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1 haI-assay and sequencing of cloned bisulfite PCR products).
2 of each clone for the presence or absence of PCR product.
3 or with the ss extension of the next-in-line PCR product.
4 above 95% in the central 56% of the average PCR product.
5 criptase (RT)-PCR and sequencing of the bulk PCR product.
6 d primers that amplify a Balamuthia-specific PCR product.
7 n unambiguous base composition for a 120-mer PCR product.
8 nblocked prior to hybridization with labeled PCR product.
9 , which were used in PCR to amplify a 137-bp PCR product.
10 done efficiently without purification of the PCR product.
11 ons when the 4-bromopyridone is present in a PCR product.
12 er from a linearized plasmid or from a crude PCR product.
13 strain typing, and Sanger sequencing of bulk PCR product.
14 igh-resolution melt analysis to characterize PCR products.
15 ous and seamless assembly of three different PCR products.
16 (SNP-PCR), and (3) optical detection of the PCR products.
17 electrospray ionization mass spectrometry of PCR products.
18 ifferentiation between predicted alternative PCR products.
19 ) patients with FPAH had abnormally sized RT-PCR products.
20 display method with quantitative analysis of PCR products.
21 pecies clones per patient from serum-derived PCR products.
22 PCR) and by analysis of the sequences of the PCR products.
23 gle-base mismatch cleavage of heteroduplexed PCR products.
24 he TSPY gene in both purified and unpurified PCR products.
25 PCR (RT-PCR) and restriction digestion of RT-PCR products.
26 eed for purification and denaturation of the PCR products.
27 opy, culture, and gel electrophoresis of the PCR products.
28 melting curves and denaturation profiles of PCR products.
29 ed and, thus, enhanced the brightness of the PCR products.
30 for TA cloning of polymerase chain reaction (PCR) products.
31 ect sequencing of polymerase chain reaction (PCR) products.
35 e variation (electrophoretic karyotypes) and PCR products (AFLP procedures) were determined for Micro
37 particular short polymerase chain reaction (PCR) product allowed this nonbinding sequence to overtak
38 the free primer and not the double-stranded PCR product, allowing real-time fluorescent quantificati
40 nal bisulfite capillary sequencing of cloned PCR products amplified from a subset of the selected reg
42 n different days, using different batches of PCR product and different sphere segment void (SSV) subs
45 the intrinsic charge of multiple unprocessed PCR products and does not require sample processing or a
48 tocol utilizes only submicroliter volumes of PCR products and is compatible with multiple capillary D
49 d oligochromatographic dipstick detection of PCR products and is highly sensitive for use in humans b
51 pancreatic tissue by sequence analysis of RT-PCR products and quantification using real-time PCR.
52 pancreatic tissue by sequence analysis of RT-PCR products and quantification using real-time PCR.
53 as confirmed by E1/\E4 reverse transcription-PCR products and RhPV-d sequence identity with the donor
54 approach based on different lengths of Aly8 PCR products and show that most A. lyrata haplotypes hav
57 , the replacement of human DNA template with PCR product, and the coating of the microchannel surface
58 trode surface as synthetic oligonucleotides, PCR products, and RNA transcripts are all detected with
59 m DNA was confirmed by sequencing the cloned PCR products, and while alignment of the ITS amplicons s
60 the adapter and the T-DNA; sequencing of the PCR products; and identification of the flanking sequenc
63 re 50-100 SNPs/capillary/run if the sizes of PCR products are arranged at every 5-10 bases from 100 t
69 abundant transcript generating a 1.2-kbp RT-PCR product) arising from an unspliced precursor likely
71 erating a 1.2-kbp reverse transcription [RT]-PCR product) as well as viral assembly on the cell membr
72 cle sequencing of polymerase chain reaction (PCR) products at kilobase scale, without conventional DN
73 tion discovery from the sequences of diploid PCR products, automated and reliable detection of indels
74 identified genes is then designed, with each PCR product being of a different size to allow multiplex
75 alytic activity of the MPNP, the analysis of PCR product bound MPNP yielded a sensitivity of 10(3) CF
76 ne synovial fluid) yielded an atypical oppA1 PCR product, but no atypical results were detected befor
77 ion abundance of the oligonucleotide and the PCR product by more than 6-fold relative to the best ach
79 ltaneous mutation scanning and genotyping of PCR products by high-resolution DNA melting analysis.
81 -labelled DNA was conveniently prepared from PCR products by lambda-exonuclease digestion and strepta
82 primers, followed by characterization of the PCR products by microchip hybridization with oligonucleo
83 immediately accessible protocol to quantify PCR products, by measuring ethidium bromide fluorescence
84 h polymorphisms detected among ITS1 and ITS2 PCR products can differentiate 20 of 33 species of molds
85 set, chronic infections, and the quality of PCR products can lower the MS score but never affected t
86 lution melting of polymerase chain reaction (PCR) products can detect heterozygous mutations and most
92 transcription polymerase chain reaction (RT-PCR) products confirmed the expression of five of these
93 or non-complementary 20-mer ssDNA or various PCR products consisting of 180-190 bp (dsDNA) were recor
95 ymorphism (SSCP) analysis was performed, and PCR products containing different patterns were cloned a
96 letion virus to form plaques was restored by PCR products containing single alanine substitutions wit
98 DNA fragments, indicating that the sizes of PCR products could be validated with an integrated chip-
99 two multiplex reverse transcription-PCR (RT-PCR) products coupled with microarray-based systems for
103 sizing fragments from restriction digests of PCR products derived from two sets of 16S rDNA-specific
104 ll unmethylated cytosine bases with thymine, PCR products derived from unmethylated templates contain
105 en mixed together, the linearized vector and PCR products directionally assemble into a recombinant m
106 uses truncated recombination sites to clone PCR products directly into destination/expression vector
108 was possible to detect hybridisation of mecA PCR product electrochemically at concentrations as low a
109 formation polymorphism (SSCP) analysis of RT-PCR products, elucidated the developmental and tissue-sp
110 topoisomerase-based method was used to clone PCR products encoding 991 of the 1041 open reading frame
112 on breakpoint generates orientation-specific PCR products, exemplified by a genotyping assay for the
114 thod involving the purification of multiplex PCR products followed by uniplex analysis on a microflui
115 determined using direct manual sequencing of PCR products, followed by resequencing separately amplif
116 a genus-specific restriction analysis of the PCR product for conclusive identification of the unknown
120 equencing of bulk polymerase chain reaction (PCR) products (for 22 couples), clonal analysis (for 3),
122 ing cDNA clones and quantifying 6FAM-labeled PCR products found that although the healthy mother pred
123 quences were derived by direct sequencing of PCR products from 21 plasma specimens diluted to end poi
124 ectrometry (PCR/ESI-MS), designed to amplify PCR products from any strain of influenza virus and to g
131 in vivo were verified by the presence of the PCR products from the promoter and enhancer elements in
132 al, where PCR duplicates arise from multiple PCR products from the same template molecule binding on
133 ative nucleotide sequence analysis of cloned PCR products from three affected cats further suggested
134 res ranging from 1/99 to 50/50 of two 285-bp PCR products from two cell lines that differ at one nucl
136 Pyrosequencing of domain amplicon and RCA PCR products generated 1.5 x 10(6) reads, including more
139 acked 3' homology to the cut vector, or both PCR products had both 5' and 3' homology to the cut vect
141 luorescence of dyes bound to double-stranded PCR products has been utilized extensively in various re
142 y of a 16.2 kDa oligonucleotide and a 53-mer PCR product in the high-pressure region between an elect
144 was used to directly sequence >100 bisulfite PCR products in a single sequencing run without subcloni
145 -mutagenesis only involves transformation of PCR products in bacteria expressing Red/ET recombineerin
146 ctions with Taq polymerase failed to produce PCR products in the presence of only small amounts of dt
147 r the GNAQ and GP1BB genes, different length PCR products in the range of 700 bases to 2 kilobases co
149 mbination in yeast for efficient assembly of PCR products into programmed or random combinations of m
151 the same order of magnitude as when a single PCR product is inserted alone into the display vector by
159 ied or unpurified polymerase chain reaction (PCR) products labeled with a fluorophore and a biotin ar
160 mology to the cut vector and the second scFv PCR product lacked 3' homology to the cut vector, or bot
161 regardless of whether or not one of the scFv PCR products lacked 5' homology to the cut vector and th
162 strated for synthetic targets (LOD = 10 nM), PCR products (LOD = 100 pM), and direct, amplification-f
163 positive-selection vector ideal for cloning PCR products, making DNA libraries, as well as routine c
164 ies for checking, sizing and separating both PCR products, nucleic acids derived from in vivo or in v
165 ified by sequencing of reverse transcriptase-PCR products obtained from oral mucosal tissues, disclos
169 lymer microspheres to capture a biotinylated PCR product of the oligonucleotide sequence, which was s
173 tibody repertoires by sequencing the 5'-RACE PCR products of B-cell transcripts from IAVI donor 17 an
176 he capability for the discrimination between PCR products of normal, heterozygous, and homozygous bet
177 of CD4, CXCR4, and CCR5, or in the amount of PCR products of reverse transcription, DNA synthesis, an
181 of the AGA926-928TTC H. pylori genotype and PCR products of two patients showed absence of the conse
182 present a method to identify single-stranded PCR products of varying lengths by hybridization of n-al
183 Cot, that measures the sequence diversity of PCR products on the basis of DNA hybridization kinetics,
184 a spotter for the deposition of the purified PCR products on the substrates and the purification step
185 loned DNA inserts to detailed analysis using PCR products or oligonucleotides of 100 bp or less.
186 ctly on the Escherichia coli chromosome with PCR products or synthetic single-stranded DNA (ssDNA) ol
187 relevant range and specifically detects the PCR products over reagents such as Taq polymerase and nu
188 cilitate the detailed analysis of bisulphite PCR products (particularly using multiple cloned templat
189 or protein-analysis, like DNA sequencing of PCR products, PCR-SSCP (polymerase chain reaction - sing
190 fully automated method to purify and desalt PCR products prior to analysis by electrospray ionizatio
191 ect sequencing of polymerase chain reaction (PCR) products, pyrosequencing, and cloning of PCR produc
193 ically feasible, and alternative methods for PCR product quantification can be expensive and time con
194 ust and simple method for direct, label-free PCR product quantification using an integrated microelec
195 imultaneously with detection of the Bcc recA PCR product; recA sequence cluster analysis also was par
196 previously published protocols: (i) smaller PCR products reduce primer numbers and amplification ste
197 , as well as with polymerase chain reaction (PCR) products related to different lineages of Mycobacte
199 althy donors using a microarray spotted with PCR products representing every gene from the seven S. a
200 acted from rats, we were able to demonstrate PCR products representing MOR1, MOR1(A), and MOR1(B) spl
202 ata are consistent with a model in which one PCR product results from the action of Tn5386 integrase,
203 kuADelta) strains of A. nidulans with fusion PCR products results in high frequencies of accurate gen
205 nd restriction enzyme digestion of this wbiI PCR product revealed sufficient DNA polymorphisms to dis
207 dditionally, sequence analysis of the 5'RACE-PCR products revealed multiple transcriptional start sit
213 f a portion of the DAPK promoter followed by PCR product sequencing confirmed dense hypermethylation
214 ungarotoxin binding and quantitative PCR and PCR product sequencing, we showed that the rat mast/baso
215 age charge states of the oligonucleotide and PCR product shifted from 12.5- to 14.5- and 10.9- to 12.
216 triction fragment length polymorphism of the PCR products showed that each of the four erythromycin-r
218 several microorganism taxa and sequenced all PCR products simultaneously by high-throughput sequencin
221 Detection of DNA restriction fragments and PCR product sizing is demonstrated using the electroacti
225 chain reaction (SP-PCR) to form the array of PCR products starting from the oligonucleotide primers.
228 a rapid method for the production of fusion PCR products that can be used, generally without band pu
229 ugh primer design, we can create a series of PCR products that vary in size and contain only one rest
231 electrolytes is presented with an unpurified PCR product, the tip surface electrostatically interacts
232 ING is dependent only on sufficient yield of PCR products, TILLING can be applied to most organisms.
233 tion (PCR), followed by hybridization of the PCR product to a fungus-specific oligonucleotide probe i
234 Additionally, the entire protocol from crude PCR product to an "electrosprayable" analyte solution re
240 med deligotyping, which hybridizes multiplex-PCR products to membrane-bound, highly specific oligonuc
241 ping assay involves reverse hybridization of PCR products to the capture spacers attached to nitrocel
242 t this streamlined protocol can be used with PCR products up to 1300 bp and had up to a 97% success r
243 DNA that was easily digested and yielded PCR products up to 8.5 kb in size was recovered from bro
246 for acquiring haplotypic sequences from long PCR products using simple, high-throughput techniques.
248 s have been used to directly detect specific PCR products utilizing the difference in adsorption of s
249 These were also the only strains to give PCR products (verifiable by sequencing) with degenerate
255 rae strain N16961 and found that no excision PCR product was produced, indicating that a functional c
256 romosome 8 (Acta1) so that the yield of each PCR product was proportional to the amount of its templa
261 lectrophoresis (DGGE) of a 16S ribosomal DNA PCR product was used to differentiate 32 mycoplasma spec
262 modified primers for the direct detection of PCR products was applied to the genotyping of real patie
263 plify these alleles, and the analysis of the PCR products was performed by capillary electrophoresis.
264 ime PCR with bidirectional sequencing of the PCR products was used to resolve discrepancies, the sens
284 n of desmosome-encoding genes was performed, PCR products were sequenced, and diseased tissue samples
287 CR) products, pyrosequencing, and cloning of PCR products were utilized to identify mutations in dhfr
288 synthetic DNA and polymerase chain reaction (PCR) products were accurately decoded, and a read length
290 or H. pylori strains and did not produce any PCR products when other Helicobacter species and other b
291 CR, stutter patterns may appear in the final PCR product, which hinder us from accurate genotyping mi
293 ten produce a high background of nonspecific PCR products, which can exclude the identification of th
294 combination is achieved by incubation of the PCR product with cells expressing lambda-Red proteins an
295 is step was also devised to dual-labeling of PCR products with biotin and 6-FAM, which are then easil
296 enosensor was suitable for discrimination of PCR products with different location of the complementar
297 me oxidase I, and 16S rRNA genes to generate PCR products with specific melting peaks that differenti
298 er amplification, the dU is excised from the PCR products with the USER enzyme leaving PCR products f
299 on by sequencing the pan-Plasmodium 18S rRNA PCR product, with correct identification in all cases.
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