Computer‐aided biochemical programming of synthetic microreactors as diagnostic devices

Biological systems have evolved efficient sensing and decision‐making mechanisms to maximize fitness in changing molecular environments. Synthetic biologists have exploited these capabilities to engineer control on information and energy processing in living cells. While engineered organisms pose im...

Celý popis

Uloženo v:
Podrobná bibliografie
Vydáno v:Molecular systems biology Ročník 14; číslo 4; s. e7845 - n/a
Hlavní autoři: Courbet, Alexis, Amar, Patrick, Fages, François, Renard, Eric, Molina, Franck
Médium: Journal Article
Jazyk:angličtina
Vydáno: London Nature Publishing Group UK 01.04.2018
EMBO Press
John Wiley and Sons Inc
Springer Nature
Témata:
Assembling
Automation
biochemical programming
Biochemistry
Bioinformatics
Biological evolution
Biomarkers
Bioreactors
Biosensing Techniques
Biosensors
Boolean algebra
Circuit design
Circuits
Computation
computational biochemical circuit design
Computer applications
Computer Science
Data processing
Decision making
Diabetes
Diabetes mellitus
Diagnosis
Diagnostic systems
diagnostics
Embedding
EMBO33
EMBO41
Encapsulation
Ethics
Fitness
Gene Regulatory Networks - genetics
Humans
Information processing
Information systems
Logic circuits
Microfluidics
Microreactors
Parameter identification
Phospholipids
Programming
Specifications
synthetic biochemical logic circuits
Synthetic Biology
synthetic microreactors
Temporal logic
Workflow
biochemical programming
diagnostics
synthetic biochemical logic circuits
computational biochemical circuit design
synthetic microreactors
ISSN:1744-4292, 1744-4292
On-line přístup:Získat plný text
Tagy: Přidat tag
Žádné tagy, Buďte první, kdo vytvoří štítek k tomuto záznamu!
Popis
Shrnutí:Biological systems have evolved efficient sensing and decision‐making mechanisms to maximize fitness in changing molecular environments. Synthetic biologists have exploited these capabilities to engineer control on information and energy processing in living cells. While engineered organisms pose important technological and ethical challenges, de novo assembly of non‐living biomolecular devices could offer promising avenues toward various real‐world applications. However, assembling biochemical parts into functional information processing systems has remained challenging due to extensive multidimensional parameter spaces that must be sampled comprehensively in order to identify robust, specification compliant molecular implementations. We introduce a systematic methodology based on automated computational design and microfluidics enabling the programming of synthetic cell‐like microreactors embedding biochemical logic circuits, or protosensors , to perform accurate biosensing and biocomputing operations in vitro according to temporal logic specifications. We show that proof‐of‐concept protosensors integrating diagnostic algorithms detect specific patterns of biomarkers in human clinical samples. Protosensors may enable novel approaches to medicine and represent a step toward autonomous micromachines capable of precise interfacing of human physiology or other complex biological environments, ecosystems, or industrial bioprocesses. Synopsis A systematic approach is presented to design and encapsulate biochemical logic circuits within synthetic phospholipid bilayers that operate as synthetic microreactors. As proof‐of‐concept, such devices were programmed to detect specific patterns of metabolic biomarkers for the diagnosis of diabetes. We introduce the first complete workflow based on computational design and microfluidics for the programming of synthetic cell‐like microreactors using biochemical logic circuits, to perform biosensing and biocomputing operations in vitro . For the first time we show that the implementation of Boolean logic circuits with reactive biochemical species can be automated to satisfy user defined temporal logic specifications and their behavior optimized for robustness. We demonstrate the programming, synthesis and operability of three different instances of synthetic biochemical logic circuits encapsulated within synthetic phospholipid bilayers. Using these methodologies, we generate proof‐of‐concept diagnostic microreactors, or protosensors, biochemically programmed to detect specific patterns of biomarkers and classify pathological states in situ . We demonstrate their capabilities for the diagnosis of acute diabetes complications in human clinical samples. Graphical Abstract A systematic approach is presented to design and encapsulate biochemical logic circuits within synthetic phospholipid bilayers that operate as synthetic microreactors. As proof‐of‐concept, such devices were programmed to detect specific patterns of metabolic biomarkers for the diagnosis of diabetes.
Bibliografie:ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 14
content type line 23
ISSN:1744-4292
1744-4292
DOI:10.15252/msb.20177845