[시장보고서]심장 조직 공학 시장 - 시장 규모, 점유율, 동향 : 재료별, 제품별, 용도별, 최종 사용자별, 지역별

심장 조직 공학 시장 - 시장 규모, 점유율, 동향 : 재료별, 제품별, 용도별, 최종 사용자별, 지역별 - 예측(-2029년)

Cardiac Tissue Engineering Market Size, Share & Trends by Material, Product, Applications, End-User - Global Forecast to 2029

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리서치사 : MarketsandMarkets

발행일 : 2024년 09월

페이지 정보 : 영문 337 Pages

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한글목차

샘플 요청 목록에 추가

세계 심장 조직 공학 시장 규모는 2024년 6억 2,120만 달러에서 2029년 13억 3,360만 달러에 달할 것으로 예상되며, 2024년부터 2029년까지 연평균 16.5%의 연평균 복합 성장률(CAGR)을 나타낼 것으로 예상됩니다.

시장 성장의 원동력은 3D 바이오프린팅의 기술 발전입니다. 전 세계적으로 심혈관 질환이 급증하고 있는 것도 시장 성장의 원동력이 되고 있습니다. 그러나 심장 조직 공학 공정을 통한 심혈관 질환 치료와 관련된 높은 비용이 시장 성장에 영향을 미치고 있습니다. 또한, 심장 조직 공학 분야의 엄격한 규제 정책은 시장 성장을 억제하는 주요 요인으로 작용하고 있습니다.

조사 범위
조사 대상년도	2021-2029년
기준년도	2023년
예측 기간	2024-2029년
검토 단위	금액(100만 달러)
부문별	재료별, 제품별, 용도별, 최종사용자별, 지역별
대상 지역	북미, 유럽, 아시아태평양, 라틴아메리카, 중동/아프리카, GCC 국가

재료에 따라 줄기세포와 스캐폴드 부문으로 나뉩니다. 스캐폴드 부문은 다시 합성 스캐폴드와 생물학적 스캐폴드로 나뉩니다. 생물학적 스캐폴드는 다시 콜라겐 기반 스캐폴드와 하이드로겔 기반 스캐폴드로 구분되며, 2023년에는 이 두 가지 생물학적 스캐폴드 중 하이드로겔 기반 스캐폴드가 심장 조직 공학 시장에서 큰 점유율을 차지할 것으로 예상됩니다. 이는 천연 조직의 특성을 충실하게 모방한 다재다능한 특성 때문입니다. 하이드로겔은 세포외 매트릭스와 같이 고도로 수화된 네트워크로 구성되어 조직 재생에 필수적인 세포의 접착, 증식 및 분화를 촉진합니다. 하이드로겔의 기계적 특성은 특정 조직의 특성에 맞게 광범위하게 조절할 수 있어 생체 내 적합성과 통합성을 높일 수 있습니다. 이러한 조절 가능성은 최적의 다공성, 생분해성 및 투과성을 가진 스캐폴드를 설계하여 세포의 생존과 조직 발달에 필수적인 영양과 산소의 확산을 촉진할 수 있습니다.

용도별로 심장 조직 공학 시장은 심근경색, 심장 판막 수리/교체, 선천성 심장병 치료, 기타로 구분되며, 2023년에는 선천성 심장병 치료가 가장 큰 비중을 차지할 것으로 예상됩니다. 이는 전 세계적으로 선천성 심장병 관련 유병률이 증가하면서 심각한 의료 수요가 증가하고 있기 때문입니다. 예를 들어, 호주에서는 약 65,000명이 선천성 심장질환을 앓고 있으며, 매년 약 5,900건의 선천성 심장질환이 진단되고 있습니다. 이 질환은 매년 79명의 영아 사망의 원인이 되고 있으며, 이는 공중보건에 미치는 심각한 영향을 보여줍니다. 또한, 미국에서는 매년 약 4만 명의 영아들이 선천성 심장병으로 태어나고 있으며, 이 중 상당수가 고도의 치료가 필요한 것으로 밝혀졌습니다. 심장 조직 공학은 결함이 있는 심장 조직을 복구하거나 대체할 수 있는 맞춤형 접근법을 제공함으로써 선천성 심장 질환에 대한 유망한 해결책을 제시합니다. 이러한 혁신은 선천성 심장병의 독특한 해부학적, 생리적 문제를 해결하는 데 매우 중요하며, 많은 경우 영아기부터 성인기까지 개별화되고 내구성 있는 개입이 필요합니다. 전 세계적으로 선천성 심장질환의 발생률이 증가함에 따라 환자의 예후와 삶의 질을 개선할 수 있는 혁신적인 치료법에 대한 수요가 증가하고 있으며, 이는 심장조직공학 시장에서 선천성 심장질환 분야의 존재감을 높여주고 있습니다.

이 보고서는 세계 심장 조직 공학 시장을 조사했으며, 재료별/제품별/용도별/최종 사용자별/지역별 동향, 시장 진출기업 프로파일 등을 정리한 보고서입니다.

서론
시장 역학
업계 동향
기술 분석
파이프라인 분석
밸류체인 분석
Porter의 Five Forces 분석
주요 이해관계자와 구입 기준
규제 상황
특허 분석
무역 분석
가격 분석
2024-2025년 주요 컨퍼런스 및 이벤트
심장 조직공학 시장의 미충족 요구
심장 조직공학 시장의 최종사용자 기대
심장 조직공학 시장의 AI 통합
생태계 분석
사례 연구
공급망 분석
심장 조직공학 시장 : 투자 및 자금조달 시나리오
인접 시장 분석

제6장 심장 조직공학 시장(재료별)

서론
줄기세포
스캐폴드

제7장 심장 조직공학 시장(제품별)

서론
혈관 이식
심장 패치
심장 판막

제8장 심장 조직공학 시장(용도별)

서론
심근경색
심장판막 수복/치환
선천성 심질환
기타

제9장 심장 조직공학 시장(최종사용자별)

서론
병원 및 클리닉
학술연구기관
기타

제10장 심장 조직공학 시장(지역별)

서론
북미
유럽
아시아태평양
라틴아메리카
중동 및 아프리카

제11장 경쟁 구도

개요
주요 시장 진출기업의 전략/비책
매출 분배 분석
시장 점유율 분석
헬스케어 서비스 벤더 평가와 재무 지표
기업 평가 매트릭스, 주요 시장 진출기업(2023년)
스타트업/중소기업용 기업 평가 매트릭스(2023년)
경쟁 시나리오
브랜드/제품 비교 분석

제12장 기업 개요

주요 시장 진출기업
- TERUMO CORPORATION
- ARTIVION, INC.
- BAXTER INTERNATIONAL, INC.
- TEIJIN LIMITED
- MEDTRONIC PLC
- BOSTON SCIENTIFIC CORPORATION
- ABBOTT LABORATORIES
- MERCK KGAA
- FUJIFILM HOLDINGS CORPORATION
- BICO-THE BIO CONVERGENCE COMPANY
- ELUTIA
- W. L. GORE AND ASSOCIATES, INC.
- MERIL LIFESCIENCES PVT. LTD.
- VASCUDYNE, INC.
- REPROCELL, INC.
기타 기업
- AXOL BIOSCIENCE LTD.
- BPS BIOSCIENCE, INC.
- TAKARA BIO, INC.
- XELTIS
- VISCOFAN DE GMBH
- CELL APPLICATION, INC
- PROMOCELL GMBH

제13장 부록

LSH

영문 목차

영문목차

The global cardiac tissue engineering market is projected to reach USD 1,333.6 Million by 2029 from USD 621.2 Million in 2024, at a CAGR of 16.5% from 2024 to 2029. The growth of the market is driven Technological advancement in 3d bioprinting. The market also benefits from the up surge in prevalence of cardiovascular diseases across the globe. However, high cost associated with treating cardiovascular diseases by cardiac tissue engineering process, is impacting the growth of the market. Moreover, the stringent regulatory policies in the field of cardiac tissue engineering are a major factor restraining the market growth.

Scope of the Report
Years Considered for the Study	2021-2029
Base Year	2023
Forecast Period	2024-2029
Units Considered	Value (USD Million)
Segments	By Material, Product, Application, End User
Regions covered	North America, Europe, Asia Pacific, Latin America, the Middle East & Africa, and GCC Countries

"Hydrogel based scaffolds segment to witness the significant growth during the forecast period."

Based on material, the segment is divided into stem cells, and scaffolds. The scaffolds segment is further divided into synthetic scaffolds and biological scaffolds. The biological scaffolds are further segmented into collagen-based scaffolds and hydrogel-based scaffolds. In 2023, among these two biological scaffolds, the hydrogel-based scaffolds accounts for the significant share in cardiac tissue engineering market. This is due to their versatile properties that closely mimic natural tissue characteristics. Hydrogels are composed of highly hydrated networks, like the extracellular matrix, which promotes cell attachment, proliferation, and differentiation critical for tissue regeneration. Their mechanical properties can be tailored across a wide range to match those of specific tissues, enhancing compatibility and integration within the body. This tunability allows for the design of scaffolds with optimal porosity, biodegradability, and permeability, facilitating nutrient and oxygen diffusion essential for cell survival and tissue development. Moreover, hydrogels can be engineered to deliver bioactive molecules and growth factors in a controlled manner, further supporting tissue regeneration processes. Compared to collagen-based scaffolds, which also offer biological compatibility but have more limited mechanical tunability, hydrogels provide a superior platform for creating complex tissue constructs in cardiac tissue engineering and other regenerative medicine applications. These advantages position hydrogel-based scaffolds as the preferred choice, driving their dominance in the biological scaffold segment of the scaffold market.

The segment is separated into scaffolds and stem cells based on the type of material. The material used on scaffolds is subdivided into two categories: biological scaffolds and synthetic scaffolds. Collagen- and hydrogel-based scaffolds are two further categories into which the biological scaffolds are divided. By 2023, the hydrogel-based biological scaffolds will have a larger market share in cardiac tissue engineering than the other two biological scaffolds combined. This is because of its adaptable qualities, which closely resemble those of natural tissue. Similar to the extracellular matrix, hydrogels are made of highly hydrated networks that support cell adhesion, proliferation, and differentiation-all of which are essential for tissue regeneration. Their ability to modify their mechanical characteristics to a large degree in order to match the characteristics of particular tissues improves their compatibility and integration with the body. dominance in the scaffold market's biological scaffold sector. Because of its tunability, scaffolds with the ideal porosity, biodegradability, and permeability may be designed, enabling the flow of nutrients and oxygen-both of which are necessary for tissue formation and cell survival. Hydrogels can also be designed to supply growth factors and bioactive compounds in a regulated way, which will aid in the processes involved in tissue regeneration. For the creation of complex tissue constructs in cardiac tissue engineering and other regenerative medicine applications, hydrogels offer a superior platform than collagen-based scaffolds, which likewise offer biological compatibility but have less mechanical tunability. Because of these benefits, hydrogel-based scaffolds are positioned as the best option and dominate the market for biological scaffolds.

"Congenital heart disease treatment segment accounted for the significant share in the cardiac tissue engineering market during the forecast period."

Based on application, the cardiac tissue engineering market is segmented into myocardial infarction, heart valve repair/replacement, congenital heart disease treatment and others. Among these in 2023, the congenital heart disease treatment accounted for significant share. This is attributed to the rising prevalence and critical medical needs associated with congenital heart defects globally. For instance, in Australia, approximately 65,000 individuals live with congenital heart disease, with around 5,900 cases diagnosed annually as the principal cause. This condition also accounts for 79 infant deaths annually, highlighting its severe impact on public health. Similarly, in the United States, nearly 40,000 infants are born with congenital heart defects each year, underscoring the substantial patient population requiring advanced treatment options. Cardiac tissue engineering offers promising solutions for congenital heart defects by providing tailored approaches to repair or replace defective heart tissues. These innovations are crucial in addressing the specific anatomical and physiological challenges presented by congenital heart diseases, which often require personalized and durable interventions from early infancy throughout adulthood. The increasing incidence of congenital heart defects globally drives demand for innovative therapies that can improve patient outcomes and quality of life, thereby bolstering the congenital heart disease segment's prominence in the cardiac tissue engineering market.

The cardiac tissue engineering market is divided into segments based on application, comprising treatment for congenital heart disease, myocardial infarction, and heart valve repair/replacement. Treatment for congenital cardiac disease accounted for a sizable portion of these in 2023. This is explained by the increased global prevalence of congenital cardiac abnormalities and the urgent medical needs they provide. For example, congenital heart disease affects about 65,000 people in Australia, with 5,900 new instances being diagnosed as the primary cause each year. Its devastating influence on public health is further evidenced by the 79 newborn fatalities that are attributed to this illness each year. Comparably, over 40,000 babies in the US are born with congenital cardiac abnormalities every year, highlighting the sizeable patient population in need of cutting-edge care. Cardiac tissue engineering provides customized methods for replacing or repairing damaged cardiac tissues, which presents promising remedies for congenital heart abnormalities. These advancements are essential for tackling the unique anatomical and physiological problems associated with congenital cardiac disorders, which frequently call for customized and long-lasting therapies from early childhood into adulthood. The need for novel treatments that can enhance patient outcomes and quality of life is being driven by the rising incidence of congenital heart problems worldwide. This is expected to increase the importance of the congenital heart disease segment in the cardiac tissue engineering market.

"APAC is estimated to register the highest CAGR during the forecast period."

In this report, the cardiac tissue engineering market is segmented into five major regional segments, namely, North America, Europe, Asia Pacific, Latin America and Middle East and Africa. The market in APAC is projected to register the highest growth rate during the forecast period attributed to increase in strategic collaborations and robust research initiatives. In June 2023, the establishment of the Asia-Pacific Cardiovascular Disease Alliance (APAC CVD Alliance), involving patient organizations, allied health professionals, academia, corporate partners, and a global health think-tank, underscored a concerted effort across nine health systems in Asia to enhance heart health and mitigate cardiovascular disease (CVD) impacts. Moreover, the presence of esteemed research institutions such as the Heart Research Institute, dedicated to advancing cardiovascular disease pathophysiology and pioneering tissue engineering solutions, enhances the region's capability to innovate in cardiac health technologies. With such collaborative frameworks and research capabilities, the Asia Pacific region is accelerating in scientific advancements for market growth in cardiac tissue engineering, promising significant opportunities for stakeholders in the sector.

North America, Europe, Asia Pacific, Latin America, and the Middle East and Africa are the five main geographical regions into which the cardiac tissue engineering market is divided in the report. Due to a rise in strategic partnerships and active research projects, the APAC market is anticipated to grow at the fastest rate over the forecast period. The Asia-Pacific Cardiovascular Disease Alliance (APAC CVD Alliance) was founded in June 2023 and represents a coordinated effort across nine Asian health systems to improve heart health and lessen the effects of cardiovascular disease (CVD). Participants in the alliance include patient organizations, allied health professionals, academia, corporate partners, and a global health think-tank. Furthermore, the region's capacity to innovate in heart health technologies is further enhanced by the existence of prestigious research organizations like the Heart Research Institute, which is committed to studying the pathophysiology of cardiovascular illness and developing innovative tissue engineering treatments. The Asia Pacific area is experiencing a notable surge in scientific developments for cardiac tissue engineering market growth, thanks to the presence of collaborative frameworks and research capacities. This presents substantial prospects for industry stakeholders.

Breakdown of supply-side primary interviews, by company type, designation, and region:

By Company Type: Tier 1 (20%), Tier 2 (45%), and Tier 3 (35%)
By Designation: C-level (30%), Director-level (20%), and Others (50%)
By Region: North America (35%), Europe (24%), Asia Pacific (25%), RoW (16%)

List of Companies Profiled in the Report

Terumo corporation (Japan)
Artivion, Inc. (US)
Baxter international, Inc. (US)
Teijin Limited (Japan)
Medtronic Plc. (Ireland)
Boston Scientific Corporation (US)
Abbott Laboratories (US)
Merck KGaA (Germany)
Elutia. (US)
W. L. Gore & Associates, Inc. (US)
Meril Lifesciences Pvt.Ltd (India)
Fujifilm Holdings Corporation (Japan)
Vascudyne, Inc. (US)
BICO - THE BIO CONVERGENCE COMPANY (Sweden)
ReproCELL, Inc. (US)
PromoCell GmBH (Germany)
Axol Bioscience Ltd. (UK)
BPS Bioscience, Inc. (US)
Cell Application, Inc. (US)
Viscofan DE GmBH (Germany)

Research Coverage

This report studies the cardiac tissue engineering market based on product, procedure, technology, application, end user and region. The report also analyses factors (such as drivers, restraints, opportunities and challenges) affecting market growth. It evaluates the opportunities and challenges in the market for stakeholders and provides details of the competitive landscape for market leaders. The report also studies micro markets with respect to their growth trends, prospects, and contributions to the total cardiac tissue engineering market. The report forecasts the revenue of the market segments with respect to five major regions.

Reasons to Buy the Report

This report also includes.

Analysis of key drivers (rising prevalence of cardiovascular diseases, increase in support from major market players and government bodies, Increased demand for regenerative medicine, the advancement of 3D bioprinting),restraints (High cost of treatment, Complex regulatory process), challenges (Safety concerns and complexity of biomaterials, Limited awareness and scarcity of skilled professionals), opportunities (Technological advancement in cardiac tissue engineering, The ability of biomaterials to enhance the functionality and integration of cardiac tissues offers significant opportunities, Increase in research of stems cells to treat cardiovascular diseases) contributing the growth of the cardiac tissue engineering market.
Product Development/Innovation: Detailed insights on upcoming trends, research & development activities, and new software launches in the cardiac tissue engineering market.
Market Development: Comprehensive information on the lucrative emerging markets, product, procedure, technology, application, end-user and region.
Market Diversification: Exhaustive information about the growing geographies, recent developments, investments in the cardiac tissue engineering market.
Competitive Assessment: In-depth assessment of market shares, growth strategies, product offerings, company evaluation quadrant, and capabilities of leading players in the global cardiac tissue engineering market.

1 INTRODUCTION

1.1 STUDY OBJECTIVES
1.2 MARKET DEFINITION
- 1.2.1 MATERIAL DEFINITION
- 1.2.2 PRODUCT DEFINITION
- 1.2.3 APPLICATION DEFINITION
- 1.2.4 END USER DEFINITION
- 1.2.5 INCLUSIONS & EXCLUSIONS
1.3 MARKET SCOPE
- 1.3.1 MARKETS COVERED
- 1.3.2 YEARS CONSIDERED
- 1.3.3 CURRENCY CONSIDERED
1.4 STAKEHOLDERS
1.5 LIMITATIONS

2 RESEARCH METHODOLOGY

2.1 RESEARCH APPROACH
2.2 RESEARCH METHODOLOGY DESIGN
- 2.2.1 SECONDARY RESEARCH
- 2.2.2 KEY DATA FROM SECONDARY SOURCES
- 2.2.3 PRIMARY DATA
- 2.2.4 KEY DATA FROM PRIMARY SOURCES
- 2.2.5 KEY INDUSTRY INSIGHTS
2.3 MARKET SIZE ESTIMATION
2.4 MARKET BREAKDOWN & DATA TRIANGULATION
2.5 MARKET SHARE ESTIMATION
2.6 STUDY ASSUMPTIONS
2.7 RISK ASSESSMENT
2.8 RESEARCH LIMITATIONS
- 2.8.1 METHODOLOGY-RELATED LIMITATIONS

3 EXECUTIVE SUMMARY

4 PREMIUM INSIGHTS

4.1 CARDIAC TISSUE ENGINEERING MARKET OVERVIEW
4.2 EUROPE: CARDIAC TISSUE ENGINEERING MARKET, BY APPLICATION
4.3 REGIONAL SNAPSHOT OF CARDIAC TISSUE ENGINEERING MARKET (2023)
4.4 GEOGRAPHIC MIX: CARDIAC TISSUE ENGINEERING MARKET, 2024-2029 (USD MILLION)
4.5 CARDIAC TISSUE ENGINEERING MARKET: DEVELOPING VS. DEVELOPED MARKETS, 2024 VS. 2029 (USD MILLION)

5 MARKET OVERVIEW

5.1 INTRODUCTION
5.2 MARKET DYNAMICS
- 5.2.1 DRIVERS
  - 5.2.1.1 Rising prevalence of cardiovascular diseases
  - 5.2.1.2 Increase in support from major market players and government bodies
  - 5.2.1.3 Increased demand for regenerative medicine
  - 5.2.1.4 Advancements in 3D bioprinting
- 5.2.2 RESTRAINTS
  - 5.2.2.1 High cost of treatment
  - 5.2.2.2 Complex regulatory process
- 5.2.3 OPPORTUNITIES
  - 5.2.3.1 Technological advancements in cardiac tissue engineering
  - 5.2.3.2 Enhanced functionality and integration of cardiac tissues using biomaterials
  - 5.2.3.3 Increase in stem cell research to treat cardiovascular diseases
- 5.2.4 CHALLENGES
  - 5.2.4.1 Safety concerns and complexity of biomaterials
  - 5.2.4.2 Limited awareness and availability of skilled professionals
5.3 INDUSTRY TRENDS
- 5.3.1 DEVELOPMENT OF BIOCOMPATIBLE AND BIODEGRADABLE MATERIALS
- 5.3.2 INTEGRATION OF MICROFLUIDICS AND ELECTRICAL STIMULATION FOR IMPROVED CELL FUNCTION AND TISSUE MATURATION
- 5.3.3 EXPANSION OF CARDIAC TISSUE ENGINEERING APPLICATIONS
5.4 TECHNOLOGY ANALYSIS
- 5.4.1 KEY TECHNOLOGIES
- 5.4.2 STEM CELL TECHNOLOGY
- 5.4.3 3D BIOPRINTING
- 5.4.4 BIOREACTORS
- 5.4.5 COMPLEMENTARY TECHNOLOGY
- 5.4.6 GENE EDITING
- 5.4.7 ELECTROSPINNING
- 5.4.8 MICROFLUIDICS
- 5.4.9 ADJACENT TECHNOLOGIES
  - 5.4.9.1 Biosensors
- 5.4.10 ARTIFICIAL INTELLIGENCE AND MACHINE LEARNING
- 5.4.11 NANOTECHNOLOGY
5.5 PIPELINE ANALYSIS
5.6 VALUE CHAIN ANALYSIS
5.7 PORTER'S FIVE FORCES ANALYSIS
- 5.7.1 THREAT OF NEW ENTRANTS
- 5.7.2 THREAT OF SUBSTITUTES
- 5.7.3 BARGAINING POWER OF SUPPLIERS
- 5.7.4 BARGAINING POWER OF BUYERS
- 5.7.5 INTENSITY OF COMPETITIVE RIVALRY
5.8 KEY STAKEHOLDERS AND BUYING CRITERIA
- 5.8.1 KEY STAKEHOLDERS IN BUYING PROCESS
- 5.8.2 BUYING CRITERIA
5.9 REGULATORY LANDSCAPE
- 5.9.1 REGULATORY ANALYSIS
- 5.9.2 REGULATORY BODIES, GOVERNMENT AGENCIES, AND OTHER ORGANIZATIONS
5.10 PATENT ANALYSIS
- 5.10.1 PATENT PUBLICATION TRENDS FOR CARDIAC TISSUE ENGINEERING MARKET
- 5.10.2 INSIGHTS: JURISDICTION AND TOP APPLICANT ANALYSIS
5.11 TRADE ANALYSIS
- 5.11.1 TRADE ANALYSIS FOR DIAGNOSTIC AND LABORATORY REAGENTS
- 5.11.2 IMPORT DATA FOR DIAGNOSTIC AND LABORATORY REAGENTS, BY COUNTRY, 2018-2021 (USD MILLION)
- 5.11.3 EXPORT DATA FOR DIAGNOSTIC AND LABORATORY REAGENTS, BY COUNTRY, 2018-2021 (USD MILLION)
5.12 PRICING ANALYSIS
5.13 KEY CONFERENCES AND EVENTS, 2024-2025
5.14 UNMET NEEDS IN CARDIAC TISSUE ENGINEERING MARKET
5.15 END USER EXPECTATIONS IN CARDIAC TISSUE ENGINEERING MARKET
5.16 AI INTEGRATION IN CARDIAC TISSUE ENGINEERING MARKET
5.17 ECOSYSTEM ANALYSIS
5.18 CASE STUDIES
5.19 SUPPLY CHAIN ANALYSIS
5.20 CARDIAC TISSUE ENGINEERING MARKET: INVESTMENT AND FUNDING SCENARIO
5.21 ADJACENT MARKET ANALYSIS
- 5.21.1 TISSUE ENGINEERING MARKET

6 CARDIAC TISSUE ENGINEERING MARKET, BY MATERIAL

6.1 INTRODUCTION
6.2 STEM CELLS
- 6.2.1 INCREASING FUNDING FOR STEM CELL RESEARCH TO DRIVE MARKET
6.3 SCAFFOLDS
- 6.3.1 SYNTHETIC SCAFFOLDS
  - 6.3.1.1 Advancements in fabrication techniques to drive market
- 6.3.2 BIOLOGICAL SCAFFOLDS
- 6.3.3 COLLAGEN-BASED SCAFFOLDS
  - 6.3.3.1 Biocompatibility of material - key driver
  - 6.3.3.2 Hydrogel-based scaffolds
    - 6.3.3.2.1 Low mechanical strength to restrain segment growth

7 CARDIAC TISSUE ENGINEERING MARKET, BY PRODUCT

7.1 INTRODUCTION
7.2 VASCULAR GRAFTS
- 7.2.1 INCREASE IN PREVALENCE OF CORONARY ARTERY DISEASE TO DRIVE MARKET
7.3 CARDIAC PATCHES
- 7.3.1 INCREASE IN CLINICAL TRIALS FOR CARDIAC PATCHES TO BOOST MARKET
7.4 HEART VALVES
- 7.4.1 INCREASE IN PREVALENCE OF VALVE REGURGITATION TO DRIVE MARKET

8 CARDIAC TISSUE ENGINEERING MARKET, BY APPLICATION

8.1 INTRODUCTION
8.2 MYOCARDIAL INFARCTION
- 8.2.1 IMPROVED STRUCTURAL INTEGRATION TO DRIVE MARKET GROWTH
8.3 HEART VALVE REPAIR/REPLACEMENT
- 8.3.1 INCREASE IN INCIDENCE OF AORTIC STENOSIS TO DRIVE MARKET
8.4 CONGENITAL HEART DISEASE
- 8.4.1 SIGNIFICANT INVESTMENT BY KEY MARKET PLAYERS TO DRIVE MARKET
8.5 OTHER APPLICATIONS

9 CARDIAC TISSUE ENGINEERING MARKET, BY END USER

9.1 INTRODUCTION
9.2 HOSPITALS & CLINICS
- 9.2.1 ADVANCED INFRASTRUCTURE AND ACCESS TO CLINICAL TRIALS - KEY DRIVERS
9.3 ACADEMIC & RESEARCH INSTITUTES
- 9.3.1 AVAILABILITY OF FUNDING FOR RESEARCH - KEY DRIVER
9.4 OTHER END USERS

10 CARDIAC TISSUE ENGINEERING MARKET, BY REGION

10.1 INTRODUCTION
10.2 NORTH AMERICA
- 10.2.1 MACROECONOMIC OUTLOOK FOR NORTH AMERICA
- 10.2.2 US
  - 10.2.2.1 Increasing government grants for research to drive market
- 10.2.3 CANADA
  - 10.2.3.1 Availability of funding for research on regenerative medicine to fuel market
10.3 EUROPE
- 10.3.1 MACROECONOMIC OUTLOOK FOR EUROPE
- 10.3.2 UK
  - 10.3.2.1 Fastest-growing market for cardiac tissue engineering in Europe
- 10.3.3 GERMANY
  - 10.3.3.1 Rising prevalence of cardiovascular diseases - key driver
- 10.3.4 FRANCE
  - 10.3.4.1 Increasing focus on regenerative medicine to boost market
- 10.3.5 ITALY
  - 10.3.5.1 Insufficient research funding to restrain growth of market
- 10.3.6 SPAIN
  - 10.3.6.1 Increase in R&D investment to drive market growth
- 10.3.7 REST OF EUROPE
10.4 ASIA PACIFIC
- 10.4.1 MACROECONOMIC OUTLOOK FOR ASIA PACIFIC
- 10.4.2 JAPAN
  - 10.4.2.1 Increasing aging population to drive market growth
- 10.4.3 CHINA
  - 10.4.3.1 Major cardiac tissue engineering market in Asia Pacific
- 10.4.4 INDIA
  - 10.4.4.1 Increasing government initiatives for clinical trials in stem cell research to boost market
- 10.4.5 AUSTRALIA
  - 10.4.5.1 Growing government support to fuel market
- 10.4.6 SOUTH KOREA
  - 10.4.6.1 Advancements in technology and strong government support to drive market growth
- 10.4.7 REST OF ASIA PACIFIC
10.5 LATIN AMERICA
- 10.5.1 MACROECONOMIC OUTLOOK FOR LATIN AMERICA
- 10.5.2 BRAZIL
  - 10.5.2.1 Increase in prevalence of congenital heart disease to drive market
- 10.5.3 MEXICO
  - 10.5.3.1 Rapidly growing geriatric population - key driver
- 10.5.4 REST OF LATIN AMERICA
10.6 MIDDLE EAST & AFRICA
- 10.6.1 EXPANDING NETWORK OF ADVANCED HEALTHCARE FACILITIES TO SUPPORT MARKET GROWTH
- 10.6.2 MACROECONOMIC OUTLOOK FOR MIDDLE EAST & AFRICA
- 10.6.3 GCC COUNTRIES
  - 10.6.3.1 Increased inclination toward novel therapies - key driver
- 10.6.4 REST OF MIDDLE EAST & AFRICA

11 COMPETITIVE LANDSCAPE

11.1 OVERVIEW
11.2 KEY PLAYER STRATEGIES/RIGHT TO WIN
11.3 REVENUE SHARE ANALYSIS
11.4 MARKET SHARE ANALYSIS
11.5 VALUATION AND FINANCIAL METRICS OF HEALTHCARE SERVICE VENDORS
11.6 COMPANY EVALUATION MATRIX, KEY PLAYERS (2023)
- 11.6.1 STARS
- 11.6.2 EMERGING LEADERS
- 11.6.3 PERVASIVE PLAYERS
- 11.6.4 PARTICIPANTS
- 11.6.5 COMPANY FOOTPRINT: KEY PLAYERS, 2023
  - 11.6.5.1 Company footprint
  - 11.6.5.2 Region footprint
  - 11.6.5.3 Application footprint
  - 11.6.5.4 Product footprint
  - 11.6.5.5 Material footprint
  - 11.6.5.6 End user footprint
11.7 COMPANY EVALUATION MATRIX, STARTUPS/SMES (2023)
- 11.7.1 PROGRESSIVE COMPANIES
- 11.7.2 RESPONSIVE COMPANIES
- 11.7.3 DYNAMIC COMPANIES
- 11.7.4 STARTING BLOCKS
- 11.7.5 COMPETITIVE BENCHMARKING OF KEY STARTUPS/SMES
  - 11.7.5.1 Detailed list of key startups/smes
  - 11.7.5.2 Competitive benchmarking of key startups/SMEs
11.8 COMPETITIVE SCENARIO
- 11.8.1 PRODUCT LAUNCHES
- 11.8.2 DEALS
11.9 BRAND/PRODUCT COMPARATIVE ANALYSIS

12 COMPANY PROFILES

12.1 KEY PLAYERS
- 12.1.1 TERUMO CORPORATION
  - 12.1.1.1 Business overview
  - 12.1.1.2 Products offered
  - 12.1.1.3 MnM view
    - 12.1.1.3.1 Right to win
    - 12.1.1.3.2 Strategic choices
    - 12.1.1.3.3 Weaknesses & competitive threats
- 12.1.2 ARTIVION, INC.
  - 12.1.2.1 Business overview
  - 12.1.2.2 Products offered
  - 12.1.2.3 Recent developments
  - 12.1.2.4 MnM view
    - 12.1.2.4.1 Right to win
    - 12.1.2.4.2 Strategic choices
    - 12.1.2.4.3 Weaknesses & competitive threats
- 12.1.3 BAXTER INTERNATIONAL, INC.
  - 12.1.3.1 Business overview
  - 12.1.3.2 Products offered
  - 12.1.3.3 Recent developments
  - 12.1.3.4 MnM view
    - 12.1.3.4.1 Right to win
    - 12.1.3.4.2 Strategic choices
    - 12.1.3.4.3 Weaknesses & competitive threats
- 12.1.4 TEIJIN LIMITED
  - 12.1.4.1 Business overview
  - 12.1.4.2 Products offered
  - 12.1.4.3 MnM view
    - 12.1.4.3.1 Right to win
    - 12.1.4.3.2 Strategic choices
    - 12.1.4.3.3 Weaknesses & competitive threats
- 12.1.5 MEDTRONIC PLC
  - 12.1.5.1 Business overview
  - 12.1.5.2 Products offered
  - 12.1.5.3 Recent developments
  - 12.1.5.4 MnM view
    - 12.1.5.4.1 Right to win
    - 12.1.5.4.2 Strategic choices
    - 12.1.5.4.3 Weaknesses & competitive threats
- 12.1.6 BOSTON SCIENTIFIC CORPORATION
  - 12.1.6.1 Business overview
  - 12.1.6.2 Products offered
- 12.1.7 ABBOTT LABORATORIES
  - 12.1.7.1 Business overview
  - 12.1.7.2 Products offered
  - 12.1.7.3 Recent developments
- 12.1.8 MERCK KGAA
  - 12.1.8.1 Business overview
  - 12.1.8.2 Products offered
- 12.1.9 FUJIFILM HOLDINGS CORPORATION
  - 12.1.9.1 Business overview
  - 12.1.9.2 Products offered
- 12.1.10 BICO - THE BIO CONVERGENCE COMPANY
  - 12.1.10.1 Business overview
  - 12.1.10.2 Products offered
- 12.1.11 ELUTIA
  - 12.1.11.1 Business overview
  - 12.1.11.2 Products offered
- 12.1.12 W. L. GORE AND ASSOCIATES, INC.
  - 12.1.12.1 Business overview
  - 12.1.12.2 Products offered
- 12.1.13 MERIL LIFESCIENCES PVT. LTD.
  - 12.1.13.1 Business overview
  - 12.1.13.2 Products offered
- 12.1.14 VASCUDYNE, INC.
  - 12.1.14.1 Business overview
  - 12.1.14.2 Products offered
- 12.1.15 REPROCELL, INC.
  - 12.1.15.1 Business overview
  - 12.1.15.2 Products offered
  - 12.1.15.3 Recent developments
12.2 OTHER PLAYERS
- 12.2.1 AXOL BIOSCIENCE LTD.
- 12.2.2 BPS BIOSCIENCE, INC.
- 12.2.3 TAKARA BIO, INC.
- 12.2.4 XELTIS
- 12.2.5 VISCOFAN DE GMBH
- 12.2.6 CELL APPLICATION, INC
- 12.2.7 PROMOCELL GMBH

13 APPENDIX

13.1 DISCUSSION GUIDE
13.2 KNOWLEDGESTORE: MARKETSANDMARKETS' SUBSCRIPTION PORTAL
13.3 CUSTOMIZATION OPTIONS
13.4 RELATED REPORTS
13.5 AUTHOR DETAILS