Laboratory Instrumentation

The Natural Sciences Laboratories and Field Facilities support practical learning experiences that fully complement the science courses and academic programs offered by the University.

Instrumentation

The Biology and Chemistry programs are housed mainly in the Unified Science Center where introductory and advanced laboratory courses in these disciplines are offered. Advanced instrumentation and research rooms are located within the Unified Science Center. Undergraduate teaching and research utilize the following instrumentation and equipment:

Agilent 1260 High Performance Liquid Chromatograph (HPLC) with diode array detector 

A pressure range of up to 600 bar with a flow rate up to 
5 mL/min allows the use of almost any column – conventional, sub-2 µm-particle or superficially porous columns. A UV, fluorescence or ELSD detector provides the data rate required for high resolution separations or fast analyses. 

Image of Agilent 1260 High Performance LIquid Chromatograph HPLC with diode array detector

Molecular Devices Gene Pix 4100A  

Genomics

  • SNP genotyping arrays
  • Arrayed comparative genomic hybridization (aCGH) arrays

Transcriptomics

  • Gene expression arrays
  • RNA interference (RNAi) arrays
  • MicroRNA (miRNA) arrays

Proteomics

  • Protein arrays
  • Peptide arrays
  • Antibody arrays
  • ELISA arrays
  • Reverse Phase Arrays

Epigenomics

  • DNA methylation arrays
  • Chromatin immunoprecipitation (ChIP) arrays

Novel Applications

  • Tissue arrays
  • Quantum Dots
  • Carbohydrate Arrays
  • Chemical Compound Arrays

Image of Molecular dvices Gene Pix 4100A and Spectramax M5 microplate reader spectrophotometer

Spectramax M5 microplate reader Spectrophotometer

The optical systems use two scanning monochromators so the user can determine optimal excitation and emission settings, resulting in assay performance similar to
that of dedicated single-mode readers.

Source: Molecular Devices: SpectraMax M Series Multi-Mode Microplate Readers Manual and Molecular Devices GenePix 4100A Microarray Scanner website

Perkin Elmer Tri Carb 3110TR Liquid Scintillation Analyzer

The Tri-Carb® 3110TR is a computer-controlled benchtop liquid scintillation analyzer for detecting small amounts of alpha, beta and gamma radioactivity.

 

Source: PerkinElmer Tri-Carb 3110TR Low Activity Liquid Scintillation Analyzer Spec Sheet

Image of the Tri Carb 3110TR liquid Scintillation Analyzer

 

Applied Biosystems Hitachi 3500 Genetic Analyzer

The Applied Biosystems 3500/3500xL Genetic Analyzers are fluorescence based DNA analysis instrument using capillary electrophoresis technology with 8- or 24-capillaries.

Source: Applied Biosystems 3500/3500XL Genetic Analyzer User Guide

Image of the Hitachi 3500 Applied Biosystems Genetic Analyzer

Instrumentation used in the 2019 1st Place NAMS symposium Analysis of Soil Bacteria for the Production of Antibiotics

Poster

 

Beckman CEQ8000XL Automated DNA Sequencer

This system is fully automated and capable of determining the base sequence and fragment length of DNA samples that have been prepared with dye-labeled reagents. Four-color, dye-labeled terminator chemistry kits are used to process samples for base sequence analysis. Generation of samples for fragment length analysis is performed using dye-labeled primers.

Source: CEQTM 8000 Genetic Analysis System User's Guide

Image of Beckman CEQ8000XL Automated DNA Sequencer

 

The Biomek® 3000 Laboratory Automation Workstation

The Biomek® 3000 Laboratory Automation Workstation is a multi-axis liquid handling instrument designed for benchtop use and to fit in a laminar flow or fume hood for sterile or hazardous operations. The open architecture design, along with the extensible operating software, provides a foundation for integrating current and future specific-use components.

The Biomek 3000 workstation is a single head instrument with a series of interchangeable tools. Different tools provide options for performing a variety of functions, including liquid transfer and plate washing operations and moving labware around the deck. The modular design of the Biomek 3000 workstation allows expansion of the instrument capabilities to include additional operations such as filtration, plate shaking, photometric microplate measurement, and high-capacity operation.

Image of the Beckman Biomek 3000 Laboratory Automation Workstation

Image of the Beckman Biomek 3000 Laboratory Automation Workstation

A variety of labware and hardware adapt the deck of the Biomek 3000 workstation to accomplish multiple tasks, ranging from performing simple labware positioning and liquid transfers to completing complex assays that typically require additional devices in the laboratory.

Source: Beckman Coutler Biomek® 3000 Laboratory Automation Workstation User's Manual

 

Coy Anaerobic Chamber

Used for anerobic microbiology research, these units are also critical to many other research areas such as protein purification, clinical microbiology, biochemistry, cell culture, human microbiome studies, biofuels and more. 

Source: Coylab.com/products/anareobic-chambers
 Image of student in front of Coy Anaerobic Chamber

 

 

Leica Microsystems Microscope

Precise 5W LED illumination ideal for cell and tissue culture, microamplification and live cell examinations.

 

Source: Leica Microsystems
Image of student looking through the Leica Microsystems Microscope 

Leica TCS SPE Confocal Microscope

Providing all of the features needed for routine confocal techniques, it offers excellent quality imaging. 

  • The common Leica LAS X interface facilitates direct operation.
  • Provides true spectral detection suitable for lambda scan.
  • Is intuitively controlled and even users who are new to confocal microscopy, will get publication-quality results immediately.

High Fideliity Specral Imaging

The prism-based spectral detection – unique to all Leica confocal microscopes – and a highly dynamic photomultiplier offer extraordinary signal efficiency for gapless detection of even weak signals. A variety of robust solid-state lasers allow the use of a broad range of common dyes.

Source: Leica Microsystems
Image of student looking through the Leica TCS Confocal Microscope 

Molecular Devices Gene Pix 4100A  

Genomics

Transcriptomics

Proteomics

Epigenomics

Novel Applications

Source: Moleculardevices.com

Spectramax M5 microplate reader Spectrophotometer

The optical systems use two scanning monochromators so the user can determine optimal excitation and emission settings, resulting in assay performance similar to
that of dedicated single-mode readers.

Source: Spectramax M Series Multi-Mode Microplate Readers User Manual

Image of Molecular dvices Gene Pix 4100A and Spectramax M5 microplate reader spectrophotometer

Seal Analytical AA3 Dissolved Nutrient Analyzer

Based on air Segmented Flow Analysis techniques (also known as Continuous Flow Analysis), the SEAL AutoAnalyzer 3 fully automates repetitive and complex sample analysis steps, from start-up to shutdown. The SEAL AA3 HR chemistry analyzer can also perform solvent extraction, distillation, gas diffusion, on-line filtration and in-line UV digestion in a continuously flowing stream. SEAL AA3 HR chemistry analyzers are fully supported with a library of over 700 documented applications including USEPA, ISO and ASTM standard methods.

Source: SealAnalytical.com

Image of Seal Analytical AA3 dissolved nutrient analyer

Image of Seal Analytical AA3 dissolved nutrient analyzer

 

XROMM Analyzer

X-Ray Reconstruction of Moving Morphology (XROMM) is a 3D imaging technology for visualizing rapid skeletal movement in vivo

XROMM combines 3D models of bone morphology with movement data from biplanar x-ray video to create highly accurate (±0.1 mm) re-animations of the 3D bones moving in 3D space. 

Rapid bone motion, such as during bird flight, frog jumping, and human running, can be visualized and quantified with XROMM.

Source: Xromm.org

Image of the XROMM Analyzer

Image of the XROMM Analyzer mobile c-arm fluroscope

 

Agilent 1260 High Performance Liquid Chromatograph (HPLC) with diode array detector 

A pressure range of up to 600 bar with a flow rate up to 
5 mL/min allows the use of almost any column – conventional, sub-2 µm-particle or superficially porous columns. A UV, fluorescence or ELSD detector provides the data rate required for high resolution separations or fast analyses. 

Source: labwrench.com

Image of Agilent 1260 High Performance LIquid Chromatograph HPLC with diode array detector

Agilent 7890B Gas Chromatographs (GC) with autosamplers and a variety of detectors: ECD, TCD, FID, MSD

Gas chromatography, coupled with static
headspace sampling, is an easy-to-use,
high-throughput tool for determining
residual solvent impurities in pharmaceutical
products. Sample preparation is simple, and
the method is easily validated. In addition,
headspace sampling allows you to avoid
matrix injections that can cause column
degradation and coelution.

Source: Agilent 7890B Gas Chromatograph brochure 

Image of Agilent 7890B Gas Chromatographs (GC) with autosmaplers and a variety of detectors: ECD, TCD, FID, MSD

Instrumentation used in the 2019 1st Place NAMS symposium Analysis of Soil Bacteria for the Production of Antibiotics

Poster

Image of Agilent 7890B Gas Chromatographs (GC) with autosamplers and a variety of detectors: ECD, TCD, FID, MSD

 

 

Agilent Cary Eclipse Fluorescence Spectrophotometer

The fibre optic capabilities extend the utility of the system for simplified measurement of solid samples outside the sample compartment or for the direct measurement of cold, hot, or potentially dangerous samples, down to very low volumes.

Food
  • Additives and supplements. Quality
    Assurance testing and monitoring
  • Authenticity and food origin
  • Food packaging and processing
    including hydrocarbon contamination
    through processing
Environmental
  • Preliminary Identification of hydrocarbon
    origin in oil spills using synchronous
    scanning
  • Waste water tracing into environmental
    flows by using fluorescent markers
  • Investigation of the source of organic
    matter pollution in river and sea water

Image of Agilent Cary Eclipse Flurescence Spectorphotometer

Chemical and Materials Applications
  • Determination of fluorescent properties
    of cleaning products
  • Investigation of the fluorescent
    properties of optical components
  • Analysis of surface contamination by
    fluorescent organic compounds in
    manufacturing processes
  • Polarized (anisotropy) measurements
    for understanding the molecular
    environment during polymer research
Source: Agilent Cary Eclipse Fluorescence Spectrophotometer spec sheet

Agilent 240 FS AA Flame Atomic Absorption Spectrophotometer Hollow Cathode Lamps

Atomic absorption spectrophotometry analyzes the concentration of elements in a liquid sample based on energy absorbed from certain wavelengths of light (usually 190 to 900 nm). Atomic absorption spectrophotometers typically include a flame burner to atomize the sample (most commonly a hollow cathode lamp), a monochromator, and a photon detector. Equipped with a turret or fixed lamp socket that can hold multiple lamps (up to eight) to reduce downtime between samples or allow for sequential analysis.

Typical sensitivity for an atomic absorption spectrometer using a flame burner is in the parts per million range. For trace analysis, a graphite furnace can be used in place of a flame burner to increase the sensitivity by several orders of magnitude (in the parts per billion range). Atomic absorption spectrophotometers are used in many industries including environmental testing, metal analysis, semiconductor manufacturing, petroleum and chemical production, and in pharmaceuticals, for example.

Source: labcompare.com

Image of Agilent 240 FS AA Flame Atomic Absorption Spectrophotometer Hollow Cathode Lamps

Bruker Advance 400 MHz Nuclear Magnetic Resonance (NMR) Spectrometer

Analytical nuclear magnetic resonance (NMR) solutions and instruments for life science and material research applications.

Nuclear magnetic resonance spectroscopy is used to study the structure of molecules, the interaction of various molecules, the kinetics or dynamics of molecules and the composition of mixtures of biological or synthetic solutions or composites.

The size of the molecules analyzed can range from a small organic molecule or metabolite, to a mid-sized peptide or a natural product, all the way up to proteins of several tens of kDa in molecular weight.

NMR nuclear spectroscopy complements other structural and analytical techniques such as X-ray, crystallography and mass spectrometry. NMR’s advantage is the unique ability of a nuclear spectrometer to allow both the non-destructive and the quantitative study of molecules in solution and in solid state, as well as to enable the study of biological fluids.

Source: bruker.com

 

 IMage of Bruker Advance 400 MHz NMR Spectrometer

CEM MARS 6 Microwave system

Microwave is a technique used to dissolve solid sample matrices into an aqueous liquid. This is achieved by placing a sample in a concentrated acid matrix in a closed vessel and exposing it to microwave irradiation. Both the speed of thermal decomposition of the sample, and the solubility of metals are increased. Once these metals are in solution, they can be quantified through spectroscopic techniques. The MARS 6 acid digestion process routinely cuts the time of sample preparation by 50 – 75 % as compared to hot plates and hot block.

Source: CEM.com

Image of the CEM MARS 6 Microwave System

 

Dionex 5000 Ion Chromatographs (IC)

Ideally suited for trace level determinations with high matrix concentrations, using a standard or microbore column in the first dimension to separate analytes from matrix, followed by a capillary separation in the second dimension. This method provides high sensitivity, enabling conductivity detection limits to rival those of mass spectrometry.

Source: ThermoFisher.com 

 

Image of Dionex 500 Ion Chromatograph (IC)

 

 

TA Instruments Q10 Differential Scanning Calorimeter (DSC)

The most common DSC application is the precise measurement of transition temperature.
Whether a melting temperature of a polymer
or the polymorphic transition of a pharmaceutical,
DSC provides the information quickly and easily on a minimum amount of sample. Important temperature measurements include:

  • Melting Temperature
  • Glass Transition Temperature
  • Thermal Stability Temperature
  • Oxidation Onset Temperature
  • Cure Onset Temperature
  • Crystallization Temperature
  • Polymorphic Transition Temperature
  • Liquid Crystal Temperature
  • Protein Denaturation Temperature
  • Solid-Solid Transition Temperature
Source: tainstruments.com/brochure

Image of Beckman CEQ8000XL Automated DNA Sequencer

Teledyne Leeman Labs Hydra II Mercury Analyzer

It is a fully automated turnkey analyzer that measures mercury in solid and semi-solid sample matrices directly without any acid digestion (sample preparation). The system employs the technique of sample combustion (thermal decomposition), mercury concentration via gold amalgamation and detection by cold vapor atomic absorption.

Source: teledyneleemanlabs.com

Image of Teledyne Leeman Labs Hydra II Mercury Analyzer

 

Thermo Nicolet iS5 FTIR with ATR attachment

Infrared spectroscopy is the analytical technique for rapid identification of unknown materials (solids, liquids and gases) and product quality screening. 

Source: fishersci.com

Image of Thermo Nicolet iS5 FTIR with ATR attachment

 

Thermo Nicolet iS50 FTIR Spectrometer with ATR and multi-range beam splitter

The Nicolet iS50 analyzes complex mixtures and materials using its GC-IR or TGA-IR capabilities. The new OMNIC Mercury software automatically isolates and identifies compounds eluted from a GC column or evolved from a TGA. This functionality is especially useful in TGA, where several compounds can evolve at the same time. Such analyses provide insight into subtle formulation differences in plastics and rubbers, which can lead to not-so-subtle differences in product performance and quality.

Source: News-medical.net

IMage of Thermo Nicolet iS50 FTIR with ATR and multi-range beam splitter

 

 

Nicolet FT-IR Spectrometer

Uses infrared energy to excite the atoms of a material. The spectrum of the light absorbed and transmitted as the atoms vibrate provides a fingerprint of the structure of the molecules in the sample. This fingerprint can used to identify the chemical bonds present in the sample.

The Nicolet 6700 is currently equipped with a diamond crystal single bounce attenuated total reflectance (ATR) attachmen

Image of Thermo Nicolet iS5 FTIR with ATR attachment

Rigaku MiniFlex 600 X-ray Diffractometer (powder) with 6-sample changer

MiniFlex X-ray diffractometer (XRD) is a multipurpose analytical instrument that can determine: phase identification and quantification, percent (%) crystallinity, crystallite size and strain, lattice parameter refinement, Rietveld refinement, and molecular structure. It is widely used in research, especially in material science and chemistry, as well as in industry for research and quality control.

Source: Rigaku.com 

Image of Rigaku MiniFlex 600 X-ray Diffractometer (powder) with 6-sample changer

Rigaku XtaLAB mini X-ray Diffractometer (single crystal) (XRD)

The Rigaku XtaLAB, benchtop X-ray crystallography system, is a compact single crystal X-ray diffractometer designed to produce publication-quality 3D structures. Rapidly analyze new compounds as they are synthesized in the lab.

Source: Rigaku.com

IMage of Rigaku XtaLAB mini X-Ray Diffractometer (single crystal)

Coming Soon

 

 

Coming Soon

 

 

NanoMagnetics Atomic Force Microscope (AFM)

Create images of atoms and map the surface structure materials. Offers Excellent features such as alignment-free design, closed loop flexure scanner, decoupled z scanner, 10 MP video microscope and flexible operating modes.

Source: Nanomagnetics Atomic Force Microscope Flyer

 Image of ÀÏ˾»ú¸£ÀûÉç physics instrumentation, atomic force microscope

More Coming Soon

 
 

Coming Soon

 

Facilities

The School of Natural Sciences and Mathematics (NAMS) requires an extensive on-campus and off-campus infrastructure to accomplish its academic mission in the different scientific disciplines.

Most of the infrastructure is located on the Galloway campus in the Arts and Sciences (A&S) building, and the Academic Quad comprised of three newly constructed buildings (2013-2018): Unified Science Center 1 (USC1), Unified Science Center 2 (USC2) and the John F. Scarpa Health Sciences Center (HSC), which is home to the Sustainability Program. A short 15-minute drive from the Galloway campus, you will arrive at the NAMS Marine Field Station (MFS) that serves as a launch point for the University’s fleet of research vessels, as well as the site of the University’s Coastal Research Center (CRC). Other areas on campus which also support the mission of NAMS are the Arboretum, Observatory, Sustainability Farm, Greenhouses, Vivarium, and open spaces for forestry and marine field research. 

Image of Unified Science Center II

The Unified Science Center 2 (USC2) is a  state-of-the-art facilities will allow ÀÏ˾»ú¸£ÀûÉç to accommodate more students and better prepare them for successful careers in science, technology, engineering and mathematics (STEM).  The academic quad expansion will include the $33.2 million USC2 and a $15.2 million John F. Scarpa Health Sciences Center, near the existing Unified Science Center and Campus Center. The new buildings will be supported by funding from the Building Our Future Bond Act, which was overwhelmingly approved by New Jersey voters in 2012. The bond act will provide $21.465 million in funding for the USC2 and the University will pay 25 percent or $7.155 million. The John F. Scarpa Health Sciences Center will receive $13.5 million in funding from the bond issue and the University will pay 25 percent or $4.5 million.

The main entrance of the academic quad will face Vera King Farris Drive and will provide a central location for students to study and meet between classes, as well as space for the University community to gather for campus events.  The 58,210 thousand square foot Unified Science Center 2 will be an expansion to the existing 64,000-square-foot Unified Science Center. The three-story building will house teaching and research labs for various disciplines in the sciences, a vivarium, a large green house, a multi-purpose room and faculty offices. The 37,720-square-foot John F. Scarpa Health Sciences Center will include space for the Sustainability program, classrooms, faculty offices and collaboration areas with tables and chairs.

Picture of the ÀÏ˾»ú¸£ÀûÉç Marine Field Station sign

The Marine Field Station is located on an 8-acre parcel in Port Republic, New Jersey which is located within the Jacques Cousteau National Estuarine Research Reserve. It is conveniently located within 30 minutes of the Galloway and Atlantic City campuses – 15 minutes from Galloway and 30 minutes from the Atlantic City campus. The MFS is also the site of the University’s Coastal Research Center. The MFS offers laboratories and support facilities to provide access to an array of resources including vessels, sampling equipment, and marine science technology instrumentation. The inshore research fleet consists of shallow-draft vessels ranging from 16’ – 24’ and the flagship vessel, the R/V Petrel, which is 36’ x 14’. The marine operations staff provide support services and oversee the maintenance and use of the facilities, vessels, instrumentation and sampling equipment. The MFS is a University National Oceanographic Laboratory System (UNOLS) member and an organizational member of multiple professional societies, including National Association of Marine Laboratories, Organization of Biological Field Stations, Scientific Boating Safety Association, Marine Technology Society, and the Hydrographic Society of America.

Aerial view of Marine Field Station

 

The Vivarium is located in USC2 and supports a variety of research and teaching display animals. One full-time and one part-time staff member oversee the 7 day-a-week care for the animals. The Vivarium is home to the terrapin project which rehabilitates injured terrapins and also cares for mice under an NIH funded research project. Many different species of rodents, fish, amphibians, and reptiles are also housed in this secured area, which is only accessible to properly trained faculty, staff, and students who have been trained in handling the various animals.

Image of terrapins

Image of terrapin eggs

There are three Greenhouses located in different locations across the main campus (USC2, Arts & Sciences, and the Sustainability Farm) and are used for both teaching and research. The greenhouses are maintained by two staff members and student workers.
The USC2 greenhouse is the main location for the laboratory plant courses which has a large headhouse used for teaching students proper growing techniques. It houses a large variety of plants used for teaching, research and laboratory display. This greenhouse is also used in collaboration with other schools within the university, as well as outreach events. The A&S greenhouse is a small addition to the building used for soil analysis within the geology and environmental science classes. The Sustainability Farm on campus has a large mobile greenhouse that allows a variety of plants to be grown in a unique environment. This is a great experimental area for teaching and research which also extends the opportunity for off-season growing. The Sustainability greenhouses are used extensively for organic research and laboratory activities.

Image of greenhouse

Image of greenhouse

The Harold E. Taylor Observatory located off Pomona Road, on the west campus, houses a 0.4 m Meade computer-controlled reflector telescope. It also contains two computers controlled, portable reflector telescopes (8 inch and 6 inch). The Observatory is used for teaching General Astronomy courses to an average of 70 students per semester, and a hybrid Astrophysics course. It is also used for research and outreach programs. Observation nights are open to the ÀÏ˾»ú¸£ÀûÉç community and the general public and are held approximately twice a month, weather permitting. For more information please visit the observatory website.

Image of the telescope

Image of the observatory

The Sustainability Farm was established in 2012 as a student-run project. The farm productivity and campus visibility has increased significantly relative to previous years. The infrastructure expanded to include a 30’x48’ high tunnel-greenhouse, increased water storage, solar power and storage, and a new fence which increased the production area from one-third of an acre to1.5 acres. A new structure for student involvement was introduced; students can now enroll in a Farm Practicum each semester, which ensures their commitment, and  formalizes the academic aspect of farm participation. Enrolled students produce and sell organic crops at the weekly farmers market on and off campus. The farm also has a large mobile greenhouse structure that can be moved to create different environments throughout the seasons and allows for the extension of the growing season for a variety of crops. Students practice hands-on training in sustainable agriculture through the use of sustainable practices such as solar and geothermal energy use, rainwater collection-based irrigation and sustainable farming methods. For more information, please visit the farm website. 

Aerial image of the ÀÏ˾»ú¸£ÀûÉç sustainable farm

Image of vegetables grown on the sustainable farm

The Arboretum is a 3-acre area located off Vera King Farris Drive on the southern part of the campus. It contains over 80 specimens of trees and shrubs, and eight raised beds containing many display and medicinal plants. The area has an underground pipe network to support a computer-controlled irrigation system. The arboretum is the site of applied forest ecology research by Dr. Matt Olson and the current site of community ecology and maple sugaring research by Dr. Judy Vogel.