring device for patients. This device uses a patient and coordinator set design approach involving the measurement, transmission, receipt and recording of patients’ temperatures via the MiWi wireless meter iot solution. The results of experimental tests on the proposed system indicated a wider distance coverage and reasonable temperature resolution and standard deviation. The system could display the temperature and patient information remotely via a graphical-user interface as shown in the tests on three healthy participants. By continuously monitoring participants’ temperatures, this device will likely improve the quality of the health care of the patients in normal ward as less human workload is involved.

Background

During the severe acute respiratory syndrome (SARS) outbreak in 2003, hospitals became treatment centres in most countries. Because a patient’s core body temperature is one vital parameter for monitoring the progress of the patient’s health, it is often measured manually at a frequency ranging from once every few hours to once a day [1]. However, such manual measurement of the temperature of patients requires the efforts of many staff members. In addition, when the patients suffer from conditions that result in abrupt changes of the core body temperature, e.g., due to infection at a surgical site after surgery, the staff on duty will not know such a temperature change occurred until the next temperature measurement. Such a delay may lead to patients being unnoticed while their health conditions worsen, which is dangerous because a difference of 1.5 degrees Celsius can result in adverse outcomes [2]. Furthermore, there is always a need to have a monitoring system to improve the quality of health care [3], such as temperature monitoring of elderly and challenged persons using a wireless remote temperature monitoring system.

Body temperature can be used to monitor the pain level of a patient following an operation [4] or after shoulder endoprosthesis [5]. In some cases, the tissue transient temperature was monitored during microwave liver ablation [6] for the treatment of liver metastases. Instead of using a temperature sensor, pulse-echo ultrasound [7] was used to visualize changes in the temperature of the patient’s body. In addition, a non-contact temperature-measuring device, such as a thermal imaging camera [8], was successfully used to detect human body temperature during the SARS outbreak. However, it can be quite expensive to equip each patient room with a thermal imaging camera. In addition, there are a few wireless temperature measuring solution (e.g., CADIT™, Primex™, and TempTrak™) on the market that are used to monitor and store a patient’s temperature for medical research by using body sensor networks [9]. Most of these systems consist of an electronic module and a temperature-sensing device. The systems include a stand-alone electronic module with a display screen that allows the temperature sensor data to be transmitted over a secure wireless network.

However, these systems can be difficult to reconfigure to suit the current database system used in the hospital. In addition, the current systems using short message service (SMS)-based telemedicine [10] systems with hardware equipment were developed to monitor the mobility of patients. However, proper hardware and software to manage the messages and the patient’s temperature for display on mobile phones are not widely available.

Hence, a medical device to continuously measure the body temperature of patients using a wireless temperature receiver [4,11,12] is required. With such a wireless temperature sensor system, nurses will no longer have to manually measure the temperature of patients, which will free their time for other tasks and also reduce the risk associated with coming into contact with patients with contagious diseases, such as SARS. The readings will be transmitted wirelessly to the central nurse station, where they can be monitored by the staff-on-duty. In addition, the current and past history of the body temperature measurements can be stored in an online database, which allows the medical staff to access the database when they are not in the hospital.

To the best of our knowledge, a MiWi wireless (besides using the Zigbee[11]) temperature-monitoring system using a patient and coordinator set design that provides remote internet access to the temperature database has not been reported in any publication. The objective is therefore to develop and implement a prototype temperature-monitoring system for patients using a MiWi wireless remote connection to the nurse’s station for frequent real-time monitoring. The temperature monitoring system was designed based on a proposed patient and coordinator set design approach. The proposed temperature-monitoring system for use in normal ward will likely to improve the quality of the health care of the patients as the nursing workload is reduced. In this paper, the discussion on medical regulations and policy will not be included.

Global Irreversible Electroporation Ablators Market 2019 | Manufacturers In-Depth Analysis Report to 2024

The latest trending report Global Irreversible Electroporation Ablators Market 2019-2024 added by DecisionDatabases.com

Irreversible electroporation is a soft tissue ablation technique using ultra short but strong electrical fields to create permanent and hence lethal Nano pores in the cell membrane, to disrupt the cellular homeostasis. The resulting cell death results from apoptosis and not necrosis as in all other thermal or radiation based ablation techniques. The main use of IRE lies in tumor ablation in regions where precision and conservation of the extracellular matrix, blood flow and nerves are of importance. The technique is in an experimental stage and has not been approved for use outside of clinical trials. IRE is used in the NanoKnife System.

The worldwide market for Irreversible Electroporation Ablators is expected to grow at a CAGR of roughly xx% over the next five years, will reach xx million US$ in 2024, from xx million US$ in 2019.

This report focuses on the Irreversible Electroporation Ablators in global market, especially in North America, Europe and Asia-Pacific, South America, Middle East and Africa. This report categorizes the market based on manufacturers, regions, type and application.

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Market Segment by Manufacturers, this report covers

·             AngioDynamics

·             Pulse Biosciences

Market Segment by Regions, regional analysis covers

·             North America (United States, Canada and Mexico)

·             Europe (Germany, France, UK, Russia and Italy)

·             Asia-Pacific (China, Japan, Korea, India and Southeast Asia)

·             South America (Brazil, Argentina, Colombia etc.)

·             Middle East and Africa (Saudi Arabia, UAE, Egypt, Nigeria and South Africa)

Market Segment by Type, covers

·             Generator

·             Part

·             Service

Market Segment by Applications, can be divided into

·             Liver

·             Pancreas

·             Prostate

·             Other

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The content of the study subjects, includes a total of 15 chapters: Chapter 1, to describe Irreversible Electroporation Ablators product scope, market overview, market opportunities, market driving force and market risks. Chapter 2, to profile the top manufacturers of Irreversible Electroporation Ablators, with price, sales, revenue and global market share of Irreversible Electroporation Ablators in 2017 and 2018. Chapter 3, the Irreversible Electroporation Ablators competitive situation, sales, revenue and global market share of top manufacturers are analyzed emphatically by landscape contrast. Chapter 4, the Irreversible Electroporation Ablators breakdown data are shown at the regional level, to show the sales, revenue and growth by regions, from 2014 to 2019. Chapter 5, 6, 7, 8 and 9, to break the sales data at the country level, with sales, revenue and market share for key countries in the world, from 2014 to 2019. Chapter 10 and 11, to segment the sales by type and application, with sales market share and growth rate by type, application, from 2014 to 2019. Chapter 12, Irreversible Electroporation Ablators market forecast, by regions, type and application, with sales and revenue, from 2019 to 2024. Chapter 13, 14 and 15, to describe Irreversible Electroporation Ablators sales channel, distributors, customers, research findings and conclusion, appendix and data source.

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Our expert research analysts have been trained to map client’s research requirements to the correct research resource leading to a distinctive edge over its competitors. We provide intellectual, precise and meaningful data at a lightning speed.

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Excimer Laser Market -  High-Power Ultraviolet Output Which Is Making It Useful For Surgery

An excimer laser, also known as exciplex laser, is one of the form of ultraviolet laser which is has major applications in the production of microelectronic equipment and devices, eye surgery, semiconductor based integrated chips or circuits and micromachining. An excimer laser primarily consists of reactive gas, for instance chlorine or fluorine along with noble gas, for example, krypton, argon, xenon. The excimer laser market has been segmented into by emission wavelength which includes less than 200 nm, 200 nm – 300 nm and more than 300 nm. The market has been segmented into by end use industry which includes industrial equipment, aerospace and military, automotive, healthcare among others. The market for excimer laser by region has been segmented into, Asia Pacific, North America, Europe, South America and MEA (Middle East and Africa).

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The major industrial end use of excimer lasers has been in microelectronic equipment and devices along ultraviolet photolithography. Moreover, excimer lasers have high-power ultraviolet output which is making it useful for surgery, which is one of the driving factors which fuel the application of excimer lasers in medical devices. Furthermore, excimer lasers have major applications in research laboratory equipment. Major end use of excimer lasers include laser ablation, photolithography for semiconductor chips, pulsed laser deposition, the microstructuring of transparent media, laser marking, eye surgery, dye-laser pumping and psoriasis treatment. With the growing technological advancement and research activities in the field of excimer lasers, the advanced and upgraded excimer lasers are having a positive impact on the market. Advanced excimer lasers primarily offers combination of short pulse duration and high pulse energy in the UV wavelengths. These prime attributes combine to offer a unique photonics tool primarily for the commercialization of novel end uses which include LTPS (low temperature poly-Si) annealing in FPD (flat panel display), pulsed laser deposition in thin-film manufacturing, direct patterning in advanced packaging markets and surface hardening in automotive sector. The lifetime of an excimer laser is limited by gas contamination, dust created by the electric discharge, corrosion processes, apart from problems with the high-voltage electronics. These challenges may inhibit the application of excimer laser in different end use industries which is considered as one of the restraining factor for the market. Cyclical nature of semiconductor industry may be considered as one of the challenging factor which may inhibit the growth of the excimer laser market. However, application of excimer laser for different end use industries which include manufacturing, construction and power generation is one of the prime opportunities for the market.

In 2016, North America accounted for the largest market share in terms of revenue for the excimer laser market, followed by Europe and Asia Pacific. The U.S. is leading the market for excimer laser in North America. Germany, the U.K., Italy, France among others are contributing positive share in the excimer lasers market. In Asia Pacific, China, Japan, and India, South Korea among others are some of the major market contributing in the positive development of the market for excimer lasers. In Middle East and Africa, there has been considerable advancement and development in the field of electronics and other industries for example; automotive sector is fueling the demand for excimer lasers market. In South America, Brazil and Argentina are anticipated to contribute positive growth over the forecast period from 2017 to 2025.

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Coherent, Inc. (The U.S.), Alcon Inc. (The U.S.), Wavelength Opto-Electronic (S) Pte Ltd. (Singapore), NIDEK CO., LTD. (Japan), AMS Technologies AG (Germany), Laser 2000 GmbH (Germany), Radiant Dyes Laser & Accessoires GmbH (Germany), Ziemer Ophthalmic Systems AG (Switzerland) among others are some of the prime companies operating in the excimer laser market globally.

The report offers a comprehensive evaluation of the market. It does so via in-depth qualitative insights, historical data, and verifiable projections about market size. The projections featured in the report have been derived using proven research methodologies and assumptions. By doing so, the research report serves as a repository of analysis and information for every facet of the market, including but not limited to: Regional markets, technology, types, and applications.

Microscope Market Analysis, Opportunities And Forecast Report 2024-2030

The global microscope market size was estimated at USD 11.94 billion in 2023 and is projected to grow at a compound annual growth rate (CAGR) of 8.0% from 2024 to 2030. 

Growing applications and high demand for technologically advanced magnification devices is driving the market. Furthermore, the market is experiencing growth due to increased demand from the healthcare sector and the rapidly expanding semiconductor industry. Additionally, the adoption of microscopy to facilitate research endeavors fuels the demand for microscopes.

Gather more insights about the market drivers, restrains and growth of the Microscope Market

In order to improve market penetration, the microscope industry is currently undergoing advancements in technology, developing types that boast faster performance and incorporate user-friendly sample preparation techniques. Furthermore, the ongoing technical advancements, including integration with display modalities for high-definition imaging and 3-dimensional views, are poised to drive increased demand for microscopes throughout the forecast period.

The sector is expanding through the incorporation of cutting-edge technologies such as the Internet of Things (IoT) and extended ultraviolet lithography (EUVL) and deep learning. IoT creates a need for memory, connectivity, sensors, and microcontrollers, employing neural networks to improve the type of Integrated Circuits (ICs). Meanwhile, EUVL plays a pivotal role in the manufacturing of high-end computing chips. Electron microscopy, providing high-resolution imaging, enables a thorough assessment ranging from packaged devices to atomic-level gate structures. Systems based on electron beams are applied in scrutinizing the sources of device failures to optimize the manufacturing process.

The growing emphasis on research and development in areas like neuroscience, life sciences, nanotechnology, and semiconductor technology is anticipated to drive the adoption of microscopes. These instruments, known for their high image resolution, are essential for investigating cell signaling pathways and studying cancer cell proliferation. Furthermore, scanning probe microscopes offer versatility by not relying on the wavelength of the light source for magnification, making them suitable for diverse environments such as gas and liquid and allowing the examination of insulator and conductor specimens.

Browse through Grand View Research's Medical Devices Industry Research Reports.

• The global pulsed field ablation market size was estimated at USD 116.6 million in 2023 and is projected to grow at a CAGR of 37.7% from 2024 to 2030.

• The global retinal imaging devices market size was estimated at USD 3.74 billion in 2023 and is expected to grow at a CAGR 7.9% from 2024 to 2030.

Microscope Market Segmentation

Grand View Research has segmented the global microscope market report based on type, application, and region:

Type Outlook (Revenue, USD Million, 2018 - 2030)

• Optical

• Electron

• Scanning Probe

• Others

Application Outlook (Revenue, USD Million, 2018 - 2030)

• Material Science

• Nanotechnology

• Life Science

• Semiconductors

• Other Applications

Regional Outlook (Revenue, USD Million, 2018 - 2030)

• North America

• U.S.

• Canada

• Europe

• UK

• Germany

• France

• Italy

• Spain

• Denmark

• Sweden

• Norway

• Asia Pacific

• Japan

• China

• India

• South Korea

• Australia

• Thailand

• Latin America

• Brazil

• Mexico

• Argentina

• Middle East & Africa

• South Africa

• Saudi Arabia

• UAE

• Kuwait

Key Microscope Company Insights

Key players such as Thermo Fisher Scientific, Inc, Bruker Corporation and Zeiss Group have been focusing on product innovation, expanding their service offerings, and improving operational efficiency. Additionally, these industry leaders often engage in strategic collaborations, acquisitions, and partnerships to strengthen their market presence and maintain a competitive edge in the rapidly evolving field of microscopy.

Emerging players such as CAMECA and Joel ltd. are actively pursuing strategies to establish their presence by introducing innovative technologies, forming strategic partnerships, and focusing on niche applications. Furthermore, these players are leveraging technological advancements and strategic partnerships to compete effectively with established market leaders.

Key Microscope Companies:

The following are the leading companies in the microscope market. These companies collectively hold the largest market share and dictate industry trends. Financials, strategy maps & products of these microscope companies are analyzed to map the supply network.

• Zeiss Group

• Bruker Corporation

• CAMECA

• Thermo Fisher Scientific, Inc.

• Nikon Corporation

• Olympus Corporation

• NT-MDT SI

• Hitachi High-Tech Corporation

• JEOL Ltd.

• Oxford Instruments (Asylum Corporation)

Recent Developments

• In November 2023, Ashoka University partnered with Carl Zeiss India (Bangalore) Pvt. Ltd. to establish a core imaging facility. Under this partnership Carl Zeiss India will provide Ashoka University with microscopy technology.

• In July 2023, at the Microscopy and Microanalysis (M&M) 2023 Conference, ZEISS Microscopy presents an array of interactive display features, highlighting new Type launches and introducing emerging researchers.

• In April 2023, Nikon unveiled the ECLIPSE Ui, Japan's inaugural digital imaging microscope designed for medical applications, with the goal of enhancing the efficiency of pathological observation and facilitating data sharing.

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