Hereditary Pancreatic Cancer Panel

Summary
Is a 22 gene panel that includes assessment of non-coding variants.

Is ideal for patients with a clinical suspicion of an inherited susceptibility to pancreatic cancer. This panel is designed to detect heritable germline mutations and should not be used for the detection of somatic mutations in tumor tissue.

Analysis methods
  • PLUS
Availability
4 weeks
Number of genes
22
Test code
ON0301
Panel tier
Tier 2
CPT Code *
81162, 81201, 81203, 81292, 81294, 81295, 81297, 81298, 81300, 81307, 81317, 81319, 81351, 81403 x2, 81404 x4, 81405 x4, 81406 x3, 81407 , 81408 x2, 81479
* The CPT codes provided are based on AMA guidelines and are for informational purposes only. CPT coding is the sole responsibility of the billing party. Please direct any questions regarding coding to the payer being billed.

Summary

The Blueprint Genetics Hereditary Pancreatic Cancer Panel (test code ON0301):

Read about our accreditations, certifications and CE-marked IVD medical devices here.

ICD Codes

Refer to the most current version of ICD-10-CM manual for a complete list of ICD-10 codes.

Sample Requirements

  • Blood (min. 1ml) in an EDTA tube
  • Extracted DNA, min. 2 μg in TE buffer or equivalent
  • Saliva (Please see Sample Requirements for accepted saliva kits)

Label the sample tube with your patient’s name, date of birth and the date of sample collection.

We do not accept DNA samples isolated from formalin-fixed paraffin-embedded (FFPE) tissue. In addition, if the patient is affected with a hematological malignancy, DNA extracted from a non-hematological source (e.g. skin fibroblasts) is strongly recommended.

Please note that, in rare cases, mitochondrial genome (mtDNA) variants may not be detectable in blood or saliva in which case DNA extracted from post-mitotic tissue such as skeletal muscle may be a better option.

Read more about our sample requirements here.

Pancreatic ductal carcinoma makes up the vast majority (90%) of all pancreatic neoplasms and remains a disease with very poor prognosis and high morbidity. Familial aggregation has been recognized in approximately 10% of pancreatic cancers. Familial pancreatic cancer is defined as a family with at least one pair of first-degree relatives (parent-child or sibling pair) with pancreatic cancer without an identifiable syndrome in the family. Inherited pancreatic cancer is genetically highly heterogenous and has been associated with germline mutations in ATM, BRCA2, CDKN2A, and PALB2, among others (PMID: 26658419). Increased susceptibility to pancreatic cancer may also be associated with different cancer syndromes such as hereditary breast and ovarian cancer syndrome, Lynch syndrome, ataxia telangiectasia, and familial adenomatous polyposis (PMID: 23187834). Genetic diagnosis of familial pancreatic cancer offers opportunities for personalized therapies (PMID: 25719666).

Genes in the Hereditary Pancreatic Cancer Panel and their clinical significance

To view complete table content, scroll horizontally.

Gene Associated phenotypes Inheritance ClinVar HGMD
APC Gardner syndrome, Desmoid disease, hereditary, Familial adenomatous polyposis AD 773 1926
ATM Breast cancer, Ataxia-Telangiectasia AD/AR 1047 1109
BMPR1A* Polyposis, juvenile intestinal AD 110 140
BRCA1* Pancreatic cancer, Breast-ovarian cancer, familial, Fanconi anemia AD 2997 2631
BRCA2 Fanconi anemia, Medulloblastoma, Glioma susceptibility, Pancreatic cancer, Wilms tumor, Breast-ovarian cancer, familial AD/AR 3369 2659
BUB1B Mosaic variegated aneuploidy syndrome, Premature chromatid separation trait AD/AR 14 28
CDKN2A Melanoma, familial, Melanoma-pancreatic cancer syndrome AD 87 232
EPCAM Diarrhea 5, with tufting enteropathy, congenital, Colorectal cancer, hereditary nonpolyposis AD/AR 38 80
FANCC Fanconi anemia AR 94 64
MEN1 Hyperparathyroidism, familial primary, Multiple endocrine neoplasia AD 263 730
MLH1 Muir-Torre syndrome, Endometrial cancer, Mismatch repair cancer syndrome, Colorectal cancer, hereditary nonpolyposis AD/AR 873 1191
MSH2 Muir-Torre syndrome, Endometrial cancer, Colorectal cancer, hereditary nonpolyposis,, Mismatch repair cancer syndrome AD/AR 933 1249
MSH6 Endometrial cancer, Mismatch repair cancer syndrome, Colorectal cancer, hereditary nonpolyposis AD/AR 672 586
NF1* Watson syndrome, Neurofibromatosis, Neurofibromatosis-Noonan syndrome AD 1157 2901
PALB2 Fanconi anemia, Pancreatic cancer, Breast cancer AD/AR 495 406
PMS2* Mismatch repair cancer syndrome, Colorectal cancer, hereditary nonpolyposis AD/AR 319 342
SMAD4 Juvenile polyposis/hereditary hemorrhagic telangiectasia syndrome, Polyposis, juvenile intestinal, Myhre dysplasia, Hereditary hemorrhagic telangiectasia AD 179 143
STK11 Peutz-Jeghers syndrome AD 173 460
TP53 Colorectal cancer, Li-Fraumeni syndrome, Ependymoma, intracranial, Choroid plexus papilloma, Breast cancer, familial, Adrenocortical carcinoma, Osteogenic sarcoma, Hepatoblastoma, Non-Hodgkin lymphoma AD 393 505
TSC1 Lymphangioleiomyomatosis, Tuberous sclerosis AD 177 372
TSC2 Lymphangioleiomyomatosis, Tuberous sclerosis AD 396 1195
VHL Erythrocytosis, familial, Pheochromocytoma, Von Hippel-Lindau disease AD/AR 206 614
#

The gene has suboptimal coverage (means <90% of the gene’s target nucleotides are covered at >20x with mapping quality score (MQ>20) reads), and/or the gene has exons listed under Test limitations section that are not included in the panel as they are not sufficiently covered with high quality sequence reads.

*

Some, or all, of the gene is duplicated in the genome. Read more.

The sensitivity to detect variants may be limited in genes marked with an asterisk (*) or number sign (#). Due to possible limitations these genes may not be available as single gene tests.

Gene refers to the HGNC approved gene symbol; Inheritance refers to inheritance patterns such as autosomal dominant (AD), autosomal recessive (AR), mitochondrial (mi), X-linked (XL), X-linked dominant (XLD) and X-linked recessive (XLR); ClinVar refers to the number of variants in the gene classified as pathogenic or likely pathogenic in this database (ClinVar); HGMD refers to the number of variants with possible disease association in the gene listed in Human Gene Mutation Database (HGMD). The list of associated, gene specific phenotypes are generated from CGD or Mitomap databases.

Non-coding variants covered by Hereditary Pancreatic Cancer Panel

To view complete table content, scroll horizontally.

Gene Genomic location HG19 HGVS RefSeq RS-number
APC Chr5:112043009-112043595
APC Chr5:112043220 c.-195A>C NM_001127511.2
APC Chr5:112043223 c.-192A>G/T NM_001127511.2
APC Chr5:112043223 c.-192A>G NM_001127511.2 rs879253784
APC Chr5:112043223 c.-192A>T NM_001127511.2
APC Chr5:112043224 c.-191T>C NM_001127511.2
APC Chr5:112043225 c.-190G>A NM_001127511.2
APC Chr5:112043289 c.-125delA NM_001127511.2
APC Chr5:112072710-112073585
APC Chr5:112111314 c.423-12A>G NM_000038.5
APC Chr5:112111315 c.423-11A>G NM_000038.5
APC Chr5:112115546 c.532-941G>A NM_000038.5 rs730881227
APC Chr5:112151175 c.835-17A>G NM_000038.5
APC Chr5:112158419 c.1408+731C>T NM_000038.5
APC Chr5:112158423 c.1408+735A>T NM_000038.5
ATM Chr11:108093770 c.-174A>G NM_000051.3
ATM Chr11:108094508 c.-31+595G>A NM_000051.3
ATM Chr11:108098321 c.-30-1G>T NM_000051.3 rs869312754
ATM Chr11:108138753 c.2639-384A>G NM_000051.3
ATM Chr11:108141209 c.2839-579_2839-576delAAGT NM_000051.3
ATM Chr11:108151710 c.3403-12T>A NM_000051.3 rs201370733
ATM Chr11:108158168 c.3994-159A>G NM_000051.3 rs864622543
ATM Chr11:108164028 c.4612-12A>G NM_000051.3
ATM Chr11:108179837 c.5763-1050A>G NM_000051.3 rs774925473
ATM Chr11:108214779 c.8418+681A>G NM_000051.3 rs748635985
BRCA1 Chr17:41196352 c.*1340_*1342delTGT NM_007294.3 rs1281551853
BRCA1 Chr17:41196424 c.*1271T>C NM_007294.3
BRCA1 Chr17:41197167 c.*528G>C NM_007294.3 rs1060504556
BRCA1 Chr17:41197588 c.*103_*106delTGTC NM_007294.3 rs431825382
BRCA1 Chr17:41197637 c.*58C>T NM_007294.3 rs137892861
BRCA1 Chr17:41197859 c.5468-40T>A NM_007294.3 rs80358151
BRCA1 Chr17:41199745 c.5407-25T>A NM_007294.3 rs758780152
BRCA1 Chr17:41201232 c.5333-36_5333-22delTACTGCAGTGATTTT NM_007294.3
BRCA1 Chr17:41206122 c.5277+2916_5277+2946delAAATTCTAGTGCTTTGGATTTTTTCCTCCATinsGG NM_007294.3
BRCA1 Chr17:41209164 c.5194-12G>A NM_007294.3 rs80358079
BRCA1 Chr17:41215994 c.5075-27delA NM_007294.3
BRCA1 Chr17:41251909 c.442-22_442-13delTGTTCTTTAC NM_007294.3 rs879254224
BRCA1 Chr17:41256984 c.213-11T>G NM_007294.3 rs80358061
BRCA1 Chr17:41256985 c.213-12A>G NM_007294.3 rs80358163
BRCA1 Chr17:41256988 c.213-15A>G NM_007294.3
BRCA1 Chr17:41276134 c.-19-2A>G NM_007294.3
BRCA2 Chr13:32889805 c.-40+1G>A NM_000059.3
BRCA2 Chr13:32890469 c.-39-89delC NM_000059.3
BRCA2 Chr13:32890556 c.-39-1_-39delGA NM_000059.3 rs758732038
BRCA2 Chr13:32890558 c.-39-1G>A NM_000059.3 rs1060499566
BRCA2 Chr13:32900222 c.426-12_426-8delGTTTT NM_000059.3 rs276174844
BRCA2 Chr13:32945079 c.8488-14A>G NM_000059.3
BRCA2 Chr13:32953872 c.8954-15T>G NM_000059.3
BRCA2 Chr13:32971007 c.9502-28A>G NM_000059.3 rs397508059
BRCA2 Chr13:32971023 c.9502-12T>G NM_000059.3 rs81002803
BUB1B Chr15:40409289 c.-44133G>A NM_001211.5 rs576524605
BUB1B Chr15:40504689 c.2386-11A>G NM_001211.5 rs751421137
CDKN2A Chr9:21968346 c.458-105A>G NM_000077.4
CDKN2A Chr9:21972311 c.151-1104C>G NM_000077.4
CDKN2A Chr9:21973573 c.150+1104C>A NM_000077.4 rs756102261
CDKN2A Chr9:21974401 c.*73+2T>G NM_058197.4
CDKN2A Chr9:21974847 c.-21C>T NM_000077.4
CDKN2A Chr9:21974875 c.-49C>A NM_000077.4 rs1064797383
CDKN2A Chr9:21974882 c.-56G>T NM_000077.4
CDKN2A Chr9:21974916 c.-93_-91delAGG NM_000077.4
EPCAM Chr2:47606078 c.556-14A>G NM_002354.2 rs376155665
FANCC Chr9:98011653 c.-78-2A>G NM_000136.2 rs587779898
FANCC Chr9:98079807 c.-79+1G>A NM_000136.2
MEN1 Chr11:64571394 c.*412G>A NM_000244.3
MEN1 Chr11:64575165 c.670-15_670-14delTC NM_000244.3
MEN1 Chr11:64577602 c.-23-11_-22delTTGCCTTGCAGGC NM_000244.3
MEN1 Chr11:64577603 c.-23_-22insT NM_000244.3
MEN1 Chr11:64577626 c.-23-22C>A NM_000244.3
MLH1 Chr3:37034619 c.-413_-411delGAG NM_000249.3 rs953169437
MLH1 Chr3:37034932 c.-107C>G NM_000249.3 rs587778886
MLH1 Chr3:37034976 c.-63_-58delGTGATTinsCACGAGGCACGAGCACGA NM_000249.3
MLH1 Chr3:37034997 c.-42C>T NM_000249.3 rs41285097
MLH1 Chr3:37035012 c.-27C>A NM_000249.3 rs587779001
MLH1 Chr3:37035260 c.116+106G>A NM_000249.3
MLH1 Chr3:37038099 c.117-11T>A NM_000249.3 rs267607711
MLH1 Chr3:37050292 c.454-13A>G NM_000249.3 rs267607749
MLH1 Chr3:37061788 c.885-9_887dupTCCTGACAGTTT NM_000249.3 rs63751620
MLH1 Chr3:37070436 c.1558+13T>A NM_000249.3 rs267607834
MSH2 Chr2:47630106 c.-225G>C NM_000251.2 rs138068023
MSH2 Chr2:47630150 c.-181G>A NM_000251.2 rs786201698
MSH2 Chr2:47630249 c.-81dupA NM_000251.2 rs560991330,rs587779187
MSH2 Chr2:47630251 c.-78_-77delTG NM_000251.2 rs587779182
MSH2 Chr2:47698086 c.1662-17dupG NM_000251.2 rs587779099
MSH6 Chr2:48018295 c.457+33_457+34insGTGT NM_000179.2
MSH6 Chr2:48030536 c.3173-16_3173-5delCCCTCTCTTTTA NM_000179.2
MSH6 Chr2:48034014 c.*15A>C NM_000179.2
MSH6 Chr2:48034047 c.*49_*68dupTTCAGACAACATTATGATCT NM_000179.2 rs777409019
NF1 Chr17:29422055 c.-273A>C NM_001042492.2
NF1 Chr17:29422056 c.-272G>A NM_001042492.2
NF1 Chr17:29431417 c.60+9031_60+9035delAAGTT NM_001042492.2
NF1 Chr17:29475515 c.61-7486G>T NM_001042492.2
NF1 Chr17:29488136 c.288+2025T>G NM_001042492.2
NF1 Chr17:29508426 c.587-14T>A NM_001042492.2
NF1 Chr17:29508428 c.587-12T>A NM_001042492.2
NF1 Chr17:29510334 c.888+651T>A NM_001042492.2
NF1 Chr17:29510427 c.888+744A>G NM_001042492.2
NF1 Chr17:29510472 c.888+789A>G NM_001042492.2
NF1 Chr17:29527428 c.889-12T>A NM_001042492.2
NF1 Chr17:29530107 c.1260+1604A>G NM_001042492.2
NF1 Chr17:29533239 c.1261-19G>A NM_001042492.2
NF1 Chr17:29534143 c.1392+754T>G NM_001042492.2
NF1 Chr17:29540877 c.1393-592A>G NM_001042492.2
NF1 Chr17:29542762 c.1527+1159C>T NM_001042492.2
NF1 Chr17:29548419 c.1642-449A>G NM_001042492.2 rs863224655
NF1 Chr17:29549489 c.*481A>G NM_001128147.2
NF1 Chr17:29553439 c.2002-14C>G NM_001042492.2
NF1 Chr17:29554225 c.2252-11T>G NM_001042492.2
NF1 Chr17:29556025 c.2410-18C>G NM_001042492.2
NF1 Chr17:29556027 c.2410-16A>G NM_001042492.2
NF1 Chr17:29556028 c.2410-15A>G NM_001042492.2
NF1 Chr17:29556031 c.2410-12T>G NM_001042492.2
NF1 Chr17:29556839 c.2851-14_2851-13insA NM_001042492.2
NF1 Chr17:29557267 c.2991-11T>G NM_001042492.2
NF1 Chr17:29558777 c.3198-314G>A NM_001042492.2
NF1 Chr17:29563299 c.3974+260T>G NM_001042492.2
NF1 Chr17:29577082 c.4110+945A>G NM_001042492.2
NF1 Chr17:29580296 c.4173+278A>G NM_001042492.2
NF1 Chr17:29588708 c.4578-20_4578-18delAAG NM_001042492.2
NF1 Chr17:29588715 c.4578-14T>G NM_001042492.2
NF1 Chr17:29654479 c.5269-38A>G NM_001042492.2
NF1 Chr17:29656858 c.5610-456G>T NM_001042492.2
NF1 Chr17:29657848 c.5812+332A>G NM_001042492.2 rs863224491
NF1 Chr17:29661577 c.5813-279A>G NM_001042492.2
NF1 Chr17:29664375 c.6428-11T>G NM_001042492.2
NF1 Chr17:29664618 c.6642+18A>G NM_001042492.2
NF1 Chr17:29676126 c.7190-12T>A NM_001042492.2
NF1 Chr17:29676127 c.7190-11_7190-10insGTTT NM_001042492.2
NF1 Chr17:29685177 c.7971-321C>G NM_001042492.2
NF1 Chr17:29685481 c.7971-17C>G NM_001042492.2
NF1 Chr17:29685665 c.8113+25A>T NM_001042492.2
PALB2 Chr16:23649285 c.109-12T>A NM_024675.3 rs774949203
PMS2 Chr7:6027263 c.1145-31_1145-13delCTGACCCTCTTCTCCGTCC NM_000535.5 rs751973268
PMS2 Chr7:6048599 c.23+21_23+28delTCCGGTGT NM_000535.5
STK11 Chr19:1220520 c.597+16_597+33delGGGGGGCCCTGGGGCGCCinsTG NM_000455.4
STK11 Chr19:1220530 c.598-32_597+31delGCCCCCTCCCGGGC NM_000455.4
TP53 Chr17:7571520 NM_000546.5
TP53 Chr17:7577647 c.673-39G>A NM_000546.5
TP53 Chr17:7579601 c.97-11C>G NM_000546.5
TP53 Chr17:7590694 c.-29+1G>T NM_000546.5
TSC1 Chr9:135800306 c.363+668G>A NM_000368.4
TSC2 Chr16:2098067 c.-30+1G>C NM_000548.3 rs587778004
TSC2 Chr16:2106052 c.600-145C>T NM_000548.3
TSC2 Chr16:2107460 c.848+281C>T NM_000548.3 rs45517132
TSC2 Chr16:2110656 c.976-15G>A NM_000548.3 rs45517150
TSC2 Chr16:2127477 c.2838-122G>A NM_000548.3
TSC2 Chr16:2138031 c.5069-18A>G NM_000548.3 rs45484794
VHL Chr3:10183453 c.-75_-55delCGCACGCAGCTCCGCCCCGCG NM_000551.3 rs727503744
VHL Chr3:10183471 c.-54_-44dupTCCGACCCGCG NM_000551.3
VHL Chr3:10191719 c.*70C>A NM_000551.3
VHL Chr3:10191719 c.*70C>T NM_000551.3 rs552290225

Test Strengths

The strengths of this test include:

  • CAP accredited laboratory
  • CLIA-certified personnel performing clinical testing in a CLIA-certified laboratory
  • Powerful sequencing technologies, advanced target enrichment methods and precision bioinformatics pipelines ensure superior analytical performance
  • Careful construction of clinically effective and scientifically justified gene panels
  • Some of the panels include the whole mitochondrial genome (please see the Panel Content section)
  • Our Nucleus online portal providing transparent and easy access to quality and performance data at the patient level
  • ~2,000 non-coding disease causing variants in our clinical grade NGS assay for panels (please see ‘Non-coding disease causing variants covered by this panel’ in the Panel Content section)
  • Our rigorous variant classification scheme
  • Our systematic clinical interpretation workflow using proprietary software enabling accurate and traceable processing of NGS data
  • Our comprehensive clinical statements

Test Limitations

This panel may not detect inversions, including the inversion of exons 1-7 of *MSH2*. Genes with partial, or whole gene, segmental duplications in the human genome are marked with an asterisk (*) if they overlap with the UCSC pseudogene regions. The technology may have limited sensitivity to detect variants in genes marked with these symbols (please see the Panel content table above).

This test does not detect the following:

  • Complex inversions
  • Gene conversions
  • Balanced translocations
  • Some of the panels include the whole mitochondrial genome but not all (please see the Panel Content section)
  • Repeat expansion disorders unless specifically mentioned
  • Non-coding variants deeper than ±20 base pairs from exon-intron boundary unless otherwise indicated (please see above Panel Content / non-coding variants covered by the panel).

This test may not reliably detect the following:

  • Low level mosaicism in nuclear genes (variant with a minor allele fraction of 14.6% is detected with 90% probability)
  • Stretches of mononucleotide repeats
  • Low level heteroplasmy in mtDNA (>90% are detected at 5% level)
  • Indels larger than 50bp
  • Single exon deletions or duplications
  • Variants within pseudogene regions/duplicated segments
  • Some disease causing variants present in mtDNA are not detectable from blood, thus post-mitotic tissue such as skeletal muscle may be required for establishing molecular diagnosis.

The sensitivity of this test may be reduced if DNA is extracted by a laboratory other than Blueprint Genetics.

For additional information, please refer to the Test performance section.

The genes on the panel have been carefully selected based on scientific literature, mutation databases and our experience.

Our panels are sectioned from our high-quality, clinical grade NGS assay. Please see our sequencing and detection performance table for details regarding our ability to detect different types of alterations (Table).

Assays have been validated for various sample types including EDTA-blood, isolated DNA (excluding from formalin fixed paraffin embedded tissue), saliva and dry blood spots (filter cards). These sample types were selected in order to maximize the likelihood for high-quality DNA yield. The diagnostic yield varies depending on the assay used, referring healthcare professional, hospital and country. Plus analysis increases the likelihood of finding a genetic diagnosis for your patient, as large deletions and duplications cannot be detected using sequence analysis alone. Blueprint Genetics’ Plus Analysis is a combination of both sequencing and deletion/duplication (copy number variant (CNV)) analysis.

The performance metrics listed below are from an initial validation performed at our main laboratory in Finland. The performance metrics of our laboratory in Marlborough, MA, are equivalent.

Performance of Blueprint Genetics high-quality, clinical grade NGS sequencing assay for panels.

Sensitivity % (TP/(TP+FN) Specificity %
Single nucleotide variants 99.89% (99,153/99,266) >99.9999%
Insertions, deletions and indels by sequence analysis
1-10 bps 99.2% (7,745/7,806) >99.9999%
11-50 bps 99.13% (2,524/2,546) >99.9999%
Copy number variants (exon level dels/dups)
1 exon level deletion (heterozygous) 100% (20/20) NA
1 exon level deletion (homozygous) 100% (5/5) NA
1 exon level deletion (het or homo) 100% (25/25) NA
2-7 exon level deletion (het or homo) 100% (44/44) NA
1-9 exon level duplication (het or homo) 75% (6/8) NA
Simulated CNV detection
5 exons level deletion/duplication 98.7% 100.00%
Microdeletion/-duplication sdrs (large CNVs, n=37))
Size range (0.1-47 Mb) 100% (25/25)
     
The performance presented above reached by Blueprint Genetics high-quality, clinical grade NGS sequencing assay with the following coverage metrics
     
Mean sequencing depth 143X
Nucleotides with >20x sequencing coverage (%) 99.86%

Performance of Blueprint Genetics Mitochondrial Sequencing Assay.

Sensitivity % Specificity %
ANALYTIC VALIDATION (NA samples; n=4)
Single nucleotide variants
Heteroplasmic (45-100%) 100.0% (50/50) 100.0%
Heteroplasmic (35-45%) 100.0% (87/87) 100.0%
Heteroplasmic (25-35%) 100.0% (73/73) 100.0%
Heteroplasmic (15-25%) 100.0% (77/77) 100.0%
Heteroplasmic (10-15%) 100.0% (74/74) 100.0%
Heteroplasmic (5-10%) 100.0% (3/3) 100.0%
Heteroplasmic (<5%) 50.0% (2/4) 100.0%
CLINICAL VALIDATION (n=76 samples)
All types
Single nucleotide variants n=2026 SNVs
Heteroplasmic (45-100%) 100.0% (1940/1940) 100.0%
Heteroplasmic (35-45%) 100.0% (4/4) 100.0%
Heteroplasmic (25-35%) 100.0% (3/3) 100.0%
Heteroplasmic (15-25%) 100.0% (3/3) 100.0%
Heteroplasmic (10-15%) 100.0% (9/9) 100.0%
Heteroplasmic (5-10%) 92.3% (12/13) 99.98%
Heteroplasmic (<5%) 88.9% (48/54) 99.93%
Insertions and deletions by sequence analysis n=40 indels
Heteroplasmic (45-100%) 1-10bp 100.0% (32/32) 100.0%
Heteroplasmic (5-45%) 1-10bp 100.0% (3/3) 100.0%
Heteroplasmic (<5%) 1-10bp 100.0% (5/5) 99,997%
SIMULATION DATA /(mitomap mutations)
Insertions, and deletions 1-24 bps by sequence analysis; n=17
Homoplasmic (100%) 1-24bp 100.0% (17/17) 99.98%
Heteroplasmic (50%) 100.0% (17/17) 99.99%
Heteroplasmic (25%) 100.0% (17/17) 100.0%
Heteroplasmic (20%) 100.0% (17/17) 100.0%
Heteroplasmic (15%) 100.0% (17/17) 100.0%
Heteroplasmic (10%) 94.1% (16/17) 100.0%
Heteroplasmic (5%) 94.1% (16/17) 100.0%
Copy number variants (separate artifical mutations; n=1500)
Homoplasmic (100%) 500 bp, 1kb, 5 kb 100.0% 100.0%
Heteroplasmic (50%) 500 bp, 1kb, 5 kb 100.0% 100.0%
Heteroplasmic (30%) 500 bp, 1kb, 5 kb 100.0% 100.0%
Heteroplasmic (20%) 500 bp, 1kb, 5 kb 99.7% 100.0%
Heteroplasmic (10%) 500 bp, 1kb, 5 kb 99.0% 100.0%
The performance presented above reached by following coverage metrics at assay level (n=66)
Mean of medians Median of medians
Mean sequencing depth MQ0 (clinical) 18224X 17366X
Nucleotides with >1000x MQ0 sequencing coverage (%) (clinical) 100%
rho zero cell line (=no mtDNA), mean sequencing depth 12X

The target region for each gene includes coding exons and ±20 base pairs from the exon-intron boundary. In addition, the panel includes non-coding and regulatory variants if listed above (Non-coding variants covered by the panel). Some regions of the gene(s) may be removed from the panel if specifically mentioned in the ‘Test limitations” section above. If the test includes the mitochondrial genome the target region gene list contains the mitochondrial genes. The sequencing data generated in our laboratory is analyzed with our proprietary data analysis and annotation pipeline, integrating state-of-the art algorithms and industry-standard software solutions. Incorporation of rigorous quality control steps throughout the workflow of the pipeline ensures the consistency, validity and accuracy of results. Our pipeline is streamlined to maximize sensitivity without sacrificing specificity. We have incorporated a number of reference population databases and mutation databases including, but not limited, to 1000 Genomes Project, gnomAD, ClinVar and HGMD into our clinical interpretation software to make the process effective and efficient. For missense variants, in silico variant prediction tools such as  SIFT, PolyPhen,MutationTaster are used to assist with variant classification. Through our online ordering and statement reporting system, Nucleus, ordering providers have access to the details of the analysis, including patient specific sequencing metrics, a gene level coverage plot and a list of regions with suboptimal coverage (<20X for nuclear genes and <1000X for mtDNA) if applicable. This reflects our mission to build fully transparent diagnostics where ordering providers can easily visualize the crucial details of the analysis process.

We provide customers with the most comprehensive clinical report available on the market. Clinical interpretation requires a fundamental understanding of clinical genetics and genetic principles. At Blueprint Genetics, our PhD molecular geneticists, medical geneticists, and clinical consultants prepare the clinical statement together by evaluating the identified variants in the context of the phenotypic information provided in the requisition form. Our goal is to provide clinically meaningful statements that are understandable for all medical professionals regardless of whether they have formal training in genetics.

Variant classification is the cornerstone of clinical interpretation and resulting patient management decisions. Our classifications follow the ACMG guideline 2015.

The final step in the analysis is orthogonal confirmation. Sequence and copy number variants classified as pathogenic, likely pathogenic, and variants of uncertain significance (VUS) are confirmed using bi-directional Sanger sequencing or by orthogonal methods such as qPCR/ddPCR when they do not meet our stringent NGS quality metrics for a true positive call.

Our clinical statement includes tables for sequencing and copy number variants that include basic variant information (genomic coordinates, HGVS nomenclature, zygosity, allele frequencies, in silico predictions, OMIM phenotypes, and classification of the variant). In addition, the statement includes detailed descriptions of the variant, gene, and phenotype(s) including the role of the specific gene in human disease, the mutation profile, information about the gene’s variation in population cohorts, and detailed information about related phenotypes. We also provide links to the references, abstracts, and variant databases used to help ordering providers further evaluate the reported findings if desired. The conclusion summarizes all of the existing information and provides our rationale for the classification of the variant.

Identification of pathogenic or likely pathogenic variants in dominant disorders or their combinations in different alleles in recessive disorders are considered molecular confirmation of the clinical diagnosis. In these cases, family member testing can be used for risk stratification. We do not recommend using variants of uncertain significance (VUS) for family member risk stratification or patient management. Genetic counseling is recommended.

Our interpretation team analyzes millions of variants from thousands of individuals with rare diseases. Our internal database and our understanding of variants and related phenotypes increases with every case analyzed. Our laboratory is therefore well-positioned to re-classify previously reported variants as new information becomes available. If a variant previously reported by Blueprint Genetics is re-classified, our laboratory will issue a follow-up statement to the original ordering healthcare provider at no additional cost, according to our latest follow-up reporting policy.