What is she best known for?
The fields of study Renu Pasricha is best known for:
In the field of Colloidal gold and Silver nanoparticle Renu Pasricha studies Nanoparticle.
Chemical engineering is connected with Metallurgy and Physical chemistry in her research.
Renu Pasricha conducts interdisciplinary study in the fields of Metallurgy and Chemical engineering through her research.
With her scientific publications, her incorporates both Physical chemistry and Organic chemistry.
Her research on Organic chemistry frequently links to adjacent areas such as Reducing agent.
Her Biochemistry study frequently links to other fields, such as Amino acid and In vitro.
Many of her studies on In vitro apply to Biochemistry as well.
Her Nanotechnology study frequently draws connections to other fields, such as Monolayer.
She performs integrative study on Inorganic chemistry and Catalysis in her works.
Her most cited work include:
- Synthesis of Gold Nanotriangles and Silver Nanoparticles Using Aloe vera Plant Extract (1701 citations)
- Bioreduction of chloroaurate ions by geranium leaves and its endophytic fungus yields gold nanoparticles of different shapes (791 citations)
- Nitrate reductase-mediated synthesis of silver nanoparticles from AgNO3 (518 citations)
What are the main themes of her work throughout her whole career to date
Her Organic chemistry research overlaps with other disciplines such as Catalysis, Inorganic chemistry and Physical chemistry.
She undertakes multidisciplinary studies into Catalysis and Nanoparticle in her work.
Renu Pasricha undertakes multidisciplinary studies into Nanoparticle and Colloidal gold in her work.
She merges many fields, such as Physical chemistry and Organic chemistry, in her writings.
Her Monolayer research extends to Nanotechnology, which is thematically connected.
Her Chemical engineering study often links to related topics such as Transmission electron microscopy.
Many of her studies on Transmission electron microscopy apply to Chemical engineering as well.
The study of Metallurgy is intertwined with the study of Oxide in a number of ways.
Oxide is frequently linked to Metallurgy in her study.
Renu Pasricha most often published in these fields:
- Nanotechnology (80.15%)
- Organic chemistry (61.83%)
- Chemical engineering (61.83%)
What were the highlights of her more recent work (between 2017-2022)?
- Organic chemistry (64.29%)
- Nanotechnology (57.14%)
- Covalent bond (35.71%)
In recent works Renu Pasricha was focusing on the following fields of study:
Colorectal cancer, Suppressor and Cancer cell are the subject areas of her Cancer study.
While working in this field, she studies both Colorectal cancer and Cancer.
Her Gene research extends to the thematically linked field of Suppressor.
Renu Pasricha integrates Gene and Actin in her research.
In most of her Actin studies, her work intersects topics such as Cell biology.
Many of her studies involve connections with topics such as Mitochondrion and Cell biology.
Mitochondrion and Cell are two areas of study in which Renu Pasricha engages in interdisciplinary work.
As part of her studies on Cell, Renu Pasricha frequently links adjacent subjects like Internalization.
Cancer cell is closely attributed to Internal medicine in her research.
Between 2017 and 2022, her most popular works were:
- pH-responsive high stability polymeric nanoparticles for targeted delivery of anticancer therapeutics (115 citations)
- Covalent organic nanosheets for bioimaging (66 citations)
- Covalent Organic Framework Embedded with Magnetic Nanoparticles for MRI and Chemo-Thermotherapy (63 citations)
In her most recent research, the most cited works focused on:
Nanotechnology and Biophysics are two areas of study in which Renu Pasricha engages in interdisciplinary research.
Renu Pasricha undertakes interdisciplinary study in the fields of Biophysics and Pharmacology through her research.
Renu Pasricha integrates several fields in her works, including Pharmacology and Biotechnology.
Her studies link In vivo with Biotechnology.
In her works, she conducts interdisciplinary research on In vivo and In vitro.
Her PLGA research extends to In vitro, which is thematically connected.
Her study connects Nanotechnology and PLGA.
She applies her multidisciplinary studies on Organic chemistry and Combinatorial chemistry in her research.
In her articles, she combines various disciplines, including Combinatorial chemistry and Organic chemistry.
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