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About Rice University
Founded in--
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HeadquartersHouston, United States
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Websiterice.edu
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|---|---|---|---|---|
Overall Rating | - based on 0 reviews | 4.2/5 based on 1k reviews | 3.4/5 based on 3.3k reviews | 3.9/5 based on 1.4k reviews |
Highly Rated for | - | Skill development Job security Work-life balance | No highly rated category | Skill development Work-life balance Salary |
Critically Rated for | - | No critically rated category | Work-life balance Promotions Job security | No critically rated category |
Primary Work Policy | - | Work from office 94% employees reported | Work from office 87% employees reported | Work from office 97% employees reported |
Rating by Women Employees | - no rating available | 4.3 Good rated by 410 women | 3.5 Good rated by 900 women | 4.0 Good rated by 763 women |
Rating by Men Employees | - no rating available | 4.1 Good rated by 586 men | 3.4 Average rated by 2.2k men | 3.9 Good rated by 561 men |
Job security | - Data not available | 4.1 Good | 3.1 Average | 3.7 Good |
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Rice University Salaries
Postdoctoral Associate
(1 salaries)
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₹33.7 L/yr - ₹43 L/yr
Director
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₹21.6 L/yr - ₹27.6 L/yr
Postdoctoral Research Associate
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₹42.3 L/yr - ₹54.1 L/yr
Rice University News
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Rice University’s Gustavsson Honored with NSF CAREER Award to Explore Gene Regulation Dynamics
- Rice University’s assistant professor Anna-Karin Gustavsson has been honored with a National Science Foundation (NSF) CAREER Award to advance her research on gene regulation dynamics, receiving a grant of $788,823.
- Gustavsson aims to develop innovative techniques for visualizing, quantifying, and analyzing DNA organization and interactions in real time, potentially revolutionizing our understanding of genetic behaviors crucial for various biological processes.
- Her research focuses on deciphering the arrangement of DNA within cells and understanding gene regulation mechanisms, including how the three-dimensional structure of DNA impacts gene expression and its implications for diseases.
- With a background in chemistry and as a Cancer Prevention and Research Institute of Texas Scholar, Gustavsson intends to pave the way for novel therapeutic strategies addressing gene regulation issues in diseases.
- She plans to develop advanced 3D nanoscale imaging techniques to observe genomic elements like enhancers and promoters with high resolution, aiming to shed light on how these components interact and influence gene expression.
- Through her research, Gustavsson also focuses on educational outreach, engaging high school teachers and students in the Houston Independent School District to foster interest in science and inspire future scientists.
- With a strong background in biophysics and nanoscale imaging, Gustavsson's work aims to enhance our understanding of cellular structures and dynamics linked to diseases resulting from genetic abnormalities.
- Recognized for her contributions to science with various awards, Gustavsson's NSF CAREER Award acknowledges her potential for transformative research in gene regulation, offering promise for advancements in molecular biology and genetics.
- This prestigious award underscores the importance of combining research excellence with educational initiatives, highlighting Gustavsson's commitment to advancing knowledge and inspiring the next generation of scientists.
- As Gustavsson embarks on her research journey, supported by the NSF CAREER Award, her cutting-edge imaging technology and multidisciplinary approach are poised to unravel critical insights in gene regulation dynamics, potentially reshaping scientific paradigms.
- This recognition not only validates Gustavsson's scientific endeavors but also signifies the significant impact her research may have on biology and medicine, paving the way for fundamental discoveries in the field of gene regulation.
Bioengineer | 4 Mar, 2025
Revolutionary Lithium Extraction Method Paves the Way for Sustainable EV Battery Supply Chains, Say Rice Researchers
- A team of researchers from Rice University, led by Menachem Elimelech, has developed a revolutionary method for lithium harvesting using solid-state electrolytes to address the surging global demand for lithium, particularly in electric vehicles and renewable energy technologies.
- This innovative approach promises to improve the sustainability and efficiency of lithium extraction compared to traditional methods that rely on environmentally damaging practices or inefficient chemical processes.
- By employing solid-state electrolytes as membrane materials, the research team achieved remarkable selectivity in separating lithium ions from aqueous solutions, surpassing the limitations of conventional membrane technologies.
- The method showcased exceptional lithium selectivity even in the presence of competing ions like sodium and magnesium, offering a more environmentally friendly and efficient extraction process.
- The use of solid-state electrolytes in lithium extraction represents a significant step towards greener technologies, reducing waste loads and energy expenditure associated with current practices.
- Experiments using electrodialysis setups demonstrated the effectiveness of the method, highlighting its potential scalability and practicality in real-world settings.
- The research team combined computational and experimental approaches to understand the principles behind solid-state electrolytes' unrivaled selectivity in lithium extraction, paving the way for broader applications in resource recovery.
- The findings offer insights into challenges faced by direct lithium extraction technologies and signal a promising future for sustainable lithium production and environmental stewardship.
- The application of solid-state electrolytes in aqueous lithium extraction not only improves lithium production but also hints at opportunities for recovering other valuable elements, promoting resource sustainability.
- The ongoing research exemplifies the transformative potential of interdisciplinary collaborations and innovative technologies in reshaping the landscape of resource management towards a more sustainable and resilient future.
Bioengineer | 1 Mar, 2025
Rice University Study Reveals Enhanced Cancer Treatment Through Focused Ultrasound Therapy
- Collaborative research between Rice University and Vanderbilt University has discovered a new approach to cancer treatment involving TRAIL therapy and focused ultrasound, showing promise in diminishing tumor size in prostate cancer models.
- TRAIL therapy is known for inducing cancer cell death, but its efficacy is limited by rapid degradation, leading to the exploration of low-intensity focused ultrasound to enhance its effects.
- FUS activates Piezo1, triggering cellular events that result in cancer cell apoptosis while preserving healthy tissues, representing a significant advancement in prostate cancer therapy.
- By combining TRAIL and FUS, researchers achieved superior results in reducing tumor volume and cellular proliferation compared to individual treatments.
- The study offers a non-invasive therapeutic avenue for advanced prostate cancer, addressing the critical need for innovative treatments in the second-leading cause of cancer-related deaths among men in the U.S.
- The implications of this research extend beyond prostate cancer, hinting at the broader application of mechanotherapy across various cancer types and the potential for personalized cancer care.
- Interdisciplinary collaboration between bioengineering and radiological sciences proved instrumental in advancing cancer therapy and may inspire further innovative research efforts in oncology.
- This groundbreaking study paves the way for an innovative therapeutic strategy, redefining treatment paradigms in oncology with enhanced anticancer efficacy and non-invasive methodology.
- Funded by grants from the NIH and NSF, this research underscores the evolving landscape of cancer treatment, emphasizing the importance of continued innovation in therapeutic approaches.
- Keywords: TRAIL therapy, focused ultrasound, prostate cancer, cancer treatment, apoptosis, mechanotherapy, synergistic effect, innovative research, non-invasive therapy, cancer mortality, therapeutic strategies, biomedical engineering.
- Tags: advancements in cancer care, collaborative cancer research initiatives, enhancing TRAIL efficacy with ultrasound, focused ultrasound therapy for tumors, improving patient outcomes in prostate cancer, innovative cancer treatment methods, non-invasive cancer therapies, overcoming TRAIL therapy limitations, prostate cancer research breakthroughs, Rice University cancer treatment study, TRAIL therapy in prostate cancer, tumor reduction techniques.
Bioengineer | 22 Feb, 2025
Transforming Setbacks into Success: Rice Researchers Pioneer Advanced Wearable Technology
- Researchers at Rice University have pioneered advanced wearable technology through innovative approaches to sheet-based fluidic devices, redefining lightweight and flexible technologies.
- By embracing failure as a functional aspect of design, they have created smarter and more adaptive systems, showcasing programmed failure for enhanced functionality.
- Their fluidic devices operate under pressure and feature a 'fluidic fuse' that protects the system from damage by breaking under threshold pressure, enhancing sustainability.
- The research resulted in easily programmable devices capable of performing complex tasks through controlled failure processes, revolutionizing robotics and wearables.
- These innovations have wide applications in wearable technology, adaptive robotics, rehabilitation, and haptic feedback communication systems.
- The fluidic systems offer adaptable solutions without complex electronic control, streamlining design processes for multifunctional autonomous systems.
- The team's approach to engineering failure signals a transformative shift in material science and engineering disciplines, inspiring future innovations.
- The balance between failure and functionality in these fluidic devices opens up new possibilities in soft robotics and wearables.
- The research at Rice University marks a significant advancement where failure is seen as an opportunity for technological progress rather than a setback.
- Their work signifies a new era in technology construction and interaction, showcasing the power of embracing and leveraging failure for innovation.
Bioengineer | 19 Feb, 2025
Scientists create advanced sense-and-respond systems that mimic natural cellular behavior
- Protein phosphorylation is crucial for cellular communication, enabling rapid responses to environmental cues.
- Researchers at Rice University have developed modular phosphorylation circuits in human cells for therapeutic applications.
- Phosphorylation, adding a phosphate group to proteins, plays a vital role in cellular functions like movement and gene expression.
- The team reimagined phosphorylation cycles as modular units to create novel circuits without disrupting cell viability.
- Synthetic kinases and substrates were engineered to selectively phosphorylate proteins in human cells.
- The modular system allows bidirectional control and accurate prediction of phosphorylation behavior across various circuit compositions.
- Synthetic phosphorylation circuits integrated with gene expression provide real-time responses to external signals.
- These circuits show promise in detecting inflammatory markers and regulating autoimmune responses for precision medicine.
- The work advances synthetic biology by creating smart cells capable of rapid functional changes in response to specific signals.
- Synthetic phosphorylation circuits offer customizable and scalable cellular therapies with therapeutic and biosensing applications.
Brighter Side of News | 17 Feb, 2025
Revolutionary Gene-Editing Advance at Rice University Paves the Way for Enhanced Liver Disease Treatments and Beyond
- Rice University researchers have developed a cutting-edge gene-editing technique called Repair Drive, revolutionizing liver-targeted gene therapies and potentially expanding to other organs.
- Repair Drive significantly boosts the success rate of repairing liver cells, leading to improved liver regeneration and cell division in murine liver models.
- The method utilizes small interfering RNA (siRNA) to suppress the FAH gene temporarily and introduce therapeutic genes to enable only gene-edited cells to thrive and propagate.
- Gang Bao, a key figure in bioengineering at Rice University, highlights the importance of precision in gene editing and collaboration for scientific advancements.
- The collaborative efforts between Rice University and partners aim to enhance CRISPR/Cas9 techniques for more accurate and safe gene editing in diverse genetic disorders.
- The extensive research team, including members from various institutions, underscores the collective effort and expertise required for breakthroughs in gene therapy.
- Financial support from reputable organizations like the National Institutes of Health emphasizes the significant impact of this gene-editing research on public health.
- With pending patent applications, the commercial potential of Repair Drive technology presents opportunities for partnerships and advancements in medical treatment.
- The findings pave the way for enhanced gene therapies targeting liver disorders, showcasing the transformative potential of gene therapy and regenerative medicine.
- Collaboration and innovation remain crucial in advancing effective treatments for genetic disorders, holding promise for groundbreaking solutions that could revolutionize healthcare.
Bioengineer | 14 Feb, 2025
Rice University Researchers Unveil Innovative Approach to Tailor Living Materials for Tissue Engineering, Drug Delivery, and 3D Printing
- Rice University has made a groundbreaking advancement in engineered living materials (ELMs).
- The ELMs allow for enhanced customization through genetic engineering.
- The structure and mechanical responses of ELMs have previously been challenging to control.
- Protein matrices play a crucial role in shaping the structural integrity of ELMs.
- The technique is beneficial for several applications, including tissue engineering, drug delivery, and 3D printing.
- Engineered to produce a specific protein termed BUD, Caulobacter crescentus was an important part of the study.
- The research team varied the length of elastin-like polypeptides (ELPs) and created several new materials.
- The variations were found to possess specific mechanical properties that are useful in different applications.
- The research demonstrated that the self-assembling nature of these engineered living materials is useful in diverse environmental and technological sectors.
- The research was supported by funding from esteemed institutions such as the Welch Foundation and the National Science Foundation Graduate Research Fellowship.
Bioengineer | 6 Feb, 2025
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Rice University is headquartered in Houston.
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