PURPOSE: Neonatal sepsis caused by Streptococcus agalactiae [group B streptococcus (GBS)] is a life-threatening condition, which is preventable if colonized mothers are identified and given antibiotic prophylaxis during labour. Conventional culture is time consuming and unreliable, and many available non-culture diagnostics are too complex to implement routinely at point of care. Loop-mediated isothermal amplification (LAMP) is a method that, enables the rapid and specific detection of target nucleic acid sequences in clinical materials without the requirement for extensive sample preparation. METHODOLOGY: A prototype LAMP assay targeting GBS sip gene is described. RESULTS: The assay was 100 % specific for GBS, with a limit of detection of 14 genome copies per reaction. The clinical utility of the LAMP assay for rapid direct molecular detection of GBS was determined by testing a total of 157 vaginal swabs with minimal sample processing using a rapid lysis solution. Compared to a reference quantitative real-time PCR assay, the direct LAMP protocol had a sensitivity and specificity of 95.4 and 100 %, respectively, with positive and negative predictive values of 100 and 98.3 %, respectively. Positive and negative likelihood ratios were infinity and 0.05, respectively. The direct LAMP method required a mean time of 45 min from the receipt of a swab to generation of a confirmed result, compared to 2 h 30 min for the reference quantitative real-time PCR test. CONCLUSION: The direct LAMP protocol described is easy to perform, facilitating rapid and accurate detection of GBS in vaginal swabs. This test has a potential for use at point of care.
PURPOSE:Neonatal sepsis caused by Streptococcus agalactiae [group B streptococcus (GBS)] is a life-threatening condition, which is preventable if colonized mothers are identified and given antibiotic prophylaxis during labour. Conventional culture is time consuming and unreliable, and many available non-culture diagnostics are too complex to implement routinely at point of care. Loop-mediated isothermal amplification (LAMP) is a method that, enables the rapid and specific detection of target nucleic acid sequences in clinical materials without the requirement for extensive sample preparation. METHODOLOGY: A prototype LAMP assay targeting GBS sip gene is described. RESULTS: The assay was 100 % specific for GBS, with a limit of detection of 14 genome copies per reaction. The clinical utility of the LAMP assay for rapid direct molecular detection of GBS was determined by testing a total of 157 vaginal swabs with minimal sample processing using a rapid lysis solution. Compared to a reference quantitative real-time PCR assay, the direct LAMP protocol had a sensitivity and specificity of 95.4 and 100 %, respectively, with positive and negative predictive values of 100 and 98.3 %, respectively. Positive and negative likelihood ratios were infinity and 0.05, respectively. The direct LAMP method required a mean time of 45 min from the receipt of a swab to generation of a confirmed result, compared to 2 h 30 min for the reference quantitative real-time PCR test. CONCLUSION: The direct LAMP protocol described is easy to perform, facilitating rapid and accurate detection of GBS in vaginal swabs. This test has a potential for use at point of care.
Authors: Christina M Newman; Mitchell D Ramuta; Matthew T McLaughlin; Roger W Wiseman; Julie A Karl; Dawn M Dudley; Miranda R Stauss; Robert J Maddox; Andrea M Weiler; Mason I Bliss; Katrina N Fauser; Luis A Haddock; Cecilia G Shortreed; Amelia K Haj; Molly A Accola; Anna S Heffron; Hailey E Bussan; Matthew R Reynolds; Olivia E Harwood; Ryan V Moriarty; Laurel M Stewart; Chelsea M Crooks; Trent M Prall; Emma K Neumann; Elizabeth D Somsen; Corrie B Burmeister; Kristi L Hall; William M Rehrauer; Thomas C Friedrich; Shelby L O'Connor; David H O'Connor Journal: J Biomol Tech Date: 2021-09
Authors: Tamieka A Fraser; Scott Carver; Alynn M Martin; Kate Mounsey; Adam Polkinghorne; Martina Jelocnik Journal: PeerJ Date: 2018-07-27 Impact factor: 2.984
Authors: Kirsty Le Doare; Paul T Heath; Jane Plumb; Natalie A Owen; Peter Brocklehurst; Lucy C Chappell Journal: Clin Infect Dis Date: 2019-08-01 Impact factor: 9.079
Authors: Christina M Newman; Mitchell D Ramuta; Matthew T McLaughlin; Roger W Wiseman; Julie A Karl; Dawn M Dudley; Miranda R Stauss; Robert J Maddox; Andrea M Weiler; Mason I Bliss; Katrina N Fauser; Luis A Haddock; Cecilia G Shortreed; Amelia K Haj; Molly A Accola; Anna S Heffron; Hailey E Bussan; Matthew R Reynolds; Olivia E Harwood; Ryan V Moriarty; Laurel M Stewart; Chelsea M Crooks; Trent M Prall; Emma K Neumann; Elizabeth D Somsen; Corrie B Burmeister; Kristi L Hall; William M Rehrauer; Thomas C Friedrich; Shelby L O'Connor; David H O'Connor Journal: medRxiv Date: 2021-02-27
Authors: Ameneh Khatami; Tara M Randis; Anna Chamby; Thomas A Hooven; Margaret Gegick; Evan Suzman; Brady A'Hearn-Thomas; Andrew P Steenhoff; Adam J Ratner Journal: Open Forum Infect Dis Date: 2018-07-07 Impact factor: 3.835
Authors: Daniel F Escobar; Diego A Diaz-Dinamarca; Carlos F Hernández; Daniel A Soto; Ricardo A Manzo; Pedro I Alarcón; Camila H Pinto; Diego N Bastias; Carolayn N Oberg-Bravo; Robert Rojas; Sebastián E Illanes; Alexis M Kalergis; Abel E Vasquez Journal: BMC Pregnancy Childbirth Date: 2020-06-09 Impact factor: 3.007