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Test tube rack
Test tube rack
Test tube rack
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Test Tube Rack

Test tube racks are laboratory equipment used to hold upright multiple test tubes at the same time. They are most commonly used when various different solutions are needed to work with simultaneously, for safety reasons, for safe storage of test tubes, and to ease the transport of multiple tubes. Test tube racks also ease the organization of test tubes and provide support for the test tubes being worked with.[1]

Types

[edit]

Test tube racks come in a variety of size, composition, material, and color. The variety of test tube racks increases the number of circumstances they can be used in whether it is to be placed in an autoclave, or to be placed in the refrigerator. The racks are most commonly made of metal wires, but they can also be found as plastic, polystyrene, foam, fiberglass, and polypropylene. Test tube racks come in the form of a classic rack, an interlocking cube form, a stack-able form, test tube drying rack, slant rack, and 1-well rack.[2]

Classic Test Tube Rack

Classic rack

[edit]

The classic racks are normally found in any regular laboratory and are made of wood, stainless steel, or plastic. It generally has 8 holes, 10 holes, or 12 holes to keep test tubes.

Interlocking cube form

[edit]

This form of test tube racks consists of several cubes of racks that are detachable and twist-able based on the side that is needed for use. Each cube can hold one size of test tubes but each of the four sides of the cube holds the tubes in various arrangements that can be adjusted for use accordingly. These racks can not only be used for test tubes, but it can also be used to hold culture tubes, centrifuge tubes, and micro-centrifuge tubes. The interlocking cube racks can also be put in the autoclave, as well as ease the transport of multiple different sized tubes.[3]

Stackable rack

[edit]
Stackable Test Tube Rack

Stackable racks are made of polypropylene and can be placed in the autoclave as well. Using a secondary frame or chassis these racks that otherwise appear as the classic test tube racks can be placed one on top of the other.

Test tube drying rack

[edit]

Drying Racks can be used for various purposes, including drying and holding chromatography plates, as well as drying test tubes by placing them in an inverted position in the pegs. Placing the test tubes in an inverted position not only aids in drying, but it also minimizes the accumulation of airborne contaminants and other substances. Additionally, the drying racks are usually made of polypropylene and can be placed in the autoclave.[4]

Slant rack

[edit]

Slant racks are used to hold the slants at the degree it is required to be placed in to be dried after the media has been inserted into the tube. It is also used to incubate certain liquid cultures at an angle so that all the tubes are uniform.[5]

1-well rack

[edit]

The 1 well rack is designed to hold only one test tube or any tube that fits in the space. It is normally made of epoxy-coated steel wire[6] but can also be made of polystyrene. The racks made from polystyrene are friction-fit and can only hold tubes that match in size to the rack. These racks are autoclavable and can hold both conical or round bottom tubes.[7]

Vial racks

[edit]
Hinge-top vials being filled by pipette on a plastic vial rack.

This type of rack is designed for much smaller plastic vials. It is often made out of plastic.[8]

See also

[edit]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Test tube rack

View on Grokipedia
from Grokipedia
A test tube rack is a fundamental piece of designed to securely hold multiple test tubes in an upright position at the same time, facilitating organization, storage, and access during experiments. These racks typically feature an array of vertical wells or slots tailored to the of standard test tubes, preventing tipping and enabling safe handling of samples such as chemicals, biological materials, or reagents. Test tube racks are widely used in scientific settings, including chemistry, biology, and medical laboratories, for tasks like mixing solutions, observing reactions, drying tubes after washing, and preparing samples for analysis. They come in various types to suit specific needs, such as general-purpose racks for everyday use, drying racks with drainage features to air-dry inverted tubes, and interlocking modular designs that allow customization for larger setups. Materials for construction include durable plastics like polypropylene and polycarbonate for lightweight and chemical-resistant options, metals such as stainless steel or aluminum for robustness and autoclavability, wood for basic educational environments, and foam inserts for gentle handling of fragile samples. The choice of rack depends on factors like tube size compatibility (e.g., for 10-25 mm diameters), chemical resistance to avoid contamination, and heat tolerance for sterilization processes, ensuring efficiency and safety in diverse lab workflows. In modern labs, advanced racks may incorporate features like color-coding for sample identification or stackable designs for space-saving storage, enhancing productivity in high-throughput environments.

Overview

Definition and Purpose

A test tube rack is a fundamental piece of equipment designed to hold multiple test tubes in an upright position simultaneously, ensuring stability and efficient organization during scientific procedures. This design allows researchers to manage several samples at once without the need for individual supports, making it indispensable for routine tasks. The primary purposes of a test tube rack include providing secure storage to prevent test tubes from tipping over or breaking, facilitating chemical reactions by keeping tubes easily accessible for additions or manipulations, and supporting observational processes such as monitoring color changes or formation. By maintaining tubes in a vertical orientation, racks enable safe handling during mixing, heating, or cooling, which is crucial for accurate experimental outcomes. Key benefits of using test tube racks encompass improved efficiency through organized access to multiple samples, reduced of accidents and breakage that could lead to spills or injuries, and minimized potential for cross-contamination by isolating tubes from one another. Additionally, they promote safer management of hazardous materials by stabilizing containers that may hold reactive or toxic substances, thereby enhancing overall and productivity. Test tube racks have evolved from simple wooden holders employed in early 20th-century laboratories to versatile, essential tools integral to modern scientific practice.

Basic Design Features

Test tube racks typically feature upright holders consisting of evenly spaced holes or slots designed to securely accommodate of standard diameters, such as 10-25 mm, ensuring the tubes remain vertical and stable during storage or procedures. A stable base supports these holders, providing balance to prevent tipping, while optional integrated handles facilitate safe transport without disturbing contents. Hole configurations vary to optimize access and capacity, including single-row arrangements for linear organization and straightforward retrieval, multi-row setups that support higher volumes such as up to 50 tubes, and angled slots that enhance visibility of tube contents without removal. These designs maintain even spacing, typically 1-2 cm between positions, to allow sufficient airflow and prevent cross-contamination. Ergonomic considerations include non-slip bases to secure the rack on lab surfaces, labeled or alphanumeric positions for accurate sample tracking, and compatibility with standard bench tops or water baths through features like low-profile edges or non-floating stability. Capacity generally ranges from 6 to 100 tubes, with smaller racks prioritizing portability for individual workflows and larger ones emphasizing stability through broader bases to handle increased weight and prevent imbalance during use.

History and Development

Origins in Early Laboratories

The test tube rack emerged in the mid-19th century as glass test tubes became standard in chemical laboratories, providing a means to organize and secure these fragile vessels during experiments in gas analysis and other procedures. Test tubes themselves originated in the early 1800s, with possible inventors including or , whose work in necessitated reliable holders to prevent breakage and facilitate workflows in burgeoning European labs. This development paralleled the expansion of formal chemistry education and research institutions, such as those influenced by Justus von Liebig's laboratory model in , , where systematic equipment organization was essential. Early test tube racks took rudimentary forms, typically consisting of wooden blocks drilled with holes to grip tubes upright or basic metal wire frames for support and drainage. These designs appeared in apothecaries and basic chemistry across in the mid-to-late , often handmade by artisans to accommodate the growing use of in and heating tasks. Wooden peg variants allowed inverted tubes to drain after washing, reflecting the practical needs of daily lab routines without advanced engineering. By the 1880s, test tube racks were integrated into standard setups, as noted in chemical supply catalogs and early manuals that described their role in maintaining order during experiments. This adoption marked a shift toward more structured lab environments, where racks enabled safe handling of multiple tubes simultaneously for processes like qualitative . However, these initial designs had notable limitations, offering only basic stability and compatibility with uniform tube sizes, while wooden versions warped under exposure to heat or humidity and metal ones rusted in moist conditions, restricting their versatility compared to future iterations.

Modern Advancements

The introduction of plastic materials, particularly , in test tube racks during the mid-20th century marked a significant shift toward enhanced chemical resistance and reduced weight compared to earlier wooden or metal designs, facilitating easier handling and storage in diverse environments. These plastics also enabled the development of autoclavable racks by the late 20th century, allowing for effective steam sterilization essential in workflows without compromising structural integrity. Further innovations in the late 20th and early 21st centuries included modular systems, as patented in designs from the , which permit customizable assembly for flexible storage configurations tailored to varying tube sizes and quantities. racks also began integrating with , such as robotic handlers and systems, to support efficient sample processing in pharmaceutical and research settings. constructions, adopted widely in pharmaceutical laboratories for their superior durability and corrosion resistance, became a standard for heavy-duty applications requiring repeated autoclaving and exposure to harsh conditions. In the , has driven the adoption of eco-friendly variants using recyclable or bio-based plastics, minimizing environmental impact while maintaining performance standards in line with growing demands for practices. These modern advancements have collectively reduced the risk of breakage and spills relative to early designs through features like rigid supports, non-slip bases, and ergonomic grips, thereby improving safety during the handling of biohazards and sensitive samples.

Materials and Construction

Common Materials

Test tube racks are commonly constructed from , metals, plastics, and like PTFE, each selected for specific properties that suit various needs. , often sourced from or , serves as a traditional and affordable material for test tube racks, typically costing $5-20 per unit for standard 12-tube models. These racks provide good insulation against fluctuations and stability on benchtops due to their solid , making them suitable for low-chemical environments such as educational settings where exposure to harsh reagents is minimal. However, wood is absorbent and prone to or warping from liquids and chemicals, rendering it non-autoclavable and less ideal for sterile or corrosive applications. Metals, particularly such as 304 grade, offer superior durability and corrosion resistance due to a passive film that protects against oxidation and acidic environments. These racks withstand high temperatures, with operating ranges from -20°C to 90°C and autoclavability up to 121°C, and their wire construction promotes drainage and airflow to prevent from water retention. Priced at $15-50 per unit, racks provide long-term reliability and are preferred in professional labs handling bodily fluids or sterilization processes. Plastics like and are lightweight, chemically resistant alternatives that do not absorb or promote microbial growth, with offering particular tolerance to acids and bases. These materials are autoclavable at 121°C for 20 minutes and cost $5-50 per unit, depending on size and features like color-coding for sample organization. racks sink in baths without floating and resist heat and chemical attack, making them versatile for general storage and transport in diverse lab workflows. For demanding applications, advanced materials such as PTFE (Teflon) provide extreme chemical inertness and non-stick properties, ensuring no or adhesion of samples. PTFE racks operate from -200°C to 260°C and are fully autoclavable, ideal for highly reactive substances. Foam inserts, often integrated into or metal racks, offer cushioning for fragile tubes without sticking, enhancing protection during handling. Material selection depends on factors like cost, with wood being the most economical; , where metals excel for extended lifespan; and compatibility, such as plastics or PTFE for exposure to acids, bases, or extreme conditions.

Manufacturing Processes

Test tube racks are produced through a series of processes that transform raw materials into functional holders, emphasizing precision in hole formation, structural integrity, and surface treatments to meet laboratory demands. Manufacturing begins with and shaping, followed by assembly, finishing, and to ensure compatibility with standard test tube diameters and safe handling. Wooden test tube racks are typically crafted from blocks using manual or (CNC) for accuracy. The process involves cutting the wood to size, evenly spaced holes to accommodate s, sanding the surfaces for smoothness, and applying or sealant for protection against moisture and wear. Metal test tube racks, often constructed from wire or , undergo wire forming and fabrication techniques for durability. Wire is straightened, cut to length, and bent into grids or frames using CNC-controlled benders to create precise angles and radii, with capabilities for diameters from 14 gauge to 1/2 inch. Welding methods such as butt or T-welding join components, while secures frames; surfaces may receive for corrosion resistance or zinc for added protection. variants involve stamping bases for flatness before integration. Plastic test tube racks are mass-produced via injection molding for efficiency, particularly using polypropylene for its chemical resistance. Molten plastic is injected into multi-cavity molds (e.g., 1x4 layouts) under controlled temperatures, with shrinkage rates around 1.016 accounted for to achieve dimensions like 143 mm x 24.5 mm x 105 mm and wall thicknesses of 2 mm; ejector pins release parts, followed by cooling and trimming to eliminate defects such as flow lines or warpage. For custom or prototype designs in modern labs, stereolithography (SLA) 3D printing fabricates components from resins like black tough resin, involving printing layers, IPA rinsing, UV curing, manual polishing, and optional painting. Assembly across materials focuses on forming holes sized 13-16 mm in diameter to fit common test tubes securely, with arrangements like 5x12 grids for up to 60 units. Components are joined via , snapping, or adhesives, followed by quality checks for , including load-bearing capacity and uniformity. Packaging ensures sterility potential through handling. Products comply with ISO 9001:2015 for and ISO 13485:2016 for regulations, verifying no , biological safety (e.g., USP Class VI), and RoHS adherence.

Types

Classic Rack

The classic test tube rack features a fixed rectangular base with parallel rows of precisely drilled vertical holes, designed to securely hold multiple test tubes in an upright position for stability during procedures. These racks typically accommodate 20 to 50 tubes, with hole diameters ranging from 13 mm to 25 mm to fit standard borosilicate or test tubes, and lack any modular or adjustable components for a straightforward, non-configurable structure. The base often measures approximately 15 to 25 cm in length and 10 to 15 cm in width, providing a compact footprint suitable for benchtop placement. This design has been a staple since the late , when wooden constructions became prevalent alongside the widespread adoption of test tubes for chemical analysis. An example is a wooden rack owned by American Frederick Power (used 1896-1914), consisting of a simple wooden block with holes for tube insertion, offering basic organization in emerging research settings. In the mid-20th century, plastics began supplanting wood due to enhanced resistance to chemicals and moisture, while retaining the traditional fixed form. Dimensions of these historical and modern wooden or bases generally hover around 20 cm by 10 cm, ensuring portability without compromising hold. Classic racks excel in simplicity and affordability, often costing $5 to $15 per unit, which supports their widespread use in routine benchtop applications like holding tubes during mixing or observation of . Their solid, low-center-of-gravity construction ensures exceptional stability, minimizing tip-over risks in busy lab environments and facilitating quick tube retrieval. Nonetheless, the rigid, single-unit format renders them non-stackable for space-efficient storage, confines tubes to strictly vertical orientations, and necessitates separate accessories for functions like drying or secure transport.

Modular and Stackable Racks

Modular test tube racks emphasize flexibility and adaptability in laboratory storage, enabling users to interconnect or vertically pile units to suit specific workflows. Interlocking cube designs, typically made from durable polypropylene, consist of snap-together modules that form grid-based holders, such as those accommodating 42 wells across various tube diameters from 11.5 mm to 30 mm. These cubes, often sold in packs of five with color-coding for organization, allow assembly in multiple orientations to create three-dimensional configurations, facilitating space-saving storage for diverse tube sizes like 1.5 mL microcentrifuge tubes up to 50 mL conical tubes. For instance, systems with four rotatable cubes and a support tray enable simultaneous handling of multiple tube types, including 12 x 75 mm and 16 x 125 mm culture tubes, while being autoclavable for repeated sterilization. Stackable racks feature tiered structures with reinforced end plates or rails that support vertical piling, often up to multiple levels depending on load and tube height. These designs, commonly constructed from chemical-resistant for lightweight durability, hold capacities ranging from 40 to 200 tubes per unit, such as 40 places in a 4 x 10 grid for 16-20 mm tubes up to 10 cm long. Metal variants, like models with three tiers, provide enhanced stability for heavier loads in demanding environments. Quick-assembly mechanisms, including sliding interlocking plates or tongue-and-groove edges, ensure secure stacking without tools, while integrated handles enhance portability across lab benches or storage areas. These racks offer key benefits in customization, allowing reconfiguration for fluctuating lab demands, such as adapting to different experiment scales or tube assortments. By enabling compact vertical or multi-unit arrangements, they significantly optimize benchtop space compared to traditional fixed designs, making them prevalent in high-throughput settings like research facilities handling large sample volumes. Autoclavable construction further supports hygienic reuse, enhancing overall efficiency in busy laboratories.

Specialized Racks

Specialized test tube racks are designed for particular laboratory functions that require adaptations beyond standard vertical holding, such as facilitating drainage, angling for observation, or accommodating smaller containers. These racks enhance efficiency in specific workflows by incorporating features like inverted positioning, adjustable inclines, or compact single-unit designs. Test tube drying racks feature peg or clip mechanisms that allow tubes to be placed upside down for efficient post-washing drainage, preventing water accumulation and promoting air drying. Typically constructed from or wire materials, these racks often hold 50 to 96 positions to accommodate multiple tubes simultaneously, with spacious peg designs enabling easy viewing of contents during the process. The pegs are engineered to remain straight after repeated use, ensuring durability in routine lab operations. Drainage is facilitated by the elevated structure and open base, which allows excess liquid to collect below without pooling around the tubes. Slant racks provide an angled orientation, typically at 5° to 20°, to support tasks like media cooling after autoclaving or facilitating pouring and viewing of tube contents. These racks often include unique end plate designs that enable the angle adjustment by simply laying the rack on its side, allowing upright autoclaving followed by slanted cooling to create uniform slopes in culture media. Made from durable materials like , they securely hold tubes in the inclined position for easy access and reduced spillage risk during handling. Removable trays in some models permit multi-angle configurations for varied experimental needs. Single-well racks, also known as one-tube holders for microcentrifuge tubes, are compact units designed for precise handling in micro-reactions or small-scale experiments where only a single small-volume tube is needed. These holders often feature magnetic bases for to lab surfaces or equipment, accommodating tubes up to 1.5 mL in volume for stability during manipulations. Their minimalist design minimizes space usage and contamination risks in confined setups, such as those involving sensitive biochemical assays. Interlocking construction in some variants allows optional expansion if required, though the primary focus remains on isolated, precise tube positioning. Vial racks are adapted for smaller containers, such as 2-12 vials, with narrower slots typically ranging from 12 to 19 in opening size to ensure a snug fit and prevent movement. These racks, often used in pharmaceutical , organize vials in arrays like 48 or 96 positions for high-throughput processing, such as in or storage workflows. construction provides chemical resistance, and the design accommodates various vial diameters to support efficient labeling and retrieval in analytical labs. Some models include features for secure transport, reducing breakage during handling in sample prep environments.

Applications

Laboratory and Research Uses

In chemistry laboratories, test tube racks are essential for securely holding tubes during procedures such as titrations, incubations, and preparations for spectroscopy analysis, allowing researchers to maintain upright positions and prevent spills while enabling parallel processing of multiple samples. This organization facilitates efficient workflow by supporting simultaneous reactions, reducing handling time and minimizing errors in quantitative analyses. In and research, test tube racks provide sterile organization for culturing microbial samples, with autoclavable models made from or ensuring post-sterilization handling without contamination risks. These racks, often featuring alpha-numeric labeling for precise identification, support incubation in water baths or shakers while maintaining sample integrity during extended experiments. Research workflows benefit from test tube racks integrated with pipetting stations and orbital , where modular designs allow seamless placement for automated handling and agitation of multiple tubes. Similarly, portable racks are used in to transport samples upright, preserving integrity during movement from collection sites to analysis labs. Overall, racks enhance efficiency in multi-sample experiments by streamlining and retrieval, supporting higher throughput in professional settings through durable, stackable designs that integrate with automated systems.

Educational and Industrial Uses

In educational settings, racks serve as essential tools for student , providing durable and low-cost options to support hands-on chemistry experiments. wooden racks, often featuring 10 to 12 holes for standard , are commonly used in school classrooms due to their stability and affordability, allowing safe handling of tubes during basic reactions and promoting skills in laboratory and workflow management. These racks help students maintain upright positions for tubes, reducing the risk of spills and enabling clear observation of contents without the need for advanced . Slant-style racks are particularly valuable for demonstrations of visible chemical reactions, such as , where tubes are tilted at angles like 5° or 20° to enhance visibility of color changes or solid formations during group activities. Sets accommodating 10 to 20 tubes facilitate collaborative experiments in educational environments, such as mixing reagents to observe outcomes, while color-coded variants aid in sorting and identifying samples to teach methodical data tracking. In industrial applications, stackable metal racks constructed from are widely employed in for processes, enabling efficient organization and transport of multiple tubes during testing protocols. These racks support high-throughput operations in diagnostics, where vial-compatible versions integrate with automated filling lines to handle and sealing under controlled conditions. Custom modular systems, often scalable to hold thousands of tubes, are utilized in biotech factories for drug screening assays, ensuring compliance with (GMP) standards through easy sterilization and robust design for continuous 24/7 use. Heavy-duty iterations withstand rigorous environments, minimizing downtime in production workflows.

Maintenance and Safety

Cleaning and Care Methods

Maintaining test tube racks involves routine cleaning procedures to ensure and prevent in settings. For general cleaning, racks made of or wood should be washed with a mild solution and warm water using a soft or to remove residues without causing damage. Abrasives must be avoided, as they can scratch surfaces or deform the holes designed to hold test tubes securely. After washing, racks should be rinsed thoroughly with and allowed to air dry completely to eliminate any moisture that could promote microbial growth. Autoclaving is a standard sterilization method suitable for metal and certain heat-resistant plastic racks, typically conducted at 121°C and 15 psi for 15 to 20 minutes to achieve effective microbial kill. Following autoclaving, racks must be dried immediately using a low-heat or air drying to prevent , particularly on metal components exposed to residual moisture. Not all plastic racks are autoclavable, so material specifications should be checked prior to use to avoid warping or degradation. Material-specific care enhances durability and functionality. Wire racks, often constructed from stainless steel or epoxy-coated metal, benefit from ultrasonic baths filled with a mild detergent solution for thorough cleaning of crevices and slots, followed by rinsing and drying. In biological laboratories handling sensitive samples, UV sterilization cabinets emitting 253.7 nm wavelengths can be used to decontaminate racks without heat or chemicals, ensuring sterility for subsequent use. For wooden racks, which are less common in modern labs but still utilized in some educational settings, periodic application of a food-grade oil finish helps preserve the wood against drying and cracking, though these should not be autoclaved due to heat sensitivity. Proper storage is essential to maintain rack integrity between uses. Racks should be stored upright in a clean, dry environment away from direct , , and corrosive substances to prevent warping or material breakdown. Modular or stackable racks should be disassembled periodically to allow thorough airing and of components, reducing the of trapped or hidden . To extend lifespan, regular are recommended, focusing on signs of such as cracks, , or deformation in the tube-holding apertures. Damaged racks should be replaced promptly to avoid compromising workflows or , with practices like those outlined contributing to prolonged based on usage intensity.

Safety Considerations

Test tube racks are designed with stable bases to minimize the risk of tipping and subsequent breakage of contained tubes, particularly when placed on flat, level surfaces away from edges. This stability is essential in dynamic environments to prevent accidental knocks that could lead to spills or injuries. Manufacturers recommend adhering to load limits, typically supporting up to several kilograms depending on the rack's material and configuration, to avoid structural collapse under the weight of filled tubes. For instance, racks are engineered to hold dozens of tubes securely without deformation. Chemical hazards associated with test tube racks primarily arise from spills of corrosive or reactive substances, necessitating material compatibility to withstand exposure without degradation. Plastic racks made from offer resistance to acids, bases, and solvents commonly used in labs, unlike wooden variants which absorb liquids and are unsuitable for corrosive environments. Metal racks, such as those constructed from , provide enhanced durability against harsh chemicals and are preferred for applications involving fumes, where adequate ventilation must be maintained to mitigate risks. Compatibility charts guide selection to ensure racks do not react with contents, preventing secondary hazards like leaching or structural failure. Ergonomic features in test tube racks, such as integrated handles and anti-slip bases, facilitate safe transport and reduce the incidence of musculoskeletal strains or drops during handling. These design elements allow technicians to grip and move racks without awkward postures, addressing common lab accident causes like slips or improper lifting. By organizing tubes upright and preventing rolling, racks contribute to overall workspace safety, helping to lower the risk of minor injuries from unsecured glassware. In contexts, racks must feature easy-to-sterilize surfaces, such as autoclavable plastics or metals, to prevent microbial and cross-infection between samples. Guidelines recommend using racks within biological cabinets for aerosol-generating procedures and transporting cultures in secondary like racks to contain potential spills. trays or racks with leak-proof designs further minimize breakage-related biohazards, ensuring compliance with protocols for handling infectious agents. Regulatory adherence is critical, with test tube racks falling under OSHA standards for laboratory equipment stability and safe handling (29 CFR 1910.176), which require secure storage to prevent sliding, falling, or collapse. Labs must implement a Chemical Hygiene Plan incorporating these racks as to mitigate hazards from unstable setups, including regular inspections for wear that could compromise safety. Compliance ensures protection against chemical, biological, and physical risks in non-production settings.

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