Bio
Rumiana Tenchov is an information scientist at CAS. She earned her Ph.D. and D.Sc. degrees in biophysics from the Bulgarian Academy of Sciences. Prior to joining CAS, she was a research faculty member at the Department of Molecular Biosciences of the Northwestern University.
이머징 사이언스
Decoding neurodegenerative diseases like Alzheimer's, Parkinson's, and Huntington's
Uncover the latest advancements in understanding and treating neurodegenerative diseases like Alzheimer’s, Parkinson’s, and Huntington’s.
약물 발견
Are inverse vaccines the cure for autoimmune diseases?
Sharing new research on inverse vaccines, potential new breakthroughs in treating autoimmune diseases like multiple sclerosis, type 1 diabetes and celiac disease
약물 발견
Ending Alzheimer's: Emerging trends in biomarkers, gene therapy, and more
Biomarkers, personalized medicine and gene therapies are fueling research breakthroughs. Discover new treatments targeting genetics and protein buildup to manage this devastating disease.
약물 발견
Can we cure Huntington's? Research trends in PolyQ and rare diseases
While no cure exists for PolyQ diseases like Huntington's, new breakthroughs, therapies, and research could change that.
생명공학
How biomarkers unlock faster cancer detection, improving outcomes
As cancer is projected to increase, finding stronger therapeutics is more urgent. Biomarkers offer a potential solution for better diagnosis and treatment.
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Biomarkers: The key to earlier cancer detection and patient outcomes
CAS and Excelra delved into data surrounding biomarkers and their relationship to cancer to identify key targets for future study.
약물 발견
Unveiling the potential of the antibody drug conjugate
Since 2018, research interest in antibody-drug conjugates has increased exponentially, due to their potential in the fight against cancer.
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Aging reimagined: Exploring the potential of anti-aging treatment strategies
Discover the latest in anti-aging treatment strategies to promote health and longevity, including stem cell therapies, hyaluronic acid, senolytics, gene therapy, and more.
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The ultimate guide for PEGylated lipid nanoparticles
PEG immunogenicity affects the safety and efficacy of PEGylated lipid nanoparticles for drug delivery. Much work is being done to circumvent this challenge in applying these polymers.
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Friend, not foe: Harnessing the gut microbiome for health benefits
The gut microbiome is a complex ecosystem of trillions of bacteria that live in our digestive tracts with health benefits like immunity, improved mental health, and therapeutic options.
생명공학
The evolving exosome: from small player to rising star
A historical overview of the discovery of exosomes, key milestones in their rise, and why they will revolutionize the diagnostic and drug delivery fields in the future.
안전
Ammonium nitrate: making it safer today for a better tomorrow
Ammonium nitrate has the power to feed billions, yet when stored improperly is like a bomb waiting to happen. How can we make this fertilizer safer? Learn about emerging science, safer alternatives, and best practices for safe storage and transport.
약물 발견
COVID-19 이외 질병에 대한 나노 기술의 잠재적 치료 효과
지질 나노 입자와 원천 기술, COVID 백신에서의 역할과 향후 응용 가능성에 대해 알아보십시오. 백신, 약물 전달과 더불어 농업-화학, 화장품, 식품 과학과 같은 비치료 용도와 관련한 간행물, 중대 업적, 향후 응용 분야에 대한 통찰력과 새로운 동향을 개괄적으로 살펴봅니다.
약물 발견
With COVID BA.5 and BA.2.75 variants, are masks back in?
The COVID pandemic revealed deficiencies in mask development and production. Innovation will be crucial in slowing the spread of new variants of the virus.
약물 발견
Are intrinsically disordered proteins the key to treating COVID-19?
Learn about the important functions of intrinsically disordered proteins and the key role they play in COVID-19 therapy.
이머징 사이언스
장내 마이크로바이옴과 우울증, 불안의 연관성
장내 미생물군, 장내 세균 또는 마이크로바이옴은 인간 또는 다른 동물의 소화관에서 생존하는 미생물입니다. 일부 박테리아는 질병과 관련이 있는 반면 신체 건강과 정신 건강의 많은 측면에서 특히 중요한 박테리아도 있습니다.
생명공학
지질 나노 입자 - 암 치료의 핵심 요소
지질 나노 입자는 제약 산업에서 중요한 치료 수단이자 의료 영상, 화장품, 영양 등의 분야에서도 중요한 역할을 합니다. 암 치료를 위한 지질 나노 입자의 활용 방식과 나노 의학의 미래에 대해 알아보십시오.
지속 가능성
플라스틱을 먹는 수퍼 효소로 플라스틱의 환경 오염 문제를 해결할 수 있을까요?
미생물 효소로 수백년이 걸리는 플라스틱 분해 속도를 앞당길 수 있는 방법에 대한 연구 개요.