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biocatalyse

Biocatalysis, or biocatalyse, is the use of natural catalysts—primarily enzymes, and sometimes whole cells—to accelerate chemical transformations. Enzymes confer high chemo-, regio-, and enantioselectivity under mild conditions, often in aqueous solution at ambient temperature and pressure. Biocatalysts can be isolated enzymes, whole-cell catalysts, or engineered variants designed to enhance activity, stability, or substrate scope.

The field encompasses a range of reaction types, including hydrolysis and condensation by hydrolases, redox transformations

Industrial use is driven by advantages over traditional chemistry: high selectivity reduces purification burdens, reactions often

Optimization methods include protein engineering (directed evolution and rational design) to improve stability or broaden substrate

by
oxidoreductases,
carbon–carbon
and
carbon–nitrogen
bond
modifications
by
lyases
and
transferases,
and
C–H
functionalization
by
oxidases
or
monooxygenases.
Many
processes
exploit
enzyme
specificity
to
produce
chiral
building
blocks,
vitamins,
fragrances,
and
pharmaceutical
intermediates.
Cofactor-dependent
reactions
are
common,
with
strategies
such
as
cofactor
recycling
enabling
economical
processes.
proceed
under
mild,
aqueous
conditions,
and
the
processes
can
be
more
sustainable
with
lower
waste.
Biocatalysis
is
widely
applied
in
pharmaceutical
manufacturing,
agrochemicals,
food
and
feed,
and
fine
chemicals,
and
is
increasingly
integrated
with
chemical
steps
in
chemoenzymatic
cascades
and
flow
processes.
scope,
and
enzyme
immobilization
or
reactor
design
to
enable
reuse
and
continuous
operation.
Limitations
include
substrate
range,
enzyme
stability
under
process
conditions,
scale-up
challenges,
and
cofactor
requirements
for
certain
enzymes.
Advances
in
genomics,
structural
biology,
and
computational
design
continue
to
expand
its
capabilities.