Inverted Biological Microscope KIM/B/10T (Trinocular)

Features:

LWD Infinity Plan Achromatic 4x10x40x, LWD Infinity Phase
LWD Condenser N.A. 0.3, WD 72mm with Phase Contrast Slide 10x-40x
Fixed Stage 250x160mm, With Glass Plate, Metal Plate, Petri Dish Holder, Optional Moving Ruler
Transmit Critical Illumination 6V30W Halogen Brightness Adjustable

Specification
Kiparma Model	KIM/B/10T
Head :	Trinocular head, Light Split Switch E100:P0/E80:P20 Gemel Viewing Head, 45 Degree Inclined, Interpupillary distance 54-75mm, One Eyepiece tube with ±5 Diopter Adjustment.
Eyepiece :	PL 10X/22mm, high Eyepoint. Wide Field.
Nosepiece :	Reversed Revolving Quintuple Nosepiece
Objective :	Long Working Distance Infinity Plan Achromatic Objectives LWDPL 4x/0.10, W.D. = 22mm LWDPL 10x/0.25, W.D. = 7.94mm LWDPL 40x/0.60, W.D. = 3.72mm Long Working Distance Infinity Plan Phase Contrast Objectives LWDPL 20x/0.40, W.D. = 7.66mm
Focusing :	Coaxial Coarse and Fine Focusing System, Working Distance of Every Circle: 38mm/Coarse focus, 0.2mm/Fine Focus, Minimal Read 0.002mm/, with tension adjustment. With Safety Stop.
Condenser :	N.A.0.3 Kholer Illumination Condenser, with phase adjustable Slide Plate, Long Working Distance 72 mm. The Whole Set Can Be Rotated Down.
Stage :	Fixed Stage size 250x160mm, Slider Clips Glass Plate Metal Plate Petri Dish Holder, Dia. 35mm
Phase Contrast :	Phase Contrast Plug-board for 10x-40x, Center Adjustable Centering Telescope Dia. 30mm
Filter :	Dia. 45mm Green Interference Filter Dia. 45mm Color Temperature Filter
Light :	Critical Illumination, With Iris Aperture, Halogen 6V30W, Pre-centered, Intensity Adjustable

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Features & Compatibility

Unveil the Hidden World with an Inverted Biological Microscope KIM/B/10T

Inverted Biological Microscope KIM/B/10T are essential tools in modern laboratories, providing researchers and scientists with the ability to observe and analyze living cells, tissues, and organisms in their natural environments. Unlike traditional upright microscopes, an inverted microscope has its light source and condenser located above the stage, while the objectives are below. This unique design allows for the easy examination of samples in petri dishes, culture flasks, and other containers, making it ideal for a variety of applications, including cell culture, live cell imaging, and more. In this guide, we’ll explore the features, benefits, and applications of inverted biological microscopes, helping you choose the right model for your research needs.

What is an Inverted Biological Microscope?

An inverted biological microscope is a specialized microscope designed for the observation of living cells and tissues from below. This design allows the sample to remain undisturbed in a dish or flask while being viewed from underneath. The inverted configuration is particularly advantageous for studying cells that are growing in liquid media or on the bottom of culture vessels, as it minimizes disturbance to the sample and enables long-term observation of live specimens.

Key Features of Inverted Biological Microscopes

Inverted Optical Design: The unique configuration places the light source and condenser above the sample, allowing for easy access to the culture dish and minimizing the risk of sample contamination.
High-Quality Optics: Equipped with advanced objective lenses and high-resolution cameras, inverted microscopes deliver clear, detailed images, essential for precise observation and analysis.
Phase Contrast and Fluorescence Capabilities: Many inverted microscopes are equipped with phase contrast and fluorescence imaging options, enhancing the ability to observe transparent specimens and visualize specific cellular components.
Long Working Distance Objectives: These microscopes feature long working distance objectives, allowing for observation of thick samples or those in deeper culture vessels without the need to remove the lid.
Stable and Ergonomic Design: Designed for stability and ease of use, inverted microscopes often feature ergonomic controls, adjustable stages, and durable construction to support extended periods of observation.
Environmental Control Options: Some models include built-in incubators, temperature control, and CO₂ control systems, allowing researchers to maintain the optimal environment for live cell imaging over extended periods.

Benefits of Using an Inverted Biological Microscope

Optimized for Cell Culture: The inverted design is ideal for observing cells in culture dishes, flasks, and multi-well plates, facilitating research in cell biology, cancer research, and drug development.
Live Cell Imaging: Inverted microscopes are perfect for live cell imaging, allowing researchers to monitor cellular processes in real-time without disturbing the sample environment.
Versatile Applications: Suitable for a wide range of applications, including tissue culture, IVF, microbiology, and more, making them indispensable in both research and clinical laboratories.
Minimized Sample Disturbance: By observing samples from below, inverted microscopes reduce the risk of contaminating or disturbing delicate samples, ensuring accurate and reliable results.
Enhanced Imaging Capabilities: With options for phase contrast and fluorescence, these microscopes enable the visualization of fine details and specific cellular components, crucial for advanced research.
User-Friendly Operation: Designed with the user in mind, these microscopes offer intuitive controls, easy adjustments, and ergonomic design, ensuring comfort and efficiency during extended use.

Applications of Inverted Biological Microscopes

Cell Culture Research: Inverted microscopes are extensively used in cell culture labs to observe the growth, morphology, and behavior of cells in real-time, aiding in research areas like cancer, stem cell, and developmental biology.
Live Cell Imaging: Researchers can monitor cellular processes, such as mitosis, migration, and apoptosis, over time, providing insights into dynamic biological phenomena.
In Vitro Fertilization (IVF): Inverted microscopes are crucial in IVF clinics for observing and manipulating embryos and oocytes, ensuring successful fertilization and development.
Tissue Engineering: Used to study the interaction between cells and biomaterials, inverted microscopes help in the development of artificial tissues and organs.
Microbiology: Inverted microscopes are used to study microorganisms, such as bacteria and fungi, in culture, supporting research in infectious diseases, environmental biology, and biotechnology.
Drug Discovery and Development: Pharmaceutical researchers use inverted microscopes to screen the effects of new drugs on live cells, enabling the identification of promising therapeutic candidates.

Choosing the Right Inverted Biological Microscope

When selecting an inverted biological microscope, consider the specific needs of your research. Key factors include the type of imaging required (e.g., phase contrast, fluorescence), the size and type of samples you’ll be working with, and whether environmental control features are necessary. Additionally, think about the microscope’s ergonomics, ease of use, and any software capabilities that may enhance your workflow. Consulting with microscope experts or manufacturers can help you find the best model to match your research requirements.

Conclusion

An inverted biological microscope is a powerful tool for researchers and scientists, providing the ability to observe living cells and tissues with precision and clarity. Whether you’re working in cell culture, microbiology, or IVF, the unique design and advanced features of an inverted microscope offer unmatched versatility and convenience. By choosing the right model for your needs, you can enhance your research capabilities, achieve more accurate results, and contribute to the advancement of science.

For expert guidance on selecting the best inverted biological microscope for your laboratory, contact our specialists today.