Atic digestion to attain the desired target length of 100?00 bp fragments is not necessary for AG 120 sequencing small RNAs, which are usually considered to be shorter than 200 nt (110). For miRNA sequencing, fragment sizes of adaptor ranscript complexes and adaptor dimers hardly differ in size. An accurate and reproducible size selection procedure is therefore a crucial element in small RNA library generation. To assess size selection bias, Locati et al. used a synthetic spike-in set of 11 oligoribonucleotides ranging from 10 to 70 nt that was added to each biological sample at the beginning of library preparation (114). Monitoring library preparation for size range biases minimized technical variability between samples and experiments even when allocating as little as 1? of all sequenced reads to the spike-ins. Potential biases introduced by purification of individual size-selected products can be reduced by pooling barcoded samples before gel or bead purification. Since small RNA library preparation products are usually only 20?0 bp longer than adapter dimers, it is strongly recommended to opt for an electrophoresis-based size selection (110). High-resolution matrices such as MetaPhorTM Agarose (Lonza Group Ltd.) or UltraPureTM Agarose-1000 (Thermo Fisher Scientific) are often employed due to their enhanced separation of small fragments. To avoid sizing variation between samples, gel purification should ideallybe carried out in a single lane of a high resolution agarose gel. When working with a limited starting quantity of RNA, such as from liquid biopsies or a small number of cells, however, cDNA libraries might have to be spread across multiple lanes. Based on our expertise, we recommend freshly preparing all solutions for each gel a0023781 electrophoresis to obtain KN-93 (phosphate) site maximal reproducibility and optimal selective properties. Electrophoresis conditions (e.g. percentage of the respective agarose, dar.12324 buffer, voltage, run time, and ambient temperature) should be carefully optimized for each experimental setup. Improper casting and handling of gels might lead to skewed lanes or distorted cDNA bands, thus hampering precise size selection. Additionally, extracting the desired product while avoiding contaminations with adapter dimers can be challenging due to their similar sizes. Bands might be cut from the gel using scalpel blades or dedicated gel cutting tips. DNA gels are traditionally stained with ethidium bromide and subsequently visualized by UV transilluminators. It should be noted, however, that short-wavelength UV light damages DNA and leads to reduced functionality in downstream applications (115). Although the susceptibility to UV damage depends on the DNA’s length, even short fragments of <200 bp are affected (116). For size selection of sequencing libraries, it is therefore preferable to use transilluminators that generate light with longer wavelengths and lower energy, or to opt for visualization techniques based on visible blue or green light which do not cause photodamage to DNA samples (117,118). In order not to lose precious sample material, size-selected libraries should always be handled in dedicated tubes with reduced nucleic acid binding capacity. Precision of size selection and purity of resulting libraries are closely tied together, and thus have to be examined carefully. Contaminations can lead to competitive sequencing of adaptor dimers or fragments of degraded RNA, which reduces the proportion of miRNA reads. Rigorous quality contr.Atic digestion to attain the desired target length of 100?00 bp fragments is not necessary for sequencing small RNAs, which are usually considered to be shorter than 200 nt (110). For miRNA sequencing, fragment sizes of adaptor ranscript complexes and adaptor dimers hardly differ in size. An accurate and reproducible size selection procedure is therefore a crucial element in small RNA library generation. To assess size selection bias, Locati et al. used a synthetic spike-in set of 11 oligoribonucleotides ranging from 10 to 70 nt that was added to each biological sample at the beginning of library preparation (114). Monitoring library preparation for size range biases minimized technical variability between samples and experiments even when allocating as little as 1? of all sequenced reads to the spike-ins. Potential biases introduced by purification of individual size-selected products can be reduced by pooling barcoded samples before gel or bead purification. Since small RNA library preparation products are usually only 20?0 bp longer than adapter dimers, it is strongly recommended to opt for an electrophoresis-based size selection (110). High-resolution matrices such as MetaPhorTM Agarose (Lonza Group Ltd.) or UltraPureTM Agarose-1000 (Thermo Fisher Scientific) are often employed due to their enhanced separation of small fragments. To avoid sizing variation between samples, gel purification should ideallybe carried out in a single lane of a high resolution agarose gel. When working with a limited starting quantity of RNA, such as from liquid biopsies or a small number of cells, however, cDNA libraries might have to be spread across multiple lanes. Based on our expertise, we recommend freshly preparing all solutions for each gel a0023781 electrophoresis to obtain maximal reproducibility and optimal selective properties. Electrophoresis conditions (e.g. percentage of the respective agarose, dar.12324 buffer, voltage, run time, and ambient temperature) should be carefully optimized for each experimental setup. Improper casting and handling of gels might lead to skewed lanes or distorted cDNA bands, thus hampering precise size selection. Additionally, extracting the desired product while avoiding contaminations with adapter dimers can be challenging due to their similar sizes. Bands might be cut from the gel using scalpel blades or dedicated gel cutting tips. DNA gels are traditionally stained with ethidium bromide and subsequently visualized by UV transilluminators. It should be noted, however, that short-wavelength UV light damages DNA and leads to reduced functionality in downstream applications (115). Although the susceptibility to UV damage depends on the DNA’s length, even short fragments of <200 bp are affected (116). For size selection of sequencing libraries, it is therefore preferable to use transilluminators that generate light with longer wavelengths and lower energy, or to opt for visualization techniques based on visible blue or green light which do not cause photodamage to DNA samples (117,118). In order not to lose precious sample material, size-selected libraries should always be handled in dedicated tubes with reduced nucleic acid binding capacity. Precision of size selection and purity of resulting libraries are closely tied together, and thus have to be examined carefully. Contaminations can lead to competitive sequencing of adaptor dimers or fragments of degraded RNA, which reduces the proportion of miRNA reads. Rigorous quality contr.