Company patents

Genomatica, Inc.

GENOMATICA INC. demonstrates a strong, albeit fluctuating, focus on "Fermentation & Biosynthesis," which constitutes 87.0% of its portfolio, experiencing a significant 40.9% YoY growth in 2025 before a sharp decline so far in 2026. Surprisingly, despite its biotech core, the company shows a notable shift away from materials-related innovation, with "Polymer Synthesis (Polycondensation)" declining by 33.3% in 2025 and "Separation Processes (Filtration, Distillation)" dropping by 100.0% in 2025, suggesting a consolidation of its patent strategy towards core biological processes.

Patent Trend by Technology Area

Yearly patent publications since 2023

Product themes

Product-level themes inferred from filings since 2023, with category chips showing where each theme appears. Select a theme to filter the patents below.

108 US filings (since 2023) · 8 categories · 9 themes

Bio-derived Chemical Production

Methods for producing organic chemicals from biomass or through fermentation processes, often focusing on carbohydrates or fatty acid derivatives for food, health, or industrial applications.

Acyclic / Carbocyclic Compounds
Who else files here? →
80since 2023
+61.1%YoY
Novel Protein & Fermentation Technologies

Methods and compositions for developing new protein sources (e.g., microbial, plant-based blends) or utilizing controlled fermentation processes to create novel food products, improve nutritional profiles, or enhance specific characteristics like texture or flavor.

Foods & Beverages
Who else files here? →
57since 2023
+58.3%YoY
Bioprocess Development for Proteins

Methods and systems for the efficient and scalable production, purification, and formulation of proteins and peptides, including fermentation, chromatography, and cell-based expression systems.

Peptides & Proteins
Who else files here? →
42since 2023
+40.0%YoY
Bioprocess Optimization and Control

Developing advanced bioreactor designs, fermentation strategies, and downstream processing techniques to optimize yield, purity, and efficiency of biotechnological production.

Fermentation & Biosynthesis
Who else files here? →
19since 2023
+20.0%YoY
Industrial Organic Synthesis

Methods and apparatus for the efficient and selective production of organic compounds, including amines, acids, and esters, often involving catalytic or continuous processes and purification steps.

Acyclic / Carbocyclic Compounds
Who else files here? →
17since 2023
-16.7%YoY
Recombinant Host Engineering

Modifying microorganisms, plant cells, or animal cells through genetic engineering to enhance or enable the biosynthesis of target compounds, often involving metabolic pathway engineering.

Fermentation & Biosynthesis
Who else files here? →
12since 2023
-25.0%YoY
Sustainable Polymer Materials

Development and application of polymer compositions designed for reprocessability, recyclability, or incorporating sustainable additives, often featuring reversible bonds or bio-based components.

Polymer Synthesis (Polycondensation)
Who else files here? →
6since 2023
-33.3%YoY
Enzyme Directed Evolution

Identifying novel enzymes or modifying existing enzymes through mutagenesis and directed evolution to improve catalytic activity, substrate specificity, or stability for industrial biotransformations.

Fermentation & Biosynthesis
Who else files here? →
3since 2023
new
Urethane/Urea Polymerization

Methods for synthesizing polyurethanes and polyureas, including non-isocyanate routes, using various monomers, catalysts, and curing agents, often for foams, coatings, or adhesives.

Polymer Synthesis (Polycondensation)
Who else files here? →
3since 2023
n/a

Patents

Showing 171-180 of 209

Page 18 of 21
US 20210241846 A1APPLICATION
G16B5/00

MULTICELLULAR METABOLIC MODELS AND METHODS

Filed:2020-09-11Pub:2021-08-05
Applicant:Genomatica, Inc.

The invention provides a computer readable medium or media, having: (a) a first data structure relating a plurality of reactants to a plurality of reactions from a first cell, each of said reactions comprising a reactant identified as a substrate of the reaction, a reactant identified as a product of the reaction and a stoichiometric coefficient relating said substrate and said product; (b) a second data structure relating a plurality of reactants to a plurality of reactions from a second cell, each of said reactions comprising a reactant identified as a substrate of the reaction, a reactant identified as a product of the reaction and a stoichiometric coefficient relating said substrate and said product; (c) a third data structure relating a plurality of intra-system reactants to a plurality of intra-system reactions between said first and second cells, each of said intra-system reactions comprising a reactant identified as a substrate of the reaction, a reactant identified as a product of the reaction and a stoichiometric coefficient relating said substrate and said product; (d) a constraint set for said plurality of reactions for said first, second and third data structures, and (e) commands for determining at least one flux distribution that minimizes or maximizes an objective function when said constraint set is applied to said first and second data structures, wherein said at least one flux distribution is predictive of a physiological function of said first and second cells. The first, second and third data structures also can include a plurality of data structures. Additionally provided is a method for predicting a physiological function of a multicellular organism. The method includes: (a) providing a first data structure relating a plurality of reactants to a plurality of reactions from a first cell, each of said reactions comprising a reactant identified as a substrate of the reaction, a reactant identified as a product of the reaction and a stoichiometric coefficient relating said substrate and said product; (b) providing a second data structure relating a plurality of reactants to a plurality of reactions from a second cell, each of said reactions comprising a reactant identified as a substrate of the reaction, a reactant identified as a product of the reaction and a stoichiometric coefficient relating said substrate and said product; (c) providing a third data structure relating a plurality of intra-system reactants to a plurality of intra-system reactions between said first and second cells, each of said intra-system reactions comprising a reactant identified as a substrate of the reaction, a reactant identified as a product of the reaction and a stoichiometric coefficient relating said substrate and said product; (d) providing a constraint set for said plurality of reactions for said first, second and third data structures; (e) providing an objective function, and (f) determining at least one flux distribution that minimizes or maximizes an objective function when said constraint set is applied to said first and second data structures, wherein said at least one flux distribution is predictive of a physiological function of said first and second cells.