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Mary Kay Inc. Awards 10 Grants to Young Innovators at 2025 Regeneron International Science and Engineering Fair

Mary Kay Inc. Awards 10 Grants to Young Innovators at 2025 Regeneron International Science and Engineering Fair

National Post28-05-2025
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DALLAS — Mary Kay Inc., a global advocate for furthering young women's education and encouraging youth to follow their STEM dreams, returned for a second year as a Special Awards Organization at the Regeneron International Science and Engineering Fair (Regeneron ISEF) in Columbus, Ohio. Ten grants totaling nearly $10,000 were awarded to standout high school-aged students excelling in innovative projects spanning topics from finding cures for cancers affecting women to sustainable packaging innovation and protecting our planet's most valuable resources.
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'Their work has the potential to transform industries, drive sustainable advancements, and accelerate major breakthroughs in fields like cancer research, material science, and environmental engineering.'
Each year, the event convenes nearly 2,000 participants representing more than 60 countries, with a total award pool offering over $9 million in awards and scholarships and invitations to corporate and academic events with elite global leaders in STEM.
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Celebrating its 75 th year, ISEF, a program of Society for Science, is the world's largest pre-college global STEM competition. Through a global network of local, regional, and national science fairs, millions of students are encouraged to explore their passion for scientific inquiry. Each spring, a group of these students is selected as finalists and offered the opportunity to compete for approximately $9 million in awards and scholarships at the annual Regeneron ISEF.
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'The ingenuity, passion, and innovation demonstrated by these young STEM leaders are awe-inspiring,' said Carrissa Dowdy, Manager of Product Formulation at Mary Kay. 'Their work has the potential to transform industries, drive sustainable advancements, and accelerate major breakthroughs in fields like cancer research, material science, and environmental engineering. Mary Kay is proud to stand behind them as they shape the future of STEM.'
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MEET THE STUDENT STEM LEADERS
1.
Pragathi Kasani-Akula (GA, USA)
Multi-Color Magneto-Fluorescent Nanoarchitectures for the Targeted Identification of Exosomes of Triple Negative Breast Cancer
2.
Grace Liu (NY, USA)
Evaluating Gender Disparities Due to Decision-Making Under Uncertainty in Entrepreneurship: A Panel Data Analysis
3.
Alina Albeik (VA, USA)
Implications of Resveratrol on Memory Retention in Dugesia tigrina
4.
Kaili Tseng and Leila Gheysar (CA, USA)
Bombyx mori Antimicrobial Peptides: A Novel and Sustainable Catalyst for Cancer Cell Growth Inhibition and Death
5.
Elisabeth Fischermann and Tom Kressbach (Bavaria, Germany)
On the Hunt for Free Radicals With a Blue Light Reaction
6.
Ela Doruk Korkmaz (Istanbul, Turkey)
Investigation of Potential Anti-Cancer Impacts of Coffee Bean-Derived Exosomes Through Anti-Proliferative and Apoptosis Inducing Effects on Melanoma Skin Cancer Cells via Mitogen-Activated Protein Kinase Signaling Pathway
7.
Carolina de Araujo Pereira da Silva* (Rio de Janeiro, Brazil)
Salinomycin as a Molecular Trojan Horse for Targeting Mn-Induced Malignancy in Aggressive Tumors
8.
Sofia Nunes (Maranhao, Brazil)
Formulation of Low-Cost Artificial Skin for Cellular Regeneration and Severe Burns Treatment
9.
Margareth Ac-ac (Negros Oriental, Philippines)
SKIMP: Artificial Intelligence- Convolutional Neural Network (CNN) Portable Skin Cancer Detection Device With Skin Cancer Notifier Python-Based Program
10.
Kamila Rotger-Costas and Miranda Sanz-Alvarez (Guaynabo and Caguas, Puerto Rico)
EcoReishiFlex: An Innovative Sustainable Biodegradable Plastic Alternative Made From Ganoderma lucidum (Reishi Fungi) Polysaccharides
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* Carolina de Araujo Pereira da Silva is a two-time Mary Kay Young Women in STEM grant recipient for her outstanding contributions to the cancer research field. Her 2024 prize money was utilized toward furthering her presented project – Rock the Metals! Investigating Manganese as a Trigger of Malignancy and Metal Transporters as Targets in Cancer Treatment which elevated her 2025 award-winning submission.
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One of the original glass ceiling breakers, Mary Kay Ash founded her dream beauty brand in Texas in 1963 with one goal: to enrich women's lives. That dream has blossomed into a global company with millions of independent sales force members in more than 40 markets. For over 60 years, the Mary Kay opportunity has empowered women to define their own futures through education, mentorship, advocacy, and innovation. Mary Kay is dedicated to investing in the science behind beauty and manufacturing cutting-edge skincare, color cosmetics, nutritional supplements, and fragrances. Mary Kay believes in preserving our planet for future generations, protecting women impacted by cancer and domestic abuse, and encouraging youth to follow their dreams. Learn more at marykayglobal.com. Find us on Facebook, Instagram, and LinkedIn, or follow us on X.
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Healthcare Simulation Market: Trends, Innovations, and Future Perspectives
Healthcare Simulation Market: Trends, Innovations, and Future Perspectives

Globe and Mail

time21 minutes ago

  • Globe and Mail

Healthcare Simulation Market: Trends, Innovations, and Future Perspectives

"Browse 336 market data Tables and 43 Figures spread through 363 Pages and in-depth TOC on "Healthcare Simulation Market by Product & Service (Simulation (Patient-Fidelity, Surgical-Laparoscopic, Ortho, Spine, Gynae, Ultrasound), Training), Technology (3D Printing, Virtual Patient, Procedural Rehearsal), End User, & Region - Global Forecast 2030" North America led the healthcare simulation market, mainly driven by sustained investments in mobile simulation technology and rural healthcare training. In recent years, healthcare simulation has become a powerful tool in training healthcare professionals, advancing research, and improving patient outcomes. The healthcare simulation market includes a wide array of products and technologies designed to replicate clinical scenarios, allowing medical students, nurses, physicians, and other healthcare professionals to practice skills, test procedures, and learn in a risk-free environment. As demand for quality healthcare increases and technology advances, the healthcare simulation market is poised for significant growth. In this blog, we'll explore the driving factors, innovations, challenges, and future trends shaping the healthcare simulation market. Download an Illustrative overview: 1. Understanding the Healthcare Simulation Market What is Healthcare Simulation? Healthcare simulation is a training and educational method that uses artificial models, virtual environments, and high-tech devices to simulate clinical settings. These simulations range from simple anatomical models to sophisticated virtual reality (VR) and augmented reality (AR) platforms that replicate complex scenarios in real-time. Simulation allows healthcare professionals to learn from errors, improve skills, and practice procedures without endangering patients, making it an invaluable tool in medical education. Types of Healthcare Simulations Healthcare simulation encompasses several types, each serving different training and educational needs: Manikin-Based Simulation: High-fidelity manikins mimic human physiology and can be programmed to exhibit various conditions and symptoms, allowing users to practice physical exams, invasive procedures, and resuscitation techniques. Task Trainers: These models are designed to teach specific skills, like suturing, IV insertion, and intubation. They are highly focused, allowing learners to develop technical competencies before working with live patients. Virtual Reality (VR) Simulation: VR immerses users in simulated environments, allowing them to interact with virtual patients, perform surgeries, or navigate complex scenarios. Augmented Reality (AR) Simulation: AR overlays digital information in the real world, enhancing users' training experience by providing real-time data and visual aids. Standardized Patients (SPs): Trained actors play the role of patients, simulating various medical conditions. SPs are used to teach interpersonal skills, diagnosis, and patient communication. 2. Key Drivers of the Healthcare Simulation Market Several factors are propelling the growth of the healthcare simulation market, reflecting the need for efficient, safe, and modern training methods. 1. Growing Emphasis on Patient Safety Patient safety has become a top priority for healthcare providers worldwide. Simulation-based training provides a risk-free environment where healthcare professionals can make mistakes and learn from them without harming patients. This emphasis on safety has driven healthcare facilities to adopt simulation for training in high-stakes scenarios, particularly in emergency medicine, surgery, and critical care. 2. Shortage of Skilled Healthcare Professionals The global shortage of healthcare workers, particularly nurses and doctors, is intensifying the need for high-quality training tools. Simulation offers a way to scale training programs, allowing healthcare institutions to train large numbers of students and professionals efficiently. This is particularly important in developing regions, where access to clinical training resources may be limited. 3. Advancements in Technology Innovations in VR, AR, artificial intelligence (AI), and machine learning have expanded the possibilities of healthcare simulation. Advanced technology has enabled high-fidelity simulations that accurately replicate real-world scenarios, making training more effective and realistic. With the increased availability of affordable VR and AR devices, simulation has become more accessible to educational institutions and hospitals. 4. Increasing Use in Surgical Training and Procedural Skills Development Surgeons and interventionalists benefit significantly from simulation, as it allows them to practice complex and high-risk procedures without patient involvement. This trend has driven demand for simulators that accurately replicate the anatomy and tactile feel of various procedures, such as laparoscopy, endoscopy, and robotic surgery. Surgical simulation reduces the learning curve for new techniques and improves outcomes in real-world settings. Buy a Healthcare Simulation Industry Report (305 Pages PDF with Insightful Charts, Tables, and Figures): 3. Emerging Trends in Healthcare Simulation 1. Virtual and Augmented Reality Simulation Virtual and augmented reality are transforming healthcare simulation by providing immersive, interactive environments. VR allows learners to enter a fully simulated world where they can practice procedures and make clinical decisions. AR, on the other hand, enhances real-world interactions by overlaying digital information on physical objects. These technologies allow students and professionals to experience realistic scenarios and receive instant feedback, making learning more engaging and effective. 2. AI-Driven Simulations Artificial intelligence is beginning to play a major role in healthcare simulation, particularly in patient behavior modeling and real-time feedback. AI-driven simulators can adjust a scenario based on the learner's actions, providing dynamic and adaptive training experiences. This type of responsive learning environment can track performance, highlight areas for improvement, and tailor scenarios to individual learner needs, making training more efficient and personalized. 3. Simulation for Soft Skills Development While simulation has traditionally focused on technical skills, there is a growing trend toward using it for soft skills, such as patient communication, empathy, and teamwork. This type of training is crucial for building trust and rapport with patients, reducing errors, and enhancing patient satisfaction. Standardized patients and VR are commonly used in these simulations, which emphasize interpersonal interactions and collaborative skills. 4. Expanded Use in Medical Research Beyond training, simulation is becoming a valuable tool in medical research. It allows researchers to model disease progressions, test new treatments, and develop medical devices in a controlled environment. For example, pharmaceutical companies use simulation to understand how drugs interact with human physiology, while medical device companies simulate device functionality and test prototypes. 5. Home-Based and Remote Simulation The COVID-19 pandemic highlighted the need for remote training options, leading to the development of home-based simulation solutions. These solutions allow students to practice skills and scenarios from home, using mobile devices, VR headsets, or computer-based programs. Remote simulation will likely continue to grow, providing flexibility and accessibility, especially for institutions with limited resources. 4. Challenges in the Healthcare Simulation Market Despite the promising growth, the healthcare simulation market faces challenges that may hinder its expansion. 1. High Costs of Simulation Systems High-fidelity simulators, VR setups, and AR devices are expensive, making them difficult for smaller institutions to afford. Additionally, maintaining and upgrading simulation equipment requires significant investment. Although prices are decreasing as technology advances, cost remains a barrier, particularly in developing regions and small-scale healthcare facilities. 2. Limited Access to Trained Instructors Simulation-based training requires skilled instructors who can guide participants through scenarios, assess their performance, and provide constructive feedback. However, there is a shortage of qualified instructors trained in both clinical practice and simulation methods. Expanding access to simulation education programs for instructors is essential to fully leverage simulation technology. 3. Standardization and Validation Issues There is limited standardization in simulation, with different institutions adopting varied methodologies and equipment. This lack of consistency can lead to variations in training quality and effectiveness. Furthermore, while simulation has proven effective for skills development, there is still a need for robust evidence to validate its long-term impact on clinical outcomes. 4. Integrating Simulation into Traditional Curriculums For simulation to be effective, it must be integrated into traditional healthcare curriculums rather than treated as an optional addition. However, many educational institutions struggle with incorporating simulation into their programs due to logistical and financial constraints. Aligning simulation with core curriculum requirements will be necessary for sustainable growth. 5. Future Prospects of the Healthcare Simulation Market Expansion of Simulation in Developing Regions As healthcare systems develop and infrastructure improves in low- and middle-income countries, there will be an increasing demand for simulation-based training. Simulation offers a way to bridge the skills gap in these regions, providing scalable solutions for training healthcare workers. Non-profit organizations, governments, and private companies are investing in simulation to build healthcare capacity, making it accessible to underserved communities. Integration with Telemedicine and Remote Learning The future of healthcare simulation will likely involve integration with telemedicine and remote learning technologies. Combining telemedicine with simulation can enable real-time training and supervision, especially in remote areas. This fusion will enhance accessibility to high-quality training and potentially transform how healthcare education is delivered. Customized Simulation for Precision Medicine Personalized healthcare is gaining traction, and simulation can support this trend by enabling customized training programs for specific conditions, procedures, and patient demographics. For instance, simulators could be tailored to mimic rare diseases, complex surgeries, or high-risk patient groups, providing healthcare professionals with the skills needed to offer more personalized care. Data Analytics and Machine Learning in Simulation The incorporation of data analytics and machine learning into simulation could provide more in-depth insights into learners' performance, skills, and knowledge gaps. Simulation centers could use these insights to develop more targeted training interventions, while medical educators could use data to enhance curriculums and improve student outcomes. Simulation for Community Education and Public Health As simulation technology becomes more accessible, it could play a role in public health by educating communities on basic healthcare practices. This could involve simulations that teach first aid, CPR, or emergency response, promoting healthcare awareness and resilience within communities. Conclusion The healthcare simulation market is on an upward trajectory, with technological innovations, a focus on patient safety, and the need for high-quality training driving its growth. While challenges such as cost, access to instructors, and standardization remain, the future of healthcare simulation holds immense potential. As VR, AR, AI, and data analytics continue to evolve, simulation will become more immersive, personalized, and accessible, ultimately leading to better-trained healthcare professionals and improved patient care. Whether used in medical education, clinical training, or public health, healthcare simulation is set to become an indispensable tool in shaping the future of healthcare. Get 10% Free Customization on this Report:

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