Ever since Nuclear Magnetic Resonance (NMR) was first used in the mid-twentieth century, it became a crucial tool in modern chemistry. NRM has many useful applications for pharmaceutical and biotechnology companies.

It is projected that the global pharmaceutical industry will be worth $1,170 billion by 2021. As such, pharmaceutical companies are entrenched in a drug discovery race in order to increase their market share.

When it comes to drug discovery, Nuclear Magnetic Resonance (NMR) is an invaluable asset. By using spectrometers, scientists are able to analyze samples at a molecular level without damaging the sample. NMR spectrometers use permanent or electromagnets and can range from 60 MHz to 100 MHz.

In simple terms, these machines facilitate an in-depth analysis of molecular structures by providing different components of a molecule such as type, number of parts, and how they combine to form the molecule.

However, using low field NRM spectrometers has its fair share of challenges. This is because traditional machines are bulky, thus making it difficult for one person to move. They also break down frequently and require a lot of precautionary maintenance and repairs.

Also, outdated spectrometers need to be serviced regularly to ensure the on-board magnet is in peak condition. Fortunately, all these inconveniences are a thing of the past thanks to benchtop 100 MHz NMR spectrometers. In addition to their compact, lightweight design and portability, they come with advanced features, thus making them more efficient.

For chemists, a portable 100 MHz NMR is beneficial for the following reasons.

Makes Quantitative Data Acquisition Easier and Faster

In drug discovery, the ability and speed at which pharmaceuticals can obtain crucial data determine how soon new drugs reach the market. With a benchtop NMR, chemists can determine the relative and/or absolute molar ratios of different components in a solution. This is because these devices allow quick and easy use of relative integrations of resonances.

A Great Time Saver and Quality Backup

Benchtop NMRs can perform most of the tasks that high-field spectrometers are used to do. As such, they are a great alternative for chemists when a high-field model is unavailable. Also, portable spectrometers reduce the need for queuing in chemical laboratories as units can be placed in various laboratories.

Perfect Teaching Tool

Accessing spectrometers for learning has previously been challenging for students as the machines are bulky and only accessible from one place. However, a benchtop 100 MHz NMR spectrometer is an effective tool for teaching NRM spectroscopy to students.

These models give students greater exposure and allow them to take on a hands-on approach to learning. They will learn how to perform quantitative analysis and structurally confirm samples.

These practical skills are an essential part of drug discovery, and as such, the students will be all rounded.

Helps Reduce Costs

Conducting chemical tests is an expensive endeavor, and the costs have been rising gradually. As a result, it has become common practice for many laboratories to outsource their analytical needs.

A portable NMR is significantly cheaper than traditional models. As such, it is more convenient for chemists to own a device and conduct their analysis. In addition, benchtop models have lower maintenance costs as they require fewer additional repairs. Also, the ease and speed at which they can be used to make and pre-screen samples offer another avenue for saving money.

Portability

Unlike traditional models that could only be used from one point, benchtop spectrometers offer mobility. This allows chemists to move the spectrometer to different labs or the area of the lab where it is needed most.

In Conclusion

A chemist’s ability to conduct quantitative analysis and the time they get results greatly affects how fast they can progress their research. Fortunately, you do not have to send samples to other labs and wait for results to be sent anymore.

With a 100 MHz NMR, you can analyze samples in your lab and get quicker results, thus allowing your research to progress.