The Global In-vitro Fertilization Microscopes Market size is expected to reach $202.2 Million by 2028, rising at a market growth of 11.4% CAGR during the forecast period.
Many cell kinds, clinical specimens, and nanomaterials may all be inspected under a microscope. For instance, in IVF therapy, microscopes are used to evaluate ova selection and pre-treatment of ova utilizing IVF procedures and manipulation. In addition, for several operations, including semen analysis, oocyte preparation, in-vitro fertilization, and the overall study of the embryo, in-vitro fertilization microscopes are employed.
The market for in-vitro fertilization microscopes is anticipated to increase as a result of the rising success rate of in-vitro fertilization treatments and the accessibility of financial help. One of the methods accessible to those who are having trouble becoming pregnant is in vitro fertilization (IVF). IVF involves taking an egg from the woman's ovaries and fertilizing it with sperm in a lab. The fertilized egg is then placed back into the woman's womb, where it may continue to develop and thrive.
Moreover, IVF is often used to treat conditions including fallopian tube damage, ovulation difficulties, endometriosis, uterine fibroids, prior tubal sterilization or removal, decreased sperm production or function, and genetic diseases in patients. In addition, smoking, binge drinking, obesity, stress, and calorie restriction are other variables that affect fertility (hence raising the necessity for IVF). These reasons increase the need for IVF treatments, increasing market trends for in-vitro fertilization microscopes.
Manufacturers supply a comprehensive sperm analysis system with upright microscopes, digital microscope cameras, and software for examining pictures. Also, because maintaining a steady temperature for the sample might enhance sperm analysis, producers combine such tools with an upright microscope.
The market research report covers the analysis of key stake holders of the market. Key companies profiled in the report include Hamilton Thorne, Inc. (Hamilton Thorne, Ltd.), Olympus Corporation, Leica Microsystems GmbH (Danaher Corporation), Carl Zeiss AG, Nikon Corporation, Linkam Scientific Instruments, Meiji Techno Co., Ltd., Euromex Microscopen B.V. (Euromex Optics Group B.V.), Labomed Europe B.V., and Narishige Group.
Many cell kinds, clinical specimens, and nanomaterials may all be inspected under a microscope. For instance, in IVF therapy, microscopes are used to evaluate ova selection and pre-treatment of ova utilizing IVF procedures and manipulation. In addition, for several operations, including semen analysis, oocyte preparation, in-vitro fertilization, and the overall study of the embryo, in-vitro fertilization microscopes are employed.
The market for in-vitro fertilization microscopes is anticipated to increase as a result of the rising success rate of in-vitro fertilization treatments and the accessibility of financial help. One of the methods accessible to those who are having trouble becoming pregnant is in vitro fertilization (IVF). IVF involves taking an egg from the woman's ovaries and fertilizing it with sperm in a lab. The fertilized egg is then placed back into the woman's womb, where it may continue to develop and thrive.
Moreover, IVF is often used to treat conditions including fallopian tube damage, ovulation difficulties, endometriosis, uterine fibroids, prior tubal sterilization or removal, decreased sperm production or function, and genetic diseases in patients. In addition, smoking, binge drinking, obesity, stress, and calorie restriction are other variables that affect fertility (hence raising the necessity for IVF). These reasons increase the need for IVF treatments, increasing market trends for in-vitro fertilization microscopes.
Manufacturers supply a comprehensive sperm analysis system with upright microscopes, digital microscope cameras, and software for examining pictures. Also, because maintaining a steady temperature for the sample might enhance sperm analysis, producers combine such tools with an upright microscope.
COVID-19 Impact Analysis
The healthcare sector's sales of microscopes fell off a cliff due to the pandemic, which was the worst for the microscopes business. Consequently, there is less need in the healthcare industry for in-vitro fertilization microscopes. Many of these issues hindered the market expansion for in-vitro fertilization microscopes during the epidemic. However, the COVID-19 limitations were loosened, and IVF clinics could operate after taking precautions, including hiring enough personnel, cleaning and validating equipment, and completing risk assessments involving virus contamination.Market Growth Factors
Growing public awareness of in-vitro fertilization
Growing public awareness of in-vitro fertilization is a key element fuelling the market's expansion for in-vitro fertilization microscopes. Nowadays, a large number of parents struggle with infertility, contributing to an increase in infertility rates across most of the nations all over the world. In addition, the incidence of infertility cases has grown as a result of clinical reasons, racial and ethnic variables, as well as problems with the longer median age for family planning and people's sedentary lifestyles. As a result, couples are choosing more sophisticated treatment choices, offering enormous commercial prospects.Increased medical tourism across nations
The cost of high-quality therapy is cheaper in developing nations like Thailand and Malaysia than it is in industrialized countries. Despite the affordable price of treatments in underdeveloped countries, the quality of the process is not affected since there are resources available for comparatively less money. This causes an inflow of individuals to use the healthcare systems in these nations. Several nations prohibit gay and lesbian couples and lone moms from receiving reproductive therapy. Consequently, many individuals go to other countries where the legal system supports parenthood.
Market Restraining Factors
Low effectiveness of infertility therapy in older individuals
It has been shown that older women have lower assisted reproductive methods (ART) results than younger women, both in terms of ovarian stimulation response and pregnancy rates. Ovarian aging, characterized by a decline in ovarian quantity and quality, coexists with chronologic aging. Several studies have shown that older women respond less favourably to ovarian hyperstimulation due to ovarian depletion and declining egg quality. One of the main obstacles preventing the market's progress is the falling success rates of IVF treatment methods in individuals with increasing age.Type Outlook
Based on type, the in-vitro fertilization microscopes market is segmented into upright microscopes, inverted microscopes, stereo microscopes, and embryo microscope. The embryo microscope segment held the highest revenue share in the in-vitro fertilization microscopes market in 2021. A new piece of equipment created especially for IVF labs is the embryo microscope, which is now used there. It is equipped with a camera and computer system to take pictures of developing embryos during in vitro fertilization cycles in an incubator.End - User Outlook
On the basis of end-user, the in-vitro fertilization microscopes market is fragmented into clinical and academic research. In 2021, the academic research segment covered a considerable revenue share in the in-vitro fertilization microscopes market. The market in this sector is anticipated to be driven primarily by three trends: growing healthcare costs, rising availability of in vitro fertilization (IVF) treatments, and rising in vitro fertilization (IVF) popularity. Also, market participants are investing more money in R&D, fostering the segment's expansion.Regional Outlook
Region-wise, the in-vitro fertilization microscopes market, is analysed across North America, Europe, Asia Pacific and LAMEA. In 2021, the Europe region led the in-vitro fertilization microscopes market by generating the highest revenue share. This results from rising fertility tourism, judicial changes, and product innovation. The area has seen a substantial uptake of time-lapse technology using algorithms created by clinics. Saving space and money on the operation is made possible because of advancements in microscopy technology that allow all imaging needs to be met in a single embryo chamber.The market research report covers the analysis of key stake holders of the market. Key companies profiled in the report include Hamilton Thorne, Inc. (Hamilton Thorne, Ltd.), Olympus Corporation, Leica Microsystems GmbH (Danaher Corporation), Carl Zeiss AG, Nikon Corporation, Linkam Scientific Instruments, Meiji Techno Co., Ltd., Euromex Microscopen B.V. (Euromex Optics Group B.V.), Labomed Europe B.V., and Narishige Group.
Scope of the Study
By End-user
- Clinical
- Academic Research
By Type
- Embryo Microscope
- Upright Microscopes
- Stereo Microscopes
- Inverted Microscopes
By Geography
- North America
- US
- Canada
- Mexico
- Rest of North America
- Europe
- Germany
- UK
- France
- Russia
- Spain
- Italy
- Rest of Europe
- Asia Pacific
- China
- Japan
- India
- South Korea
- Singapore
- Malaysia
- Rest of Asia Pacific
- LAMEA
- Brazil
- Argentina
- UAE
- Saudi Arabia
- South Africa
- Nigeria
- Rest of LAMEA
Key Market Players
List of Companies Profiled in the Report:
- Hamilton Thorne, Inc. (Hamilton Thorne, Ltd.)
- Olympus Corporation
- Leica Microsystems GmbH (Danaher Corporation)
- Carl Zeiss AG
- Nikon Corporation
- Linkam Scientific Instruments
- Meiji Techno Co., Ltd.
- Euromex Microscopen B.V. (Euromex Optics Group B.V.)
- Labomed Europe B.V.
- Narishige Group
Unique Offerings
- Exhaustive coverage
- The highest number of Market tables and figures
- Subscription-based model available
- Guaranteed best price
- Assured post sales research support with 10% customization free
Table of Contents
Chapter 1. Market Scope & Methodology1.1 Market Definition
1.2 Objectives
1.3 Market Scope
1.4 Segmentation
1.4.1 Global In-vitro Fertilization Microscopes Market, by End User
1.4.2 Global In-vitro Fertilization Microscopes Market, by Type
1.4.3 Global In-vitro Fertilization Microscopes Market, by Geography
1.5 Methodology for the research
Chapter 2. Market Overview
2.1 Introduction
2.1.1 Overview
2.1.1.1 Market Composition & Scenario
2.2 Key Factors Impacting the Market
2.2.1 Market Drivers
2.2.2 Market Restraints
Chapter 3. Global In-vitro Fertilization Microscopes Market by End User
3.1 Global Clinical Market by Region
3.2 Global Academic Research Market by Region
Chapter 4. Global In-vitro Fertilization Microscopes Market by Type
4.1 Global Embryo Microscope Market by Region
4.2 Global Upright Microscopes Market by Region
4.3 Global Stereo Microscopes Market by Region
4.4 Global Inverted Microscopes Market by Region
Chapter 5. Global In-vitro Fertilization Microscopes Market by Region
5.1 North America In-vitro Fertilization Microscopes Market
5.1.1 North America In-vitro Fertilization Microscopes Market by End User
5.1.1.1 North America Clinical Market by Country
5.1.1.2 North America Academic Research Market by Country
5.1.2 North America In-vitro Fertilization Microscopes Market by Type
5.1.2.1 North America Embryo Microscope Market by Country
5.1.2.2 North America Upright Microscopes Market by Country
5.1.2.3 North America Stereo Microscopes Market by Country
5.1.2.4 North America Inverted Microscopes Market by Country
5.1.3 North America In-vitro Fertilization Microscopes Market by Country
5.1.3.1 US In-vitro Fertilization Microscopes Market
5.1.3.1.1 US In-vitro Fertilization Microscopes Market by End User
5.1.3.1.2 US In-vitro Fertilization Microscopes Market by Type
5.1.3.2 Canada In-vitro Fertilization Microscopes Market
5.1.3.2.1 Canada In-vitro Fertilization Microscopes Market by End User
5.1.3.2.2 Canada In-vitro Fertilization Microscopes Market by Type
5.1.3.3 Mexico In-vitro Fertilization Microscopes Market
5.1.3.3.1 Mexico In-vitro Fertilization Microscopes Market by End User
5.1.3.3.2 Mexico In-vitro Fertilization Microscopes Market by Type
5.1.3.4 Rest of North America In-vitro Fertilization Microscopes Market
5.1.3.4.1 Rest of North America In-vitro Fertilization Microscopes Market by End User
5.1.3.4.2 Rest of North America In-vitro Fertilization Microscopes Market by Type
5.2 Europe In-vitro Fertilization Microscopes Market
5.2.1 Europe In-vitro Fertilization Microscopes Market by End User
5.2.1.1 Europe Clinical Market by Country
5.2.1.2 Europe Academic Research Market by Country
5.2.2 Europe In-vitro Fertilization Microscopes Market by Type
5.2.2.1 Europe Embryo Microscope Market by Country
5.2.2.2 Europe Upright Microscopes Market by Country
5.2.2.3 Europe Stereo Microscopes Market by Country
5.2.2.4 Europe Inverted Microscopes Market by Country
5.2.3 Europe In-vitro Fertilization Microscopes Market by Country
5.2.3.1 Germany In-vitro Fertilization Microscopes Market
5.2.3.1.1 Germany In-vitro Fertilization Microscopes Market by End User
5.2.3.1.2 Germany In-vitro Fertilization Microscopes Market by Type
5.2.3.2 UK In-vitro Fertilization Microscopes Market
5.2.3.2.1 UK In-vitro Fertilization Microscopes Market by End User
5.2.3.2.2 UK In-vitro Fertilization Microscopes Market by Type
5.2.3.3 France In-vitro Fertilization Microscopes Market
5.2.3.3.1 France In-vitro Fertilization Microscopes Market by End User
5.2.3.3.2 France In-vitro Fertilization Microscopes Market by Type
5.2.3.4 Russia In-vitro Fertilization Microscopes Market
5.2.3.4.1 Russia In-vitro Fertilization Microscopes Market by End User
5.2.3.4.2 Russia In-vitro Fertilization Microscopes Market by Type
5.2.3.5 Spain In-vitro Fertilization Microscopes Market
5.2.3.5.1 Spain In-vitro Fertilization Microscopes Market by End User
5.2.3.5.2 Spain In-vitro Fertilization Microscopes Market by Type
5.2.3.6 Italy In-vitro Fertilization Microscopes Market
5.2.3.6.1 Italy In-vitro Fertilization Microscopes Market by End User
5.2.3.6.2 Italy In-vitro Fertilization Microscopes Market by Type
5.2.3.7 Rest of Europe In-vitro Fertilization Microscopes Market
5.2.3.7.1 Rest of Europe In-vitro Fertilization Microscopes Market by End User
5.2.3.7.2 Rest of Europe In-vitro Fertilization Microscopes Market by Type
5.3 Asia Pacific In-vitro Fertilization Microscopes Market
5.3.1 Asia Pacific In-vitro Fertilization Microscopes Market by End User
5.3.1.1 Asia Pacific Clinical Market by Country
5.3.1.2 Asia Pacific Academic Research Market by Country
5.3.2 Asia Pacific In-vitro Fertilization Microscopes Market by Type
5.3.2.1 Asia Pacific Embryo Microscope Market by Country
5.3.2.2 Asia Pacific Upright Microscopes Market by Country
5.3.2.3 Asia Pacific Stereo Microscopes Market by Country
5.3.2.4 Asia Pacific Inverted Microscopes Market by Country
5.3.3 Asia Pacific In-vitro Fertilization Microscopes Market by Country
5.3.3.1 China In-vitro Fertilization Microscopes Market
5.3.3.1.1 China In-vitro Fertilization Microscopes Market by End User
5.3.3.1.2 China In-vitro Fertilization Microscopes Market by Type
5.3.3.2 Japan In-vitro Fertilization Microscopes Market
5.3.3.2.1 Japan In-vitro Fertilization Microscopes Market by End User
5.3.3.2.2 Japan In-vitro Fertilization Microscopes Market by Type
5.3.3.3 India In-vitro Fertilization Microscopes Market
5.3.3.3.1 India In-vitro Fertilization Microscopes Market by End User
5.3.3.3.2 India In-vitro Fertilization Microscopes Market by Type
5.3.3.4 South Korea In-vitro Fertilization Microscopes Market
5.3.3.4.1 South Korea In-vitro Fertilization Microscopes Market by End User
5.3.3.4.2 South Korea In-vitro Fertilization Microscopes Market by Type
5.3.3.5 Singapore In-vitro Fertilization Microscopes Market
5.3.3.5.1 Singapore In-vitro Fertilization Microscopes Market by End User
5.3.3.5.2 Singapore In-vitro Fertilization Microscopes Market by Type
5.3.3.6 Malaysia In-vitro Fertilization Microscopes Market
5.3.3.6.1 Malaysia In-vitro Fertilization Microscopes Market by End User
5.3.3.6.2 Malaysia In-vitro Fertilization Microscopes Market by Type
5.3.3.7 Rest of Asia Pacific In-vitro Fertilization Microscopes Market
5.3.3.7.1 Rest of Asia Pacific In-vitro Fertilization Microscopes Market by End User
5.3.3.7.2 Rest of Asia Pacific In-vitro Fertilization Microscopes Market by Type
5.4 LAMEA In-vitro Fertilization Microscopes Market
5.4.1 LAMEA In-vitro Fertilization Microscopes Market by End User
5.4.1.1 LAMEA Clinical Market by Country
5.4.1.2 LAMEA Academic Research Market by Country
5.4.2 LAMEA In-vitro Fertilization Microscopes Market by Type
5.4.2.1 LAMEA Embryo Microscope Market by Country
5.4.2.2 LAMEA Upright Microscopes Market by Country
5.4.2.3 LAMEA Stereo Microscopes Market by Country
5.4.2.4 LAMEA Inverted Microscopes Market by Country
5.4.3 LAMEA In-vitro Fertilization Microscopes Market by Country
5.4.3.1 Brazil In-vitro Fertilization Microscopes Market
5.4.3.1.1 Brazil In-vitro Fertilization Microscopes Market by End User
5.4.3.1.2 Brazil In-vitro Fertilization Microscopes Market by Type
5.4.3.2 Argentina In-vitro Fertilization Microscopes Market
5.4.3.2.1 Argentina In-vitro Fertilization Microscopes Market by End User
5.4.3.2.2 Argentina In-vitro Fertilization Microscopes Market by Type
5.4.3.3 UAE In-vitro Fertilization Microscopes Market
5.4.3.3.1 UAE In-vitro Fertilization Microscopes Market by End User
5.4.3.3.2 UAE In-vitro Fertilization Microscopes Market by Type
5.4.3.4 Saudi Arabia In-vitro Fertilization Microscopes Market
5.4.3.4.1 Saudi Arabia In-vitro Fertilization Microscopes Market by End User
5.4.3.4.2 Saudi Arabia In-vitro Fertilization Microscopes Market by Type
5.4.3.5 South Africa In-vitro Fertilization Microscopes Market
5.4.3.5.1 South Africa In-vitro Fertilization Microscopes Market by End User
5.4.3.5.2 South Africa In-vitro Fertilization Microscopes Market by Type
5.4.3.6 Nigeria In-vitro Fertilization Microscopes Market
5.4.3.6.1 Nigeria In-vitro Fertilization Microscopes Market by End User
5.4.3.6.2 Nigeria In-vitro Fertilization Microscopes Market by Type
5.4.3.7 Rest of LAMEA In-vitro Fertilization Microscopes Market
5.4.3.7.1 Rest of LAMEA In-vitro Fertilization Microscopes Market by End User
5.4.3.7.2 Rest of LAMEA In-vitro Fertilization Microscopes Market by Type
Chapter 6. Company Profiles
6.1 Hamilton Thorne, Inc. (Hamilton Thorne, Ltd.)
6.1.1 Company Overview
6.1.2 Financial Analysis
6.1.3 Segmental Analysis
6.1.4 Research & Development Expenses
6.1.5 Recent strategies and developments:
6.1.5.1 Acquisition and Mergers:
6.2 Olympus Corporation
6.2.1 Company Overview
6.2.2 Financial Analysis
6.2.3 Segmental and Regional Analysis
6.2.4 Recent strategies and developments:
6.2.4.1 Partnerships, Collaborations, and Agreements:
6.3 Leica Microsystems GmbH (Danaher Corporation)
6.3.1 Company Overview
6.3.2 Financial Analysis
6.3.3 Segmental and Regional Analysis
6.3.4 Research & Development Expense
6.4 Carl Zeiss AG
6.4.1 Company Overview
6.4.2 Financial Analysis
6.4.3 Segmental and Regional Analysis
6.4.4 Research & Development Expenses
6.5 Nikon Corporation
6.5.1 Company Overview
6.5.2 Financial Analysis
6.5.3 Segmental and Regional Analysis
6.5.4 Research & Development Expense
6.6 Linkam Scientific Instruments
6.6.1 Company Overview
6.7 Meiji Techno Co., Ltd.
6.7.1 Company Overview
6.8 Euromex Microscopen B.V. (Euromex Optics Group B.V.)
6.8.1 Company Overview
6.9 Labomed Europe B.V.
6.9.1 Company Overview
6.10. Narishige Group
6.10.1 Company Overview
Companies Mentioned
- Hamilton Thorne, Inc. (Hamilton Thorne, Ltd.)
- Olympus Corporation
- Leica Microsystems GmbH (Danaher Corporation)
- Carl Zeiss AG
- Nikon Corporation
- Linkam Scientific Instruments
- Meiji Techno Co., Ltd.
- Euromex Microscopen B.V. (Euromex Optics Group B.V.)
- Labomed Europe B.V.
- Narishige Group
Methodology
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