4bdc_9093
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Lysozyme digests gram-positive bacterial cell walls. Microfluidizer Z-shaped chamber and pump create high pressure to disrupt cells. French Press Cells are forced through a tiny hole by a high-pressure hydraulic piston. Mechanical Homogenizer Consists of a fast-spinning inner rotor with a stationary outer stator to produce shearing forces. MAT4bdc_5db9
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Freeze-thaw Cold temperatures form ice crystals, which expand, ultimately causing the cell wall to rupture. Mechanical Homogenizer Motorized device with rotating blades that shear cells apart. Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. Sonication This technique applies high-frequency sound waves to shatter cells. MAT4bdc_2fb8
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Bead-beating This technique involves using glass or metal particles to apply gentle abrasion while vortexing them. Enzymatic Method Lysozyme is commonly used to digest the cell wall of gram-positive bacteria. Sonication High-frequency sound waves produce tiny bubbles that explode, producing a local shockwave. Microfluidizer A high-pressure pump pushes cells through a Z-shaped interaction chamber. MAT4bdc_7bb1
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
French Press Cells are pushed through a small hole using high pressure from a hydraulic piston. High-throughput Homogenizer An expensive bead-beating machine can process a large number of samples simultaneously in a short time. Mortar & Pestle Manual grinding of cells that can take several minutes." Enzymatic Method Cells wall digestion by protein catalysts. MAT4bdc_7656
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Freeze-thaw This technique uses extremely cold temperatures and grinding to pulverize cells. Bead-beating Glass or ceramic particles stirred at high speeds crack cells open. Mechanical Homogenizer Consists of a fast-spinning inner rotor with a stationary outer stator to produce shearing forces. Sonication This technique uses short bursts of ultrasonic waves to disrupt the tissue. MAT4bdc_4bbf
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mechanical Homogenizer Shearing forces from spinning blades break cells apart. French Press Cell suspension is forced through a narrow valve using a hydraulic piston. Mortar & Pestle Samples are ground by hand to break apart into small pieces. Bead-beating This technique involves using glass or metal particles to apply gentle abrasion while vortexing them. MAT4bdc_5a7f
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Sonication Ultrasonic sound energy is used to cause air bubbles in a liquid to implode, damaging the cells. Freeze-thaw Under cold temperatures, the water inside the cells expands into ice, causing the cells to burst open. French Press A hydraulic piston within a cylinder forces cells through a small hole using high pressure. Mechanical Homogenizer Motorized device with rotating blades that shear cells apart. MAT4bdc_73e3
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mortar & Pestle This is laborious manual work that can take several minutes. Microfluidizer Z-shaped chamber and pump create high pressure to disrupt cells. Mechanical Homogenizer Consists of a fast-spinning inner rotor with a stationary outer stator to produce shearing forces. Freeze-thaw Cells are pulverized through a combination of extreme cold. MAT4bdc_79af
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
French Press A hydraulic press drives a piston to squeeze the sample through a needle valve. Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. Microfluidizer High pressures are generated using a Z-shaped chamber and a pump. Mechanical Homogenizer Drill-like device with spinning rotor blades to shear cells apart. MAT4bdc_b5ee
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Chemical reactions digest the cell wall. Sonication High-frequency sound waves cause disruption of cells by shear force and tension. Bead-beating This technique involves using glass or metal particles to apply gentle abrasion while vortexing them. French Press A hydraulic piston within a cylinder forces cells through a small hole using high pressure. MAT4bdc_d900
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Sonication This technique uses the forces of ultrasonic waves to rupture cells. Mortar & Pestle Manual grinding of cells that can take several minutes." Freeze-thaw Cell suspensions are subjected to variable temperatures, resulting in rupture of the walls. Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. MAT4bdc_38b5
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mortar & Pestle Samples are ground by hand to break apart into small pieces. Enzymatic Method Cells wall digestion by protein catalysts. Mechanical Homogenizer Drill-like device with spinning rotor blades to shear cells apart. Dounce Homogenizer Handheld device that spins in a tube to smash cells. MAT4bdc_b3ac
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mechanical Homogenizer Consists of a fast-spinning inner rotor with a stationary outer stator to produce shearing forces. Microfluidizer A high-pressure pump pushes cells through a Z-shaped interaction chamber. French Press High-pressure hydraulic piston forces cells through a small hole. Mortar & Pestle Manual grinding of cells that can take several minutes." MAT4bdc_c7c7
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. Microfluidizer Cells are pushed through a Z-shaped chamber using a high-pressure pump. Sonication This technique uses the forces of ultrasonic waves to rupture cells. Mortar & Pestle Samples are ground by hand to break apart into small pieces. MAT4bdc_a826
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. Bead-beating Tiny glass particles are mixed and stirred to a high level of agitation. Sonication Cells are disrupted by the shear force and tension caused by high-frequency sound waves. Microfluidizer A Z-shaped interaction chamber and pump work in tandem to exert high pressures on cells. MAT4bdc_b77c
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mortar & Pestle Manual grinding of cells that can take several minutes." Dounce Homogenizer A spinning handheld device smashes cells in a tube. Microfluidizer A Z-shaped interaction chamber and pump work in tandem to exert high pressures on cells. French Press Cells are forced through a tiny hole by a high-pressure hydraulic piston. MAT4bdc_1658
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Microfluidizer A high-pressure pump pushes cells through a Z-shaped interaction chamber. Mechanical Homogenizer Spinning rotor blades shear the cell walls. Enzymatic Method Cells wall digestion by protein catalysts. Freeze-thaw The cell walls rupture due to extreme temperature variations. MAT4bdc_0225
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mechanical Homogenizer Consists of a fast-spinning inner rotor with a stationary outer stator to produce shearing forces. Freeze-thaw Cold temperatures form ice crystals, which expand, ultimately causing the cell wall to rupture. Sonication This technique applies high-frequency sound waves to shatter cells. Bead-beating Small glass particles are placed into a blender and act like bullets smashing the cells. MAT4bdc_86ba
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Sonication Ultrasonic waves in short bursts are employed to disintegrate tissue. High-throughput Homogenizer Numerous samples are processed simultaneously using a bead-beating machine. Microfluidizer Z-shaped chamber and pump create high pressure to disrupt cells. Freeze-thaw This technique uses extremely cold temperatures and grinding to pulverize cells. MAT4bdc_87d3
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
High-throughput Homogenizer Large numbers of samples are disrupted simultaneously using a bead-beating machine. Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. Mechanical Homogenizer Drill-like device with spinning rotor blades to shear cells apart. Enzymatic Method Lysozyme is commonly used to digest the cell wall of gram-positive bacteria. MAT4bdc_6064
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Dounce Homogenizer Cells are smashed using a spinning handheld device in a tube. French Press Cell suspension is forced through a narrow valve using a hydraulic piston. Sonication Ultrasonic waves rupture cell walls. High-throughput Homogenizer Large numbers of samples are disrupted simultaneously using a bead-beating machine. MAT4bdc_7b85
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
High-throughput Homogenizer Large numbers of samples are disrupted simultaneously using a bead-beating machine. Freeze-thaw Under cold temperatures, the water inside the cells expands into ice, causing the cells to burst open. Mortar & Pestle Manual grinding of cells that can take several minutes." Mechanical Homogenizer Shearing forces from spinning blades break cells apart. MAT4bdc_2cb7
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
French Press Cells are pushed through a small hole using high pressure from a hydraulic piston. Enzymatic Method Digestion of the cell wall by chemical reactions. Mechanical Homogenizer Spinning rotor blades shear the cell walls. Dounce Homogenizer A spinning handheld device smashes cells in a tube. MAT4bdc_79c4
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Cells wall digestion by protein catalysts. Microfluidizer High pressures are generated using a Z-shaped chamber and a pump. Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. Sonication High-frequency sound waves produce tiny bubbles that explode, producing a local shockwave. MAT4bdc_6826
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
French Press Cells are pushed through a small hole using high pressure from a hydraulic piston. Microfluidizer A high-pressure pump pushes cells through a Z-shaped interaction chamber. High-throughput Homogenizer An expensive bead-beating machine can process a large number of samples simultaneously in a short time. Dounce Homogenizer A spinning handheld device smashes cells in a tube. MAT4bdc_c774
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mechanical Homogenizer Shearing forces from spinning blades break cells apart. Sonication This technique uses the forces of ultrasonic waves to rupture cells. French Press Cell suspension is forced through a narrow valve using a hydraulic piston. Microfluidizer A high-pressure pump pushes cells through a Z-shaped interaction chamber. MAT4bdc_828c
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Freeze-thaw The cell walls rupture due to extreme temperature variations. French Press Cells are forced through a tiny hole by a high-pressure hydraulic piston. Dounce Homogenizer Handheld device that spins in a tube to smash cells. High-throughput Homogenizer Large numbers of samples are disrupted simultaneously using a bead-beating machine. MAT4bdc_21d9
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
French Press High-pressure hydraulic piston forces cells through a small hole. Enzymatic Method Cells wall digestion by protein catalysts. Mortar & Pestle Samples are ground by hand to break apart into small pieces. Microfluidizer High pressures are generated using a Z-shaped chamber and a pump. MAT4bdc_5817
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Chemical reactions digest the cell wall. Freeze-thaw Extreme temperature variations cause cell wall rupture. Mechanical Homogenizer Motorized device with rotating blades that shear cells apart. Dounce Homogenizer Handheld device that spins in a tube to smash cells. MAT4bdc_f836
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
French Press Cells are pushed through a small hole using high pressure from a hydraulic piston. Dounce Homogenizer Handheld device that spins in a tube to smash cells. Freeze-thaw Cell suspensions are subjected to variable temperatures, resulting in rupture of the walls. Bead-beating Glass or ceramic particles stirred at high speeds crack cells open. MAT4bdc_85cb
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Microfluidizer Z-shaped chamber and pump create high pressure to disrupt cells. Enzymatic Method Lysozyme digests gram-positive bacterial cell walls. French Press Cells are forced through a tiny hole by a high-pressure hydraulic piston. Bead-beating This technique involves using glass or metal particles to apply gentle abrasion while vortexing them. MAT4bdc_ba2d
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mortar & Pestle Grinding of the cells by hand to disrupt the cell walls. Mechanical Homogenizer Consists of a fast-spinning inner rotor with a stationary outer stator to produce shearing forces. Microfluidizer A high-pressure pump pushes cells through a Z-shaped interaction chamber. Freeze-thaw Cells are pulverized through a combination of extreme cold. MAT4bdc_5576
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Freeze-thaw Extreme temperature variations cause cell wall rupture. Mechanical Homogenizer Drill-like device with spinning rotor blades to shear cells apart. Sonication Shear force from high-frequency waves disrupts cells. Enzymatic Method Cells wall digestion by protein catalysts. MAT4bdc_b407
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mechanical Homogenizer Motorized device with rotating blades that shear cells apart. Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. French Press A hydraulic press drives a piston to squeeze the sample through a needle valve. Bead-beating Glass or ceramic particles stirred at high speeds crack cells open. MAT4bdc_d3d6
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Dounce Homogenizer A spinning handheld device smashes cells in a tube. Mechanical Homogenizer Shearing forces from spinning blades break cells apart. Microfluidizer Cells are pushed through a Z-shaped chamber using a high-pressure pump. High-throughput Homogenizer Numerous samples are processed simultaneously using a bead-beating machine. MAT4bdc_2f0a
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. Sonication High-frequency sound waves produce tiny bubbles that explode, producing a local shockwave. Mortar & Pestle This is laborious manual work that can take several minutes. High-throughput Homogenizer An expensive bead-beating machine can process a large number of samples simultaneously in a short time. MAT4bdc_61ac
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Microfluidizer A Z-shaped interaction chamber and pump work in tandem to exert high pressures on cells. Dounce Homogenizer Handheld device that spins in a tube to smash cells. Mortar & Pestle The cells are disrupted by hand grinding them. High-throughput Homogenizer Large numbers of samples are disrupted simultaneously using a bead-beating machine. MAT4bdc_dc53
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mechanical Homogenizer Spinning rotor blades shear the cell walls. French Press A hydraulic press drives a piston to squeeze the sample through a needle valve. Freeze-thaw Under cold temperatures, the water inside the cells expands into ice, causing the cells to burst open. Bead-beating Tiny glass particles are mixed and stirred to a high level of agitation. MAT4bdc_dc35
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Protein catalysts decompose the microbial cell wall. Microfluidizer A Z-shaped interaction chamber and pump work in tandem to exert high pressures on cells. Mechanical Homogenizer Drill-like device with spinning rotor blades to shear cells apart. Sonication High-frequency sound waves produce tiny bubbles that explode, producing a local shockwave. MAT4bdc_c90f
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Microfluidizer Cells are pushed through a Z-shaped chamber using a high-pressure pump. Mechanical Homogenizer Shearing forces from spinning blades break cells apart. Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. Enzymatic Method Chemical reactions digest the cell wall. MAT4bdc_185f
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Sonication High-frequency sound waves cause disruption of cells by shear force and tension. French Press A hydraulic press drives a piston to squeeze the sample through a needle valve. Bead-beating Glass or ceramic particles stirred at high speeds crack cells open. Mortar & Pestle This is laborious manual work that can take several minutes. MAT4bdc_976c
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
High-throughput Homogenizer An expensive bead-beating machine can process a large number of samples simultaneously in a short time. Dounce Homogenizer A spinning handheld device smashes cells in a tube. Enzymatic Method Chemical reactions digest the cell wall. Mortar & Pestle Samples are ground by hand to break apart into small pieces. MAT4bdc_8116
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mechanical Homogenizer Spinning rotor blades shear the cell walls. Microfluidizer A high-pressure pump pushes cells through a Z-shaped interaction chamber. Dounce Homogenizer Handheld device that spins in a tube to smash cells. High-throughput Homogenizer Numerous samples are processed simultaneously using a bead-beating machine. MAT4bdc_a621
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mortar & Pestle The cells are disrupted by hand grinding them. Dounce Homogenizer A spinning handheld device smashes cells in a tube. French Press Cell suspension is forced through a narrow valve using a hydraulic piston. Microfluidizer A Z-shaped interaction chamber and pump work in tandem to exert high pressures on cells. MAT4bdc_a064
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
High-throughput Homogenizer Large numbers of samples are disrupted simultaneously using a bead-beating machine. Microfluidizer Uses a pump and a Z-shaped interaction chamber to create high pressures. French Press A hydraulic press drives a piston to squeeze the sample through a needle valve. Dounce Homogenizer Handheld device that spins in a tube to smash cells. MAT4bdc_01e9
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Microfluidizer A Z-shaped interaction chamber and pump work in tandem to exert high pressures on cells. Dounce Homogenizer Cells are smashed using a spinning handheld device in a tube. Freeze-thaw This technique uses extremely cold temperatures and grinding to pulverize cells. Enzymatic Method Digestion of the cell wall by chemical reactions. MAT4bdc_210c
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Bead-beating Tiny glass particles are mixed and stirred to a high level of agitation. Microfluidizer A Z-shaped interaction chamber and pump work in tandem to exert high pressures on cells. Freeze-thaw Extreme temperature variations cause cell wall rupture. Mortar & Pestle The cells are disrupted by hand grinding them. MAT4bdc_26cc
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mortar & Pestle Samples are ground by hand to break apart into small pieces. Sonication This technique uses short bursts of ultrasonic waves to disrupt the tissue. Bead-beating Small glass particles are placed into a blender and act like bullets smashing the cells. Dounce Homogenizer A spinning handheld device smashes cells in a tube. MAT4bdc_a74f
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Cells are suspended in buffers containing protein catalysts that digest the cell wall. Microfluidizer A high-pressure pump pushes cells through a Z-shaped interaction chamber. Bead-beating Small glass particles are placed into a blender and act like bullets smashing the cells. Freeze-thaw Under cold temperatures, the water inside the cells expands into ice, causing the cells to burst open. MAT4bdc_2422
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Lysozyme is commonly used to digest the cell wall of gram-positive bacteria. French Press Cells are forced through a tiny hole by a high-pressure hydraulic piston. High-throughput Homogenizer Numerous samples are processed simultaneously using a bead-beating machine. Sonication High-frequency sound waves cause disruption of cells by shear force and tension. MAT4bdc_2ad0
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Digestion of the cell wall by chemical reactions. Mortar & Pestle This is laborious manual work that can take several minutes. Freeze-thaw Under cold temperatures, the water inside the cells expands into ice, causing the cells to burst open. French Press Cells are forced through a tiny hole by a high-pressure hydraulic piston. MAT4bdc_3008
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mortar & Pestle This is laborious manual work that can take several minutes. French Press A hydraulic press drives a piston to squeeze the sample through a needle valve. Dounce Homogenizer Handheld device that spins in a tube to smash cells. Freeze-thaw This technique uses extremely cold temperatures and grinding to pulverize cells. MAT4bdc_d8fe
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Protein catalysts decompose the microbial cell wall. Mechanical Homogenizer Shearing forces from spinning blades break cells apart. Freeze-thaw Cells are pulverized through a combination of extreme cold. Mortar & Pestle Manual grinding of cells that can take several minutes." MAT4bdc_f853
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Dounce Homogenizer A spinning handheld device smashes cells in a tube. Freeze-thaw This technique uses extremely cold temperatures and grinding to pulverize cells. Mortar & Pestle This is laborious manual work that can take several minutes. Microfluidizer A high-pressure pump pushes cells through a Z-shaped interaction chamber. MAT4bdc_ae9a
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Sonication This technique uses short bursts of ultrasonic waves to disrupt the tissue. Mechanical Homogenizer Motorized device with rotating blades that shear cells apart. High-throughput Homogenizer An expensive bead-beating machine can process a large number of samples simultaneously in a short time. Dounce Homogenizer Handheld device that spins in a tube to smash cells. MAT4bdc_0268
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Sonication Shear force from high-frequency waves disrupts cells. High-throughput Homogenizer Numerous samples are processed simultaneously using a bead-beating machine. Enzymatic Method Cells are suspended in buffers containing protein catalysts that digest the cell wall. Mortar & Pestle Samples are ground by hand to break apart into small pieces. MAT4bdc_6976
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
High-throughput Homogenizer An expensive bead-beating machine can process a large number of samples simultaneously in a short time. Mortar & Pestle Manual grinding of cells that can take several minutes." Enzymatic Method Lysozyme is commonly used to digest the cell wall of gram-positive bacteria. Mechanical Homogenizer Consists of a fast-spinning inner rotor with a stationary outer stator to produce shearing forces. MAT4bdc_4fc9
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mechanical Homogenizer Motorized device with rotating blades that shear cells apart. French Press High-pressure hydraulic piston forces cells through a small hole. High-throughput Homogenizer An expensive bead-beating machine can process a large number of samples simultaneously in a short time. Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. MAT4bdc_8f92
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. Microfluidizer A Z-shaped interaction chamber and pump work in tandem to exert high pressures on cells. Enzymatic Method Digestion of the cell wall by chemical reactions. Sonication Ultrasonic waves in short bursts are employed to disintegrate tissue. MAT4bdc_c59c
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mortar & Pestle This is laborious manual work that can take several minutes. Freeze-thaw Cells are pulverized through a combination of extreme cold. Microfluidizer A high-pressure pump pushes cells through a Z-shaped interaction chamber. Sonication Ultrasonic waves rupture cell walls. MAT4bdc_d526
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mortar & Pestle This is laborious manual work that can take several minutes. High-throughput Homogenizer Large numbers of samples are disrupted simultaneously using a bead-beating machine. Mechanical Homogenizer Consists of a fast-spinning inner rotor with a stationary outer stator to produce shearing forces. Enzymatic Method Digestion of the cell wall by chemical reactions. MAT4bdc_4809
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Chemical reactions digest the cell wall. Mortar & Pestle The cells are disrupted by hand grinding them. Bead-beating This technique involves using glass or metal particles to apply gentle abrasion while vortexing them. Dounce Homogenizer A spinning handheld device smashes cells in a tube. MAT4bdc_0938
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Sonication High-frequency sound waves cause disruption of cells by shear force and tension. Bead-beating This technique involves using glass or metal particles to apply gentle abrasion while vortexing them. French Press Cells are pushed through a small hole using high pressure from a hydraulic piston. Enzymatic Method Lysozyme is commonly used to digest the cell wall of gram-positive bacteria. MAT4bdc_977a
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
High-throughput Homogenizer Large numbers of samples are disrupted simultaneously using a bead-beating machine. Mortar & Pestle Grinding of the cells by hand to disrupt the cell walls. Mechanical Homogenizer Spinning rotor blades shear the cell walls. Dounce Homogenizer Handheld device that spins in a tube to smash cells. MAT4bdc_f41d
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mechanical Homogenizer Consists of a fast-spinning inner rotor with a stationary outer stator to produce shearing forces. High-throughput Homogenizer Large numbers of samples are disrupted simultaneously using a bead-beating machine. Sonication This technique applies high-frequency sound waves to shatter cells. Microfluidizer Uses a pump and a Z-shaped interaction chamber to create high pressures. MAT4bdc_2645
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mortar & Pestle This is laborious manual work that can take several minutes. High-throughput Homogenizer An expensive bead-beating machine can process a large number of samples simultaneously in a short time. Mechanical Homogenizer Spinning rotor blades shear the cell walls. Sonication High-frequency sound waves cause disruption of cells by shear force and tension. MAT4bdc_ac4e
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
High-throughput Homogenizer Large numbers of samples are disrupted simultaneously using a bead-beating machine. Dounce Homogenizer Cells are smashed using a spinning handheld device in a tube. Freeze-thaw Cell suspensions are subjected to variable temperatures, resulting in rupture of the walls. Enzymatic Method Chemical reactions digest the cell wall. MAT4bdc_6f17
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Lysozyme is commonly used to digest the cell wall of gram-positive bacteria. Mechanical Homogenizer Spinning rotor blades shear the cell walls. Mortar & Pestle Grinding of the cells by hand to disrupt the cell walls. Freeze-thaw The cell walls rupture due to extreme temperature variations. MAT4bdc_b825
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mechanical Homogenizer Drill-like device with spinning rotor blades to shear cells apart. Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. Microfluidizer High pressures are generated using a Z-shaped chamber and a pump. French Press Cell suspension is forced through a narrow valve using a hydraulic piston. MAT4bdc_ad2a
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
French Press Cell suspension is forced through a narrow valve using a hydraulic piston. Bead-beating Small glass particles are placed into a blender and act like bullets smashing the cells. Mechanical Homogenizer Shearing forces from spinning blades break cells apart. Mortar & Pestle Manual grinding of cells that can take several minutes." MAT4bdc_c814
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Sonication High-frequency sound waves cause disruption of cells by shear force and tension. Freeze-thaw Cells are pulverized through a combination of extreme cold. High-throughput Homogenizer Numerous samples are processed simultaneously using a bead-beating machine. Dounce Homogenizer A spinning handheld device smashes cells in a tube. MAT4bdc_dbab
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mortar & Pestle Manual grinding of cells that can take several minutes." High-throughput Homogenizer Numerous samples are processed simultaneously using a bead-beating machine. French Press A hydraulic press drives a piston to squeeze the sample through a needle valve. Sonication High-frequency sound waves cause disruption of cells by shear force and tension. MAT4bdc_b7c0
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mechanical Homogenizer Shearing forces from spinning blades break cells apart. French Press A hydraulic piston within a cylinder forces cells through a small hole using high pressure. Mortar & Pestle The cells are disrupted by hand grinding them. Bead-beating Tiny glass particles are mixed and stirred to a high level of agitation. MAT4bdc_55ca
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
High-throughput Homogenizer Numerous samples are processed simultaneously using a bead-beating machine. Microfluidizer Z-shaped chamber and pump create high pressure to disrupt cells. Mechanical Homogenizer Shearing forces from spinning blades break cells apart. Enzymatic Method Digestive protein catalysts digest and decompose the microbial cell wall. MAT4bdc_99bf
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mechanical Homogenizer Drill-like device with spinning rotor blades to shear cells apart. Mortar & Pestle Grinding of the cells by hand to disrupt the cell walls. Enzymatic Method Lysozyme digests gram-positive bacterial cell walls. Bead-beating Tiny glass particles are mixed and stirred to a high level of agitation. MAT4bdc_0b2d
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
French Press A hydraulic press drives a piston to squeeze the sample through a needle valve. Microfluidizer High pressures are generated using a Z-shaped chamber and a pump. Sonication Cells are disrupted by the shear force and tension caused by high-frequency sound waves. Freeze-thaw Cold temperatures form ice crystals, which expand, ultimately causing the cell wall to rupture. MAT4bdc_23b7
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Dounce Homogenizer A spinning handheld device smashes cells in a tube. Mechanical Homogenizer Motorized device with rotating blades that shear cells apart. French Press A hydraulic piston within a cylinder forces cells through a small hole using high pressure. Mortar & Pestle This is laborious manual work that can take several minutes. MAT4bdc_3025
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Chemical reactions digest the cell wall. Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. French Press Cells are forced through a tiny hole by a high-pressure hydraulic piston. High-throughput Homogenizer Numerous samples are processed simultaneously using a bead-beating machine. MAT4bdc_965a
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
High-throughput Homogenizer An expensive bead-beating machine can process a large number of samples simultaneously in a short time. Sonication Ultrasonic waves rupture cell walls. French Press Cell suspension is forced through a narrow valve using a hydraulic piston. Freeze-thaw Cells are pulverized through a combination of extreme cold. MAT4bdc_345f
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mortar & Pestle This is laborious manual work that can take several minutes. Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. Bead-beating Gentle abrasion is applied to cells through vortexing with glass or metal particles. Mechanical Homogenizer Drill-like device with spinning rotor blades to shear cells apart. MAT4bdc_acbd
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Bead-beating Tiny glass particles are mixed and stirred to a high level of agitation. Sonication This technique applies high-frequency sound waves to shatter cells. Freeze-thaw Under cold temperatures, the water inside the cells expands into ice, causing the cells to burst open. French Press Cells are forced through a tiny hole by a high-pressure hydraulic piston. MAT4bdc_6ef7
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Freeze-thaw Cell suspensions are subjected to variable temperatures, resulting in rupture of the walls. Microfluidizer A Z-shaped interaction chamber and pump work in tandem to exert high pressures on cells. Sonication This technique uses short bursts of ultrasonic waves to disrupt the tissue. French Press A hydraulic press drives a piston to squeeze the sample through a needle valve. MAT4bdc_2808
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Microfluidizer A Z-shaped interaction chamber and pump work in tandem to exert high pressures on cells. Bead-beating Small glass or ceramic particles are used to crack open cells. Sonication Ultrasonic sound energy is used to cause air bubbles in a liquid to implode, damaging the cells. Freeze-thaw Under cold temperatures, the water inside the cells expands into ice, causing the cells to burst open. MAT4bdc_8636
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Digestion of the cell wall by chemical reactions. French Press A hydraulic press drives a piston to squeeze the sample through a needle valve. High-throughput Homogenizer Numerous samples are processed simultaneously using a bead-beating machine. Sonication Ultrasonic waves rupture cell walls. MAT4bdc_6d18
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mechanical Homogenizer Drill-like device with spinning rotor blades to shear cells apart. Mortar & Pestle Grinding of the cells by hand to disrupt the cell walls. High-throughput Homogenizer An expensive bead-beating machine can process a large number of samples simultaneously in a short time. Enzymatic Method Chemical reactions digest the cell wall. MAT4bdc_0d9a
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Microfluidizer Cells are pushed through a Z-shaped chamber using a high-pressure pump. French Press A hydraulic piston within a cylinder forces cells through a small hole using high pressure. Mechanical Homogenizer Spinning rotor blades shear the cell walls. High-throughput Homogenizer Large numbers of samples are disrupted simultaneously using a bead-beating machine. MAT4bdc_7402
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
French Press Cell suspension is forced through a narrow valve using a hydraulic piston. High-throughput Homogenizer Large numbers of samples are disrupted simultaneously using a bead-beating machine. Dounce Homogenizer Cells are smashed using a spinning handheld device in a tube. Mechanical Homogenizer Motorized device with rotating blades that shear cells apart. MAT4bdc_0b9d
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Chemical reactions digest the cell wall. Dounce Homogenizer Handheld device that spins in a tube to smash cells. Microfluidizer Cells are pushed through a Z-shaped chamber using a high-pressure pump. Sonication Ultrasonic waves in short bursts are employed to disintegrate tissue. MAT4bdc_57b3
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Dounce Homogenizer Handheld device that spins in a tube to smash cells. Mortar & Pestle Samples are ground by hand to break apart into small pieces. Sonication Ultrasonic waves rupture cell walls. High-throughput Homogenizer An expensive bead-beating machine can process a large number of samples simultaneously in a short time. MAT4bdc_7ca6
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Mortar & Pestle Manual grinding of cells that can take several minutes." Microfluidizer Cells are pushed through a Z-shaped chamber using a high-pressure pump. Freeze-thaw Cells are pulverized through a combination of extreme cold. High-throughput Homogenizer An expensive bead-beating machine can process a large number of samples simultaneously in a short time. MAT4bdc_42a4
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Microfluidizer Uses a pump and a Z-shaped interaction chamber to create high pressures. High-throughput Homogenizer Numerous samples are processed simultaneously using a bead-beating machine. Freeze-thaw Under cold temperatures, the water inside the cells expands into ice, causing the cells to burst open. French Press A hydraulic press drives a piston to squeeze the sample through a needle valve. MAT4bdc_c205
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Sonication Ultrasonic waves rupture cell walls. Microfluidizer A high-pressure pump pushes cells through a Z-shaped interaction chamber. High-throughput Homogenizer An expensive bead-beating machine can process a large number of samples simultaneously in a short time. Mechanical Homogenizer Shearing forces from spinning blades break cells apart. MAT4bdc_a20e
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Bead-beating Glass or ceramic particles stirred at high speeds crack cells open. Enzymatic Method Lysozyme is commonly used to digest the cell wall of gram-positive bacteria. French Press Cells are forced through a tiny hole by a high-pressure hydraulic piston. Microfluidizer A Z-shaped interaction chamber and pump work in tandem to exert high pressures on cells. MAT4bdc_1b8f
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. Mortar & Pestle This is laborious manual work that can take several minutes. High-throughput Homogenizer An expensive bead-beating machine can process a large number of samples simultaneously in a short time. Microfluidizer Z-shaped chamber and pump create high pressure to disrupt cells. MAT4bdc_7b50
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Digestive protein catalysts digest and decompose the microbial cell wall. Bead-beating Small glass particles are placed into a blender and act like bullets smashing the cells. Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. Mortar & Pestle Samples are ground by hand to break apart into small pieces. MAT4bdc_4279
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Sonication This technique uses short bursts of ultrasonic waves to disrupt the tissue. Microfluidizer Cells are pushed through a Z-shaped chamber using a high-pressure pump. French Press High-pressure hydraulic piston forces cells through a small hole. Enzymatic Method Digestive protein catalysts digest and decompose the microbial cell wall. MAT4bdc_f560
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Lysozyme digests gram-positive bacterial cell walls. Freeze-thaw Under cold temperatures, the water inside the cells expands into ice, causing the cells to burst open. Mortar & Pestle This is laborious manual work that can take several minutes. Dounce Homogenizer Handheld cylindrical glass tube and a spinning pestle that has a tight fit within the shaft. MAT4bdc_2722
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Enzymatic Method Lysozyme is commonly used to digest the cell wall of gram-positive bacteria. Freeze-thaw This technique uses extremely cold temperatures and grinding to pulverize cells. Bead-beating This technique involves using glass or metal particles to apply gentle abrasion while vortexing them. French Press Cells are forced through a tiny hole by a high-pressure hydraulic piston. MAT4bdc_aa43
Match each of the following cell disruption techniques with their corresponding descriptions.
Note: Each choice will be used exactly once.
Microfluidizer A Z-shaped interaction chamber and pump work in tandem to exert high pressures on cells. Sonication This technique uses the forces of ultrasonic waves to rupture cells. Bead-beating This technique involves using glass or metal particles to apply gentle abrasion while vortexing them. French Press High-pressure hydraulic piston forces cells through a small hole.