Dry Bath / Heating Block DB1 ▶ Heating Block It is used to heat the sample to a controlled temperature. The equipment is primarily used in molecular biology, biochemistry, and other life science experiments for a variety of applications, such as DNA amplification (PCR), enzymatic reactions, sample thawing, and incubation. ▶ How to operate 1. Power supply and power on First, connect the dry block heater to the appropriate power supply. Turn on the power or press the operating button to activate the heater. 2. Temperature Settings Use the digital control panel to set the desired temperature. Most dry block heaters display the current temperature and the set temperature through a digital display. 3. Block insertion and sample placement Select the sample tube or container that you want to heat, and select the block for that size and type. Insert a sample into each hole in the block. 4. Heating System Operation The dry block heater operates the heating system through the aluminum block. The heating element is located around this block. When the heating element is heated, the aluminum block effectively transfers heat to the sample and heats the sample to the target temperature. 5. Utilize temperature control and safety features The heater continuously monitors and adjusts the temperature to maintain the set temperature. As one of the safety features, over-temperature protection is applied when the set maximum temperature is exceeded, turning off the heating element. 6. Complete heating and remove samples When the experiment is complete, turn off the heater and safely remove the sample.
LABTron’s Post
More Relevant Posts
-
The D1524R High-Speed Refrigerated Micro Centrifuge from DLAB—ideal for laboratories requiring rapid and efficient separation of samples. With advanced cooling technology and versatile rotor options, this centrifuge is perfect for high-precision work in molecular biology, biochemistry, and clinical labs. #LabEfficiency #MicroCentrifuge #DLAB #LabEquipment #PrecisionSeparation #SparkScientific
To view or add a comment, sign in
-
Our high-speed centrifuge tubes offer the following advantages: 1. Durability: withstand high centrifugal forces without breaking. 2. Temperature Tolerance: Can endure extreme temperatures, from -80℃ to 121℃. 3. Clear scale : Allowing for easy visualization of the contents. 4. Versatility: Suitable for a wide range of applications, including molecular biology, biochemistry, and clinical labs.
To view or add a comment, sign in
-
Spectrophotometer: Precision In Tiny Sample Detection 📡 Spectrophotometers are indispensable in modern analytical science, widely applied in fields like biology, chemistry, environmental monitoring, and medicine. From nucleic acid quantification to bacterial growth analysis, these instruments enable precise, small-sample detection, contributing to advancements in proteomics, genomics, and molecular biology. 🌏 As technology evolves, compact spectrophotometers now offer increased accuracy with minimal sample volumes, aiding researchers across life sciences and environmental fields. 🔬 Explore more: https://lnkd.in/gUkDBQWJ #Spectrophotometry #Analytical_Science #Molecular_Biology #Biotech #Environmental_Monitoring #Tiny_sample_detection
To view or add a comment, sign in
-
SBGrid's eLife paper received a citation from Jennifer Bridwell-Rabb from University of Michigan in Biochemistry: Conformation-Dependent Hydrogen-Bonding Interactions in a Switchable Artificial Metalloprotein. Read more here: https://lnkd.in/egU4ztmk #SBGrid #ScienceMatters #structuralbiology
Conformation-Dependent Hydrogen-Bonding Interactions in a Switchable Artificial Metalloprotein
pubs.acs.org
To view or add a comment, sign in
-
Enzyme Engineering By Force: DNA Springs for the Modulation of Biocatalytic Trajectories is now in ACS Synthetic Biology! Here, we present an alternative approach in protein engineering, where enzymatic active site architectures and biocatalytic trajectories can be dynamically and reversibly remodeled using mechanical forces generated by DNA springs.
Enzyme Engineering by Force: DNA Springs for the Modulation of Biocatalytic Trajectories
pubs.acs.org
To view or add a comment, sign in
-
Highly cited papers in BRIC 3 Recent advances in biological approaches towards anode biofilm engineering for improvement of extracellular electron transfer in microbial fuel cells https://lnkd.in/gaxEkCTW Over the last two decades, scientific communities have been more interested in turning organic waste materials into bioenergy. Microbial fuel cells (MFC) can degrade organic wastewater and produce electrical power. Many constraints have limited the development of MFC. Among them, the anode biofilm development is one of the significant constraints that need to be improved. This review delineates the role of various biological components in the development of electroactive biofilm. The current article focuses on the numerous electron exchange methods for microbiome-induced electron transfer activity, the different proteins, and secretory chemicals involved in electron transfer. This study also focuses on several proteomics and genomics methodologies that have been adopted and developed to improve the extra electron transfer mechanism in electroactive bacteria. Recent advances and publications on synthetic biology and genetic engineering in investigating the direct and indirect electron transport phenomena have also been highlighted. This review helps the reader to understand the recent development in the genetic manipulations of the biofilm, electrode material modifications, EET mechanisms, and operational strategies for improving anode performance. This review also discusses the challenges in present technology and the future direction for improving biofilm production at the anode.
To view or add a comment, sign in
-
How to Detect and Solve Faulty PCR – Part 1: Common PCR Issues Polymerase Chain Reaction is one of the most used techniques in molecular biology, but it can go wrong like all other experiments! Here are some key indicators that your PCR might be faulty: 1. No Amplification (No Bands on Gel) Cause: Low template DNA, wrong annealing temperature, failed reagents. 2. Non-Specific Amplification (Multiple Bands) Cause: Primers binding to non-target sequences, poor primer design, or incorrect cycling conditions. 3. Primer Dimers Cause: Primers hybridizing with each other due to poor design or high concentration. 4. Faint Bands Cause: Low template concentration or degraded reagents. 5. Smearing on the Gel Cause: Degraded template DNA, poor-quality reagents, or over-cycling. Stay tuned for the next post where I’ll cover solutions to these problems! 🧬🔬 #PCR #MolecularBiology #Troubleshooting #LabSkills
To view or add a comment, sign in
-
Unlock the power of data in the life sciences with our Introduction to Statistics online course which covers fundamental statistical concepts and techniques essential for biochemistry and related fields, starting on 14 October. https://ow.ly/5OZx50TjRO9
To view or add a comment, sign in
-
How does life work at the molecular level? From protein structures to metabolic pathways, gain a comprehensive understanding of the molecular processes that govern life with "Biochemistry: Biomolecules, Methods, and Mechanisms" from the MIT Department of Biology. Starts April 2! Learn more and enroll at https://bit.ly/3TAi8Bt #LearnBiology #OnlineEducation #OnlineLearning #Biochemistry #HigherEducation
MITx: Biochemistry: Biomolecules, Methods, and Mechanisms
edx.org
To view or add a comment, sign in
-
I'm very happy to announce our article's publication in the Chemical Engineering Journal (Impact Factor: 15.1). 🔗 [Read Our Work] ( https://lnkd.in/dJEZNn7N ) Our 30-month research journey culminated in this manuscript. We explored ZIF-67 (Cobalt core MOF) and its role in enhancing photocatalytic performance, integrating catalysis, environmental science, computational chemistry (DFT), artificial intelligence ( A novel procedure), genetic algorithm optimization, microbiology, and reaction engineering. ZIF-67 has proven to be an exceptional modifier. Techniques used include XPS, XRD, FTIR, RAMAN, HRTEM, FESEM, EDX, Elemental Mapping, TGA, XRF, PL, UV-Vis DRS, Mott-Schottky plots, VB-XPS, photocurrent, EIS, LC-MS, ICP-OES, BET, BJH, and DLS. #Metal_organic_framework #Photocatalyst #Artificial_neural_networks #Density_functional_therory #Genetic_algorithms #Toxicity #Cefixime #DFT #ANN #GA
To view or add a comment, sign in
40 followers