The life sciences labs of the future will require skills in automation, open source technologies, artificial intelligence, and many other emerging areas. Here's what you need to know. In the early 21st century, wet laboratory skills in molecular biology, cell biology, and proteomics are key for anyone seeking a life sciences career. While expertise in these areas remains essential, future laboratories will require different skill sets based on emerging trends in research and technology.

Here are six skill areas we think it’s helpful to familiarize yourself with to advance your career and prepare you for the life sciences lab of the future.

1. 自動(dòng)化知識(shí)
   2018 年世界經(jīng)濟(jì)論壇上發(fā)表的研究發(fā)現(xiàn)影響，到 2025 年參與水平，自動(dòng)化設(shè)備預(yù)計(jì)將執(zhí)行當(dāng)今一半以上的任務(wù)。機(jī)器人還將在相當(dāng)?shù)臅r(shí)間內(nèi)創(chuàng)造約 6000 萬個(gè)新工作崗位組織了。到 2026 年，僅液體處理機(jī)器人市場(chǎng)規(guī)模就預(yù)計(jì)將超過 70 億美元多元化服務體系，很難想象在不久的將來服務水平，自動(dòng)化技術(shù)不會(huì)為你的簡(jiǎn)歷增色不少認為。

Automation offers significant advantages to life science researchers, including improved data quality, increased cost efficiency, scalability, and more time to do other things in the lab other than repeat experiments. Automation also benefits new complex biotechnologies such as next-generation sequencing or mass spectrometry proteomic analysis, which require increasingly complex workflows that are sometimes too complex and time-consuming for humans to successfully execute. Automated innovation and capabilities are proliferating as the need for speed and throughput increases in drug discovery, diagnostics and even basic research.

Given the huge potential for fully automated workflows, many research labs are taking scientists away from lab work—pulling them off their benches and putting them in front of their computers to design experiments for lab robots to complete instead. Execute it yourself. This more effectively leverages scientists' understanding of biology, leaving repetitive lab work to robots so biologists can solve difficult scientific questions.

Ginkgo Bioworks designs custom organisms for customers and builds its own factories, leveraging software and hardware automation to scale the process. Synthego is the first and only company to offer full-stack genome engineering solutions, achieving this by leveraging cloud-based software automation. Synthace utilizes both hardware and software to aid large-scale automated laboratories. Of course, hundreds of biologists around the world use Opentrons software and hardware to automate protocols and workflows for a variety of experiments, from basic dilutions to PCR prep and NGS. Exploring how these companies are using automation will help you understand how automation is changing life science research.

2. Open source, collaboration and shareability skills

Open source refers to software whose source code is free for anyone to view, use, modify, and share. It allows users to build and learn from existing code, while promoting and encouraging collaboration and innovation among users around the world.

Open source applications in the life sciences are used to ingest the vast data sets produced by genomics and other related applications, such as the Ensembl Genome Browser database, which makes genomic and other related data accessible to any interested user. Open source computing technology is also used to model and simulate organisms: OpenWorm uses it to create virtual nematodes, while Virtual Cell uses it to model and simulate cells, and epidemiological researchers share genomic data to speed up pathogen analysis and identify the source of outbreaks. .

As the use of open source in life science disciplines continues to evolve, practical expertise in coding and data sharing methods will become a major asset for life scientists – so becoming familiar with some of these tools now will give you an advantage in the future. A good place to start is with open source protocol sharing platforms, such as Protocols.io and the Opentrons protocol library, which allow scientists to discover and co-develop protocols, and Plasmotron.org, which allows users to build on open source code.

3. 科學(xué)傳播
   雖然所有科學(xué)家都通過科學(xué)演講、研究論文向好態勢、文獻(xiàn)綜述和參加會(huì)議來相互交流他們的工作平臺建設，但他們需要使用不同的方法與公眾交流。

The ability to effectively communicate the applications and impact of life science research to non-technical audiences creates important connections between scientists and society. Effective communication in this area involves using non-technical, plain language, making concepts easy to understand, and learning how to reach and engage the public. Practicing both disciplines encourages important discussion and debate and makes knowledge about scientific developments transparent and accessible to everyone. You can join thousands of biologists working to improve science communication and hone your science communication skills by participating in voluntary science outreach events, sharing your research activities on social media, or creating your own science blog or podcast.

4. 機(jī)器學(xué)習(xí)和人工智能
   雖然聽起來很有未來感貢獻力量，但我們每天都被機(jī)器學(xué)習(xí)輔助的人工智能應(yīng)用所包圍：智能手機(jī)上的語音助手使用、網(wǎng)站上的實(shí)時(shí)聊天功能、社交媒體推送中的定向廣告等等發行速度。這些應(yīng)用利用復(fù)雜的算法和海量數(shù)據(jù)集來訓(xùn)練計(jì)算機(jī)像人類一樣工作和反應(yīng)更加堅強。這個(gè)過程改進(jìn)了計(jì)算機(jī)的學(xué)習(xí)過程，使它們?cè)陧憫?yīng)條件和產(chǎn)生結(jié)果方面更加高效——迅速提高了未來發(fā)現(xiàn)的速度結構。

In the life sciences, machine learning has revolutionized the speed of research and diagnosis through its ability to distinguish cells, analyze genomic data, perform image analysis and detect indicators of disease earlier and more sensitively than previous methods. One major growth area is using machine learning to design experiments. Asimov uses open source data to develop machine learning algorithms that connect large-scale data sets with biological mechanistic models to build biological circuit experiments. Cello uses machine learning to automatically design biological circuits in living cells. Another major growth area is bioinformatics. Deep Genomics uses machine learning to collect, analyze and process genomic data to develop better, more targeted medicines. Some companies, like Atomwise, are even using deep learning frameworks to try to screen drug candidates in software. Familiarity with these emerging applications will help you understand the future uses of this technology.

5. 使用 CRISPR 進(jìn)行基因編輯
   2000 年代中期發(fā)現(xiàn)的 CRISPR 是生命科學(xué)的一個(gè)轉(zhuǎn)折點(diǎn)更適合，因?yàn)樗捎糜诨蚬こ獭ｋm然我們現(xiàn)在都熟悉 CRISPR 平臺(tái)溝通協調，但基因編輯平臺(tái)的應(yīng)用影響深遠(yuǎn)——并且經(jīng)常與許多其他新興領(lǐng)域重疊要素配置改革。Oxford Genetics 提供用于基因編輯的實(shí)驗(yàn)設(shè)計(jì)工具，幫助簡(jiǎn)化工作流程保障性。Synthego 再次利用機(jī)器學(xué)習(xí)來推動(dòng)基因工程中的實(shí)驗(yàn)設(shè)計(jì)帶動產業發展。 CRISPR Therapeutics 利用 CRISPR 基因編輯平臺(tái)開發(fā)針對(duì)血液疾病（如鐮狀細(xì)胞性貧血）的藥物持續發展，而 Caribou Biosciences必然趨勢、Editas Medicine 和 Cellectis 則利用 CRISPR 和其他基因編輯技術(shù)（如 TALEN）來修改 T 細(xì)胞以針對(duì)癌細(xì)胞。

With the global CRISPR market expected to grow six-fold to $3 billion by 2023, opportunities to leverage gene-editing tools in future life science labs should be numerous.

6. 單細(xì)胞技術(shù)
   快速發(fā)展的技術(shù)允許將蛋白質(zhì)組學(xué)擴大、基因組學(xué)多樣性、轉(zhuǎn)錄組學(xué)和表觀遺傳學(xué)技術(shù)應(yīng)用于單細(xì)胞，為控制發(fā)育新格局、基因表達(dá)明顯、組織異質(zhì)性和疾病機(jī)制的復(fù)雜生物過程提供了新穎而關(guān)鍵的見解。這些技術(shù)對(duì)于分析循環(huán)腫瘤細(xì)胞和稀有干細(xì)胞等生物現(xiàn)象特別有用顯示，而這些現(xiàn)象對(duì)于標(biāo)準(zhǔn)“組學(xué)”應(yīng)用來說具有挑戰(zhàn)性創新為先，甚至是不可能的。基因組編輯創新延展、自動(dòng)化和微流控技術(shù)的同步發(fā)展進(jìn)一步促進(jìn)了單細(xì)胞應(yīng)用中常見的較小樣本的快速高通量分析強化意識。10x Genomics 使用單細(xì)胞癌癥基因組學(xué)檢測(cè)來分析癌細(xì)胞。Metafluidics 是一個(gè)用于復(fù)制或重新混合微流控設(shè)備的開源設(shè)計(jì)和協(xié)議文件數(shù)據(jù)庫基本情況，是該領(lǐng)域的一個(gè)很好的信息存儲(chǔ)庫現場。

Growth in the single-cell analysis field is driven by basic research and growing demand for early disease detection technologies, prenatal screening, biomarker discovery, liquid biopsies, and biopharmaceutical development.