Welcome to the Science Summit at the United Nations General Assembly (UNGA77)
Please Register by clicking HERE Registration is free of charge. You can register yourself and also other colleagues (up to 10 people).
After you have registered, you will receive two emails: one from Eventbrite with your ticket, and 15 min later, one from SCHED inviting you to create your username and password (these will be your SCHED login details to access the conference each time).
Once you have your SCHED login details, you can select the session(s) you would like to attend and be able to see the ZOOM link to join your selected sessions.
All times in the AGENDA are New York Local (Eastern Daylight Time (EDT)). To view times in another time zone, please use the "Timezone" box located below on the right.
Global bio-foundry Alliance (GBA) has been established between countries including the UK, US, Japan, Singapore, China, Australia, Denmark, and Canada through 16 research institutions. Global bio-foundry Alliance plays a key role in the synthetic biology drive towards a new global bioeconomy that is accelerated by advanced technological innovation. The establishment of the Biofoundry program in South Africa and Africa will plan key scientific and strategic role in promoting synthetic biology and precision medicine program in Africa. This would further enable bioeconomy and industrial development towards SME program. At our CSIR Synthetic Biology and Precision Medicine Centre, we are currently establishing biofoundry lab that will implement various synthetic biology and precision medicine projects in South Africa.
We are currently establishing two research components in the CSIR Synthetic Biology and Precision Medicine Centre Bio-foundry program, which includes industrial synthetic biology and a functional precision medicine program. We implement Biofoundry biodesign and biological engineering Design-Build-Test-Learn (DBTL) cycle into our industrial synthetic biology and functional precision medicine program. In our Industrial synthetic biology program, we are working on a) ValitaCHO: Development of superior CHO cell line system for hyper-burst protein expression system using directed evolution and synthetic biology approaches; b) Lactochassis: Designer microbes for industrial synthetic biology platform applications; In our Cancer Precision Medicine program: we are working on drug repurposing based drug sensitivity screening platform for B-cell malignancies and ovarian cancer treatment for South African patient cohort.
Results: We are currently at the Design phase of the Design-Build-Test-Learn (DBTL) cycle in our industrial synthetic biology and functional precision medicine program. We have so far progressed in the generation of the preliminary data on ValitaCHO cell-line chemstress fingerprinting profiling. We are currently designing the directed evolution approach for the generation superior CHO cell line. In the Lactochassis project, we are currently designing the computational biology-based genome mapping for Lactochassis. In our precision medicine platform, we are currently progressing in the design and build phase of a platform where we have currently procured 770 cancer drugs for drug repurposing platform, which can be applied to blood and ovarian cancer cohort. Conclusion: Using Bio-design DBTL cycle, we aim to implement our industrial synthetic biology and cancer precision medicine platform at CSIR Synthetic Biology and Precision Medicine Centre. These platforms will enable the establishment of one of the first Biofoundry labs in Africa