Neusa Steiner | Ecology and Conservation | Women Researcher Award

Published on by Forensic Scientist Awards

Women Researcher Award

Neusa Steiner
University of Hawai‘i at Mānoa, United States
Neusa Steiner
Affiliation University of Hawai‘i at Mānoa
Country United States
Scopus ID 7006954823
Documents 60
Citations 957+
h-index 17
Subject Area Ecology and Conservation
Event International Forensic Scientist Awards
ORCID 0000-0001-6063-9242

Neusa Steiner is a researcher associated with the University of Hawai‘i at Mānoa whose scholarly work has contributed significantly to plant biotechnology, conservation biology, seed physiology, somatic embryogenesis, and cryopreservation studies. Her academic record reflects sustained contributions to the understanding of ex situ plant conservation and the developmental physiology of forest and tropical plant species.[1] Through collaborative international research, Steiner has contributed to advances in plant developmental biology and ecological conservation methodologies relevant to sustainable biodiversity management.[2]

Abstract

This article presents an academic overview of the research profile and scholarly contributions of Neusa Steiner in the fields of ecology, conservation biology, plant physiology, and biotechnology. Steiner’s research activities have focused on somatic embryogenesis, conservation of forest genetic resources, cryopreservation technologies, seed biology, and in vitro culture systems for endangered and economically significant plant species.[3] Her publication record demonstrates interdisciplinary collaboration and scientific engagement across multiple botanical and environmental research domains. The article further examines her suitability for recognition through the Women Researcher Award presented at the International Forensic Scientist Awards.

Keywords

Plant Biotechnology, Ecology and Conservation, Somatic Embryogenesis, Cryopreservation, Seed Physiology, Forest Genetic Resources, In Vitro Culture, Ex Situ Conservation, Araucaria angustifolia, Women Researcher Award

Introduction

The advancement of plant biotechnology and conservation sciences has become increasingly important in response to global biodiversity loss and environmental change. Researchers contributing to these areas play a critical role in developing strategies for species preservation, propagation, and ecological sustainability. Neusa Steiner has contributed to this scientific landscape through research on embryogenic cultures, seed conservation technologies, and physiological mechanisms associated with plant development.[4]

Her academic collaborations have involved institutions and researchers across Latin America and international scientific communities, with studies frequently addressing conservation challenges related to Araucaria angustifolia and other native species.[5] The integration of molecular, histological, and physiological methodologies within her research portfolio has contributed to broader understanding in plant developmental biology and biotechnology.

Research Profile

Neusa Steiner’s scholarly profile reflects a sustained commitment to plant conservation and developmental physiology. Her documented academic output includes more than sixty indexed publications with substantial citation activity across biotechnology and ecological sciences.[1] Her work frequently investigates somatic embryogenesis and cellular differentiation processes in gymnosperm species, particularly Araucaria angustifolia.

Steiner’s research interests include:

  • Ex situ plant conservation methodologies
  • Seed physiology and seed storage technologies
  • Cryopreservation systems for endangered plant species
  • In vitro culture and embryogenic development
  • Forest genetic resource conservation

Her collaborations with specialists in plant developmental physiology, molecular biology, and environmental biotechnology demonstrate an interdisciplinary approach to botanical sciences.[6]

Research Contributions

Steiner’s scientific contributions include investigations into polyamine-mediated regulation of embryogenic cultures and endogenous hormone interactions in conifer species.[7] Her studies have explored how biochemical signaling pathways influence embryogenic competence and developmental transitions in plant tissue cultures.

Several of her publications address the conservation and propagation of Araucaria angustifolia, a species of ecological and conservation significance in South America. Research outputs associated with this work have provided insights into embryogenic tissue characterization, metabolic regulation, and somatic embryo development.[8]

Her work has additionally contributed to:

  • Improvement of somatic embryogenesis protocols
  • Morphological and ultrastructural characterization of embryogenic tissues
  • Biochemical analysis of developmental pathways
  • Studies related to seed dormancy and environmental adaptation
  • Biotechnological approaches for forest species conservation

Publications

Selected publications associated with Neusa Steiner include the following:

  1. Steiner, N., Santa-Catarina, C., Silveira, V., Floh, E.I.S., and Guerra, M.P. “Polyamine effects on growth and endogenous hormones levels in Araucaria angustifolia embryogenic cultures.” Plant Cell, Tissue and Organ Culture, 89(1), 55–62 (2007).
  2. Steiner, N., Santa-Catarina, C., Guerra, M.P., Cutri, L., Dornelas, M.C., and Floh, E.I.S. “A gymnosperm homolog of SOMATIC EMBRYOGENESIS RECEPTOR-LIKE KINASE-1 is expressed during somatic embryogenesis.” Plant Cell, Tissue and Organ Culture, 109(1), 41–50 (2012).
  3. Farias-Soares, F.L., Steiner, N., Schmidt, É.C., Pereira, M.L.T., et al. “The transition of proembryogenic masses to somatic embryos in Araucaria angustifolia is related to endogenous contents of IAA and ABA.” Acta Physiologiae Plantarum, 36(7), 1853–1865 (2014).
  4. Stefenon, V.M., Steiner, N., Guerra, M.P., and Nodari, R.O. “Integrating approaches towards the conservation of forest genetic resources.” Biodiversity and Conservation, 18(9), 2433–2448 (2009).

Research Impact

The research impact associated with Neusa Steiner is reflected through citation metrics, interdisciplinary collaborations, and long-term scientific contributions to conservation biotechnology.[9] Her studies are widely referenced in research concerning plant embryogenesis, seed conservation, and forest biotechnology.

Steiner’s work has supported improved understanding of developmental physiology in threatened plant species while contributing to conservation-oriented biotechnology applications. Her research findings continue to inform ongoing investigations into cryopreservation, tissue culture optimization, and environmental adaptation mechanisms in plants.[10]

Award Suitability

Neusa Steiner demonstrates several characteristics aligned with the objectives of the Women Researcher Award presented through the International Forensic Scientist Awards. Her publication record, citation performance, collaborative scientific engagement, and contribution to ecological and conservation sciences collectively indicate sustained academic productivity and research influence.[11]

The interdisciplinary relevance of her work in biotechnology, conservation, and plant developmental physiology reflects scientific leadership in areas important to biodiversity preservation and sustainable environmental research. Her contributions also illustrate the role of women researchers in advancing international scientific collaboration and innovation within applied biological sciences.

Conclusion

Neusa Steiner has established a notable academic profile through her contributions to plant biotechnology, ecology, and conservation-oriented research. Her investigations into somatic embryogenesis, cryopreservation, and seed physiology have contributed to scientific understanding of plant developmental processes and forest genetic resource conservation. Through a combination of scholarly publications, collaborative research, and interdisciplinary scientific engagement, Steiner’s work represents a meaningful contribution to contemporary conservation biology and plant science research.[12]

References

  1. Elsevier. (n.d.). Scopus author details: Neusa Steiner, Author ID 7006954823. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=7006954823
  2. ORCID. (n.d.). Neusa Steiner ORCID Profile.
    https://orcid.org/0000-0001-6063-9242
  3. Steiner, N. et al. (2007). Polyamine effects on growth and endogenous hormones levels in Araucaria angustifolia embryogenic cultures.
    https://link.springer.com/article/10.1007/s11240-007-9216-5
  4. Santos, A.L.W. et al. (2002). Somatic embryogenesis in parana pine (Araucaria angustifolia).
  5. Stefenon, V.M., Steiner, N., Guerra, M.P., and Nodari, R.O. (2009). Integrating approaches towards the conservation of forest genetic resources.
    https://link.springer.com/article/10.1007/s10531-009-9600-z
  6. University of Hawai‘i at Mānoa. (n.d.). Research affiliation and academic activities.
  7. Dutra, N.T. et al. (2013). Polyamines affect cellular growth and structure of pro-embryogenic masses.
  8. Farias-Soares, F.L. et al. (2014). Transition of proembryogenic masses to somatic embryos in Araucaria angustifolia.
    https://link.springer.com/article/10.1007/s11738-014-1560-6
  9. Google Scholar. (n.d.). Neusa Steiner citation metrics and publication records.
  10. Castander-Olarieta, A. et al. (2019). Thermal stress and metabolite profiles during radiata pine somatic embryogenesis.
  11. Steiner, N. et al. (2016). Morphological and ultrastructural characterization of proembryogenic masses and early somatic embryos.

Masoumeh Bararzadeh Ledari | Environmental Science | Best Researcher Award

Published on by Forensic Scientist Awards

Dr. Masoumeh Bararzadeh Ledari | Environmental Science | Best Researcher Award

Amirkabir University of Technology | Iran

Dr. Masoumeh Bararzadeh Ledari is a distinguished academic and sustainability researcher serving as a Lecturer at Amir Kabir University of Technology. She is widely recognized for her pioneering work in energy systems, sustainable development, and integrated climate-resource modeling. With an extensive background bridging academia, international research institutions, and industry, she has successfully combined theoretical frameworks with practical applications to design innovative solutions for global challenges in energy transition and environmental sustainability. Her reputation as a thought leader is evident in her ability to link resource management, industrial optimization, and climate change resilience in a holistic way.

Professional Profile

Scopus

Google Scholar

ORCID

Education

Dr. Masoumeh Bararzadeh Ledari has an impressive academic journey, beginning with her undergraduate degree in Chemical Engineering from Tehran University, where she focused on experimental modeling of advanced gasification systems. She pursued her Master’s degree in Energy Engineering at Sharif University of Technology, with research dedicated to improving refinery efficiency and reducing environmental impacts through innovative safety and process integration methods. Her doctoral work at the same institution advanced the field of sustainable resource management through hybrid evaluation models designed to minimize ecological costs of energy and material flows. Throughout her education, she consistently aligned her studies with the goal of addressing pressing issues in climate change and energy systems, which shaped the foundation for her current research.

Experience

Dr. Masoumeh Bararzadeh Ledari has built a strong career through a combination of academic appointments, international research fellowships, and technical consultancy leadership. As a Lecturer and Adjunct Professor, she has taught advanced courses in renewable energy technologies, waste management, building life cycle design, and exergy analysis at top universities in Iran. Her academic career is complemented by international research experience at renowned institutions such as the International Institute for Applied Systems Analysis in Austria and the Research Centre for Energy Resources and Consumption in Spain, where she contributed to nexus-based modeling and thermodynamic system analysis. Beyond academia, she has served as Technical Manager and Scientific Director in several national and international projects, leading consultancy in petrochemical, steel, and energy industries. Her leadership in projects involving hydrogen transition pathways, carbon capture and storage, integrated resource management, and climate policy frameworks demonstrates her unique ability to translate research into transformative practice.

Research Interests

Dr. Masoumeh Bararzadeh Ledari’s research portfolio reflects her interdisciplinary vision for sustainability. Her main focus lies in the water-food-energy-climate-land nexus, where she has developed advanced models to address complex interdependencies of resources. She is deeply engaged in circular economy approaches, regenerative life modeling, exergy-based ecosystem simulation, and life cycle assessment, with the objective of reducing the environmental footprint of industrial systems. Another core area of her work addresses low-carbon transitions in industries such as steel, petrochemicals, and hydrogen production, where she integrates climate strategies with technological innovation. Her research is globally relevant, as it provides both scientific and policy insights into mitigating climate change while ensuring long-term socio-economic resilience.

Awards

Dr. Masoumeh Bararzadeh Ledari’s contributions have earned her recognition as an emerging leader in sustainability research. She has been entrusted with key consultancy roles for organizations such as the Food and Agriculture Organization (FAO) and the United Nations Development Programme (UNDP), where her expertise shaped frameworks for climate change adaptation, stakeholder engagement, and natural resource management. She has also played a central role in developing strategies for carbon capture and storage at the Presidential Center for Progress and Development in Iran, marking a milestone in national climate policy. Her selection as a lead researcher in collaborative international projects and her leadership in critical industry-focused sustainability initiatives highlight her standing as a scholar whose work has both academic and practical impact.

Publications

Dr. Masoumeh Bararzadeh Ledari has authored influential articles that have appeared in high-impact journals and are widely cited by other scholars. Her works include:

Title: Digitalised circular construction supply chain: An integrated BIM-Blockchain solution
Journal: Automation in Construction
Published on: 2023
Citation: 137

Title: Greening steel industry by hydrogen: Lessons learned for the developing world
Journal: International Journal of Hydrogen Energy
Published on: 2023
Citation: 92

Title: Multi objective planning for sustainable retrofit of educational buildings
Journal: Journal of Building Engineering
Published on: 2019
Citation: 49

Title: Building circularity as a measure of sustainability in the old and modern architecture: A case study of architecture development in the hot and dry climate
Journal: Energy and Buildings
Published on: 2022
Citation: 42

Title: Sustainable hydrogen supply chain development for low-carbon transportation in a fossil-based port region: A case study in a tourism hub
Journal: International Journal of Hydrogen Energy
Published on: 2024
Citation: 28

Title: Water-food-energy-ecosystem nexus model development: Resource scarcity and regional development
Journal: Energy Nexus
Published on: 2023
Citation: 17

Title: Exergy analysis of high-performance cycles for gas turbine with air-bottoming
Journal: Mechanical Engineering Research
Published on: 2012
Citation: 17

Conclusion

Dr. Masoumeh Bararzadeh Ledari exemplifies the qualities of a world-class researcher, combining academic excellence, technical expertise, and global engagement. Her sustained commitment to advancing sustainable energy systems and integrated climate-resource models has produced measurable impacts on both scholarship and industry. By uniting scientific innovation with policy and industrial implementation, she represents the new generation of researchers driving the transition to a more sustainable and resilient future. Her body of work makes her an outstanding candidate for the Best Researcher Award.