Opentrons Integration
Overview
Opentrons is a Python-based lab automation platform for Flex and OT-2 robots. Write Protocol API v2 protocols for liquid handling, control hardware modules (heater-shaker, thermocycler), manage labware, for automated pipetting workflows.
When to Use This Skill
This skill should be used when:
- Writing Opentrons Protocol API v2 protocols in Python
- Automating liquid handling workflows on Flex or OT-2 robots
- Controlling hardware modules (temperature, magnetic, heater-shaker, thermocycler)
- Setting up labware configurations and deck layouts
- Implementing complex pipetting operations (serial dilutions, plate replication, PCR setup)
- Managing tip usage and optimizing protocol efficiency
- Working with multi-channel pipettes for 96-well plate operations
- Simulating and testing protocols before robot execution
Core Capabilities
1. Protocol Structure and Metadata
Every Opentrons protocol follows a standard structure:
from opentrons import protocol_api
# Metadata
metadata = {
'protocolName': 'My Protocol',
'author': 'Name <email@example.com>',
'description': 'Protocol description',
'apiLevel': '2.19' # Use latest available API version
}
# Requirements (optional)
requirements = {
'robotType': 'Flex', # or 'OT-2'
'apiLevel': '2.19'
}
# Run function
def run(protocol: protocol_api.ProtocolContext):
# Protocol commands go here
pass
Key elements:
- Import
protocol_apifromopentrons - Define
metadatadict with protocolName, author, description, apiLevel - Optional
requirementsdict for robot type and API version - Implement
run()function receivingProtocolContextas parameter - All protocol logic goes inside the
run()function
2. Loading Hardware
Loading Instruments (Pipettes):
def run(protocol: protocol_api.ProtocolContext):
# Load pipette on specific mount
left_pipette = protocol.load_instrument(
'p1000_single_flex', # Instrument name
'left', # Mount: 'left' or 'right'
tip_racks=[tip_rack] # List of tip rack labware objects
)
Common pipette names:
- Flex:
p50_single_flex,p1000_single_flex,p50_multi_flex,p1000_multi_flex - OT-2:
p20_single_gen2,p300_single_gen2,p1000_single_gen2,p20_multi_gen2,p300_multi_gen2
Loading Labware:
# Load labware directly on deck
plate = protocol.load_labware(
'corning_96_wellplate_360ul_flat', # Labware API name
'D1', # Deck slot (Flex: A1-D3, OT-2: 1-11)
label='Sample Plate' # Optional display label
)
# Load tip rack
tip_rack = protocol.load_labware('opentrons_flex_96_tiprack_1000ul', 'C1')
# Load labware on adapter
adapter = protocol.load_adapter('opentrons_flex_96_tiprack_adapter', 'B1')
tips = adapter.load_labware('opentrons_flex_96_tiprack_200ul')
Loading Modules:
# Temperature module
temp_module = protocol.load_module('temperature module gen2', 'D3')
temp_plate = temp_module.load_labware('corning_96_wellplate_360ul_flat')
# Magnetic module
mag_module = protocol.load_module('magnetic module gen2', 'C2')
mag_plate = mag_module.load_labware('nest_96_wellplate_100ul_pcr_full_skirt')
# Heater-Shaker module
hs_module = protocol.load_module('heaterShakerModuleV1', 'D1')
hs_plate = hs_module.load_labware('corning_96_wellplate_360ul_flat')
# Thermocycler module (takes up specific slots automatically)
tc_module = protocol.load_module('thermocyclerModuleV2')
tc_plate = tc_module.load_labware('nest_96_wellplate_100ul_pcr_full_skirt')
3. Liquid Handling Operations
Basic Operations:
# Pick up tip
pipette.pick_up_tip()
# Aspirate (draw liquid in)
pipette.aspirate(
volume=100, # Volume in µL
location=source['A1'] # Well or location object
)
# Dispense (expel liquid)
pipette.dispense(
volume=100,
location=dest['B1']
)
# Drop tip
pipette.drop_tip()
# Return tip to rack
pipette.return_tip()
Complex Operations:
# Transfer (combines pick_up, aspirate, dispense, drop_tip)
pipette.transfer(
volume=100,
source=source_plate['A1'],
dest=dest_plate['B1'],
new_tip='always' # 'always', 'once', or 'never'
)
# Distribute (one source to multiple destinations)
pipette.distribute(
volume=50,
source=reservoir['A1'],
dest=[plate['A1'], plate['A2'], plate['A3']],
new_tip='once'
)
# Consolidate (multiple sources to one destination)
pipette.consolidate(
volume=50,
source=[plate['A1'], plate['A2'], plate['A3']],
dest=reservoir['A1'],
new_tip='once'
)
Advanced Techniques:
# Mix (aspirate and dispense in same location)
pipette.mix(
repetitions=3,
volume=50,
location=plate['A1']
)
# Air gap (prevent dripping)
pipette.aspirate(100, source['A1'])
pipette.air_gap(20) # 20µL air gap
pipette.dispense(120, dest['A1'])
# Blow out (expel remaining liquid)
pipette.blow_out(location=dest['A1'].top())
# Touch tip (remove droplets on tip exterior)
pipette.touch_tip(location=plate['A1'])
Flow Rate Control:
# Set flow rates (µL/s)
pipette.flow_rate.aspirate = 150
pipette.flow_rate.dispense = 300
pipette.flow_rate.blow_out = 400
4. Accessing Wells and Locations
Well Access Methods:
# By name
well_a1 = plate['A1']
# By index
first_well = plate.wells()[0]
# All wells
all_wells = plate.wells() # Returns list
# By rows
rows = plate.rows() # Returns list of lists
row_a = plate.rows()[0] # All wells in row A
# By columns
columns = plate.columns() # Returns list of lists
column_1 = plate.columns()[0] # All wells in column 1
# Wells by name (dictionary)
wells_dict = plate.wells_by_name() # {'A1': Well, 'A2': Well, ...}
Location Methods:
# Top of well (default: 1mm below top)
pipette.aspirate(100, well.top())
pipette.aspirate(100, well.top(z=5)) # 5mm above top
# Bottom of well (default: 1mm above bottom)
pipette.aspirate(100, well.bottom())
pipette.aspirate(100, well.bottom(z=2)) # 2mm above bottom
# Center of well
pipette.aspirate(100, well.center())
5. Hardware Module Control
Temperature Module:
# Set temperature
temp_module.set_temperature(celsius=4)
# Wait for temperature
temp_module.await_temperature(celsius=4)
# Deactivate
temp_module.deactivate()
# Check status
current_temp = temp_module.temperature # Current temperature
target_temp = temp_module.target # Target temperature
Magnetic Module:
# Engage (raise magnets)
mag_module.engage(height_from_base=10) # mm from labware base
# Disengage (lower magnets)
mag_module.disengage()
# Check status
is_engaged = mag_module.status # 'engaged' or 'disengaged'
Heater-Shaker Module:
# Set temperature
hs_module.set_target_temperature(celsius=37)
# Wait for temperature
hs_module.wait_for_temperature()
# Set shake speed
hs_module.set_and_wait_for_shake_speed(rpm=500)
# Close labware latch
hs_module.close_labware_latch()
# Open labware latch
hs_module.open_labware_latch()
# Deactivate heater
hs_module.deactivate_heater()
# Deactivate shaker
hs_module.deactivate_shaker()
Thermocycler Module:
# Open lid
tc_module.open_lid()
# Close lid
tc_module.close_lid()
# Set lid temperature
tc_module.set_lid_temperature(celsius=105)
# Set block temperature
tc_module.set_block_temperature(
temperature=95,
hold_time_seconds=30,
hold_time_minutes=0.5,
block_max_volume=50 # µL per well
)
# Execute profile (PCR cycling)
profile = [
{'temperature': 95, 'hold_time_seconds': 30},
{'temperature': 57, 'hold_time_seconds': 30},
{'temperature': 72, 'hold_time_seconds': 60}
]
tc_module.execute_profile(
steps=profile,
repetitions=30,
block_max_volume=50
)
# Deactivate
tc_module.deactivate_lid()
tc_module.deactivate_block()
Absorbance Plate Reader:
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