Bioengineering’s Post

Sharing My Journey: From Biochemistry to International Business I want to share my journey from studying biochemistry in undergrad to now pursuing a Master's in International Business. Though these fields might seem quite different, my transition was fueled by a deep passion for grasping how the world works on a global scale. During my biochemistry years, I was captivated by the intricate details of how cells function and how molecules interact. It was a thrilling journey of discovery, where I grew to deeply appreciate the scientific method and the pursuit of knowledge. As I delved deeper into biochemistry, I realized that my curiosity extended beyond the laboratory. I became keen on how scientific advancements impact businesses, economies, and societies worldwide. This realization drove me to change course. In our interconnected world, I have realized the vital importance of understanding international business. It's not just about products and services; it's about the rich tapestry of people, cultures, and the vast global marketplace. My biochemistry background equipped me with a valuable skill set: analytical thinking, problem-solving abilities, and critical reasoning, which are incredibly useful in making sound business decisions. What truly excites me is the convergence of science and business, where groundbreaking innovations often originate. Here, I see the potential to make a meaningful impact, contributing to innovative solutions to our world's most pressing challenges. As I venture into International Business, I bring with me not only scientific knowledge but also a spirit of curiosity and a dedication to problem-solving. I firmly believe that every new day presents an opportunity for learning and growth. I'm excited about the path ahead, where I can bridge the gap between scientific knowledge and real-world applications, and make a meaningful contribution to our understanding of the global business landscape. I'm keen to connect with individuals who have undergone similar transitions and anyone interested in the fusion of science and business. Let's learn from each other and collaboratively create new opportunities!

In the dynamic landscape of scientific innovation, staying ahead requires continuous growth and adaptation. For chemists, upskilling isn't just a choice – it's a pivotal strategy to excel and make meaningful contributions. As new technologies redefine traditional paradigms, honing our skills ensures we remain at the forefront of groundbreaking discoveries. From mastering advanced analytical techniques to embracing computational chemistry, upskilling equips us with the tools to tackle complex challenges head-on. Embracing this journey isn't just about personal development; it's about amplifying our collective impact on industries ranging from pharmaceuticals to materials science. So, let's embrace the transformative power of upskilling, propelling our profession to unprecedented heights and shaping a brighter scientific future together. 💡🌟 #chemistry #innovation #upskilling #scientificexcellence

If biological breakthroughs were combined with digital technology innovations, which industries do you think will be positively impacted? 🤔   It's exciting to see future of bioengineering as a key tech trend this year. It has the potential to do wonders for healthcare, sustainability, food and agriculture, consumer products, and energy and materials production. Our research indicates that 400 bioengineering use cases could lead to an economic impact of $2 trillion to $4 trillion every year from 2030 to 2040.   Job openings in bioengineering has more than doubled since 2018. The field also attracts more scientific and research talent than any other trend, and ensures long hiring cycles as the technologies often need years or decades before they reach the market.   If you're interested to learn more about how the future of bioengineering has the potential to be a transformative tech trend, read our report here: https://lnkd.in/etPnh3DJ   #ArtificialIntelligence #McKinseyTechTrends #TechTrends2023 #Bioengineering

The difference between research and revolutionary research. Scientific research * You ask what you can do with the tools available * You use the available tools * You are reasonably confident you can succeed before you begin * Others in the field predict you can succeed * Others in the field are doing very similar work * You can predict in advance how long it will take and what it will cost * Successful completion is a priority * You had a successful career if you generated a steady stream of papers, patents, grants, or products. * You make small improvements on existing methods Revolutionary scientific research * You ask what you would want to do if you could find a way to do it * You invent new tools * You begin work with no idea if you can succeed * Others in the field think the task may be impossible * Others in the field avoid attempting similar work * You can not accurately predict the time or cost that will be involved * Attempting work that will have an important impact is a priority * You had a successful career if you made one major contribution to the field. * You develop new methods Research will get you tenure, but revolutionary research could get you a Nobel Prize.

Starting a business doesn't always require a large initial investment, and individuals with degrees in fields like Biochemistry or Genetics can leverage their skills and knowledge to explore entrepreneurial opportunities. Here are some relatively inexpensive and manageable business ideas that align with these degrees: 1. Science Tutoring:   - Offer tutoring services in biology, chemistry, or genetics to high school or college students. You can conduct one-on-one sessions or small group classes. 2. Biotech Consulting:   - Provide consulting services to small biotech startups or local businesses in need of expertise in areas such as quality control, laboratory procedures, or regulatory compliance. 3. Genetic Testing Services:   - Start a business offering genetic testing services to individuals interested in learning more about their ancestry, health risks, or genetic traits. You can collaborate with established testing laboratories for the actual analysis. 4. **Science Communication Blog/Vlog:**   - Share your knowledge and passion for science through a blog, YouTube channel, or podcast. This can serve as a platform to educate the public on scientific topics and generate income through ads or sponsorships. 5. **Science Event Planning:**   - Organize science-themed events, workshops, or seminars for schools, community groups, or businesses interested in fostering scientific knowledge. 6. **Online Courses or Webinars:**   - Develop and offer online courses or webinars on biochemistry or genetics topics. Platforms like Udemy or Teachable can help you reach a global audience. 7. **Biotech Equipment Rental:**   - Acquire basic laboratory equipment and offer rental services to small businesses, schools, or individuals who need occasional access to specialized tools. 8. **Educational Materials Production:**   - Create educational materials, such as study guides, textbooks, or interactive online resources, and sell them to students or educational institutions. 9. **Biodegradable Product Development:**   - Use your knowledge of biochemistry to explore the development of biodegradable products, such as eco-friendly packaging or sustainable materials. 10. Scientific Illustration Services:    - Offer scientific illustration services for textbooks, research papers, or educational materials. This can include creating diagrams, illustrations, or animations. 11. Health and Wellness Consultancy:    - Combine genetics knowledge with a focus on health and wellness. Offer personalized advice on nutrition, fitness, and lifestyle based on genetic factors.

Adapting research presentations for different audiences. Recently I have had the opportunity to present my PhD research, using particle image velocimetry to visualise blood flow through models of the aorta, to a biosciences audience. In the form of a seminar presentation, poster and 3 minute flash talk. Adjusting my presentation for the biosciences audience meant shifting the discussions from technical details to concentrate on the biological and medical implications of my work and the results. Designing each of the presentation formats was a really valuable experience that highlighted the importance of tailoring our communication of research to the audience. Effective science communication can help bridge gaps and encourage inquisitive questions that could perhaps lead to development of new ideas and possible collaborations.

An Aspect of Research: Intellectual Property (IP) Protection I have organised numerous seminars on fostering young researchers' development in my Department of Chemical Engineering at Imperial College London. These seminars have covered various topics, including researcher visibility, enhancing research impact, building networks and industrial connections, and intellectual property. But have we really delved deeply enough into IP? 🤔 From whom should we protect our ideas? Is it other research groups or companies in the same field? What if the challenge comes from a close colleague you are collaborating with on research projects? These are critical questions that need addressing: How do you protect your work without stifling essential collaborations? How do you find the right balance between open scientific discussion and necessary confidentiality? How can you ensure collaborations remain productive and free from unpleasant surprises? It is imperative to strike a balance where innovation thrives, collaborations flourish, and intellectual property remains secure.

Learn more about current trends in biomanufacturing with BIOMADE USA, INC. a non-profit Manufacturing Innovation Institute supported by the Department of Defense, which is working to enable domestic bioindustrial research, commercialization, and manufacturing at all scales. This webinar will cover how manufacturing institutes work, how small-medium sized manufacturers can evaluate opportunities for integrating biomaterials into their supply chains, and how faculty, startups, and K-12 schools can partner on projects intended to advance US bioindustrial product research, development, and education. A selection of BioMADE’s Technical and Education & Workforce Development projects will be featured as case studies.