Researching

Journals
  • Advanced Photonics
  • Photonics Insights
  • Advanced Photonics Nexus
  • Photonics Research
  • Advanced Imaging
  • View All Journals
  • Chinese Optics Letters
  • High Power Laser Science and Engineering
    • Articles
  • Optics
  • Physics
  • Geography
  • View All Subjects
    • Conferences
  • CIOP
  • HPLSE
  • AP
  • View All Events
    • News
    About CLP
    Search by keywords or author
    Journals >Journal of Innovative Optical Health Sciences >Volume 6 >Issue 3 >Page 1350023 > Article
    • Journal of Innovative Optical Health Sciences
    • Vol. 6, Issue 3, 1350023 (2013)
    THE EXPERIMENTAL STUDY OF STRESS-RELATED PATHOLOGICAL CHANGES IN CEREBRAL VENOUS BLOOD FLOW IN NEWBORN RATS ASSESSED BY DOCT
    OXANA V. SEMYACHKINA-GLUSHKOVSKAYA1, VLADISLAV V. LYCHAGOV1, OLGA A. BIBIKOVA1, IGOR A. SEMYACHKIN-GLUSHKOVSKIY1, SERGEY S. SINDEEV1, EKATERINA M. ZINCHENKO1, MOHHANAD M. KASSIM1、2, AL-FATLE FATEMA ALI1、2, AL HASSANI LEITH1、2, MARIA V. ULANOVA1, and VALERY V. TUCHIN1、3、4
    Author Affiliations
  • 1Department of Biology, Saratov State University, Astrachanskaya Str. 83 410012 Saratov, Russian Federation
  • 2Department of Biology, Al-Mustansiriya University, Baghdad, Iraq
  • 3Institute of Precise Mechanics and Control of Russia Academy of Science Rabochaya 28, 410028 Saratov, Russian Federation
  • 4Optoelectronics and Measurement Techniques Laboratory University of Oulu, P.O. BOX 4500 90014 University of Oulu, Finland
    • show less
    DOI: 10.1142/s1793545813500235 Cite this Article
    OXANA V. SEMYACHKINA-GLUSHKOVSKAYA, VLADISLAV V. LYCHAGOV, OLGA A. BIBIKOVA, IGOR A. SEMYACHKIN-GLUSHKOVSKIY, SERGEY S. SINDEEV, EKATERINA M. ZINCHENKO, MOHHANAD M. KASSIM, AL-FATLE FATEMA ALI, AL HASSANI LEITH, MARIA V. ULANOVA, VALERY V. TUCHIN. THE EXPERIMENTAL STUDY OF STRESS-RELATED PATHOLOGICAL CHANGES IN CEREBRAL VENOUS BLOOD FLOW IN NEWBORN RATS ASSESSED BY DOCT[J]. Journal of Innovative Optical Health Sciences, 2013, 6(3): 1350023 Copy Citation Text show less
    References

    [1] D. A. Osborn, N. Evans,M.Kluckow, "Hemodynamic and antecedent risk factors of early and late periventricular/ intraventricular hemorrhage in premature infants," Pediatrics 112, 33-39 (2003).

    [2] E. H. Whitby, P. D. Griffiths, S. Rutter et al., "Frequency and natural of subdural haemorrhages in babies and relation to obstetric factors," Lancet 363, 846-851 (2004).

    [3] C. B. Looney, J. K. Smith, L. H. Merck et al., "Intracranial hemorrhage asymptomatic neonates: Prevalence on MR images and relationship obstetric and neonatal risk factors," Radiology 242, 535-541 (2007).

    [4] W. C. Hanigan, F. C. Powell, T. C. Miller, R. M. Wright, "Symptoatic intracranial hemorrhage in full-term infants," Childs Nerv. Syst. 11, 698-707 (1995).

    [5] A. S. Hojberg, F. Ebbesen, E. B. Lund, H. Agerholm, "Neurodevelopmental outcome in full-term infants with symptomatic intracranial haemorrhage of unknown aetiology," Dan. Med. Bull. 44, 439-442 (1997).

    [6] S. N. Gaupta, A. M. Kechli, U. S. Kanamalla, "Intracranial hemorrhage in term newborns: Management and outcomes," Pediatr. Neurol. 40, 1-12 (2009).

    [7] L. C. Jordan, J. T. Kleinman, A. E. Hillis, "Intracerebral hemorrhage volume predicts poor neurologic outcome in children," Stroke 40, 1666- 1671 (2009).

    [8] J. K. Lynch, K. B. Nelson, "Epidemiology of perinatal stroke," Curr. Opin. Pediatr. 13, 499-505 (2003).

    [9] National Center for Health Statistics, Deaths, percentage of total deaths and death rates for the 10 leading causes of death in selected age groups, by race and sex: United States (2002-2005), Available at www.cdc.gov/nchs/data/nvsr/nvsr53/nvsr53 17. pdf (accessed on 16 June 2006).

    [10] L. L. Beslow, D. J. Licht, S. E. Smith, P. B. Storm, G. G. Heuer, R. A. Zimmerman, A. M. Feiler, S. E. Kasner, R. N. Ichord, L. C. Jordan, "Predictors of outcome in childhood intracerebral hemorrhage a prospective consecutive cohort study," Stroke 41, 313-318 (2010).

    [11] W. D. Lo, "Childhood hemorrhagic stroke: An important but understudied problem," J. Child Neurol. 26(9), 1174-1185 (2011).

    [12] O. Semyachkina-Glushkovskaya, V. Lychagov, O. Bibikova, I. Semyachkin-Glushkovskiy, S. Sindeev, E. Zinchenko, M. Kassim, H. Braun, F. Al-Fatle, L. Al Hassani, V. Tuchin, "The assessment of pathological changes in cerebral blood flow in hypertensive rats with stress-induced intracranial hemorrhage using Doppler OCT: Particularities of arterial and venous alterations," J. Photon Lasers Med. 1-8 (2013).

    [13] M. A. Vilenskii, O. V. Semyachkina-Glushkovskaya, P. A. Timoshina, Ya. V. Kuznetsova, I. A. Semyachkin-Glushkovskii, D. N. Agafonov, V. V. Tuchin, "Laser speckle-imaging of blood microcirculation in the brain cortex of laboratory rats in stress," Quantum Electron. 42(6), 489-494 (2012).

    [14] J. Ahlqvist, "Stress-related intracerebral hemorrhage and the water-hammer effect," Stroke 32, 275-278 (2001).

    [15] G. Lammie, R. Lindley, S. Keir, M. Wiggam, "Stress-related primary intracerebral hemorrhage. Autopsy clues to underlying mechanism," Stroke 31, 1426-1428 (2000).

    [16] L. Caplan, "Intracerebral haemorrhage revisited," Neurology 38, 624-627 (1988).

    [17] H. Girouard, C. Iadecola, "Neurovascular coupling in the normal brain and in hypertension, stroke, and Alzheimer disease," J. Appl. Physiol. 100(1), 328-335 (2006).

    [18] D. Annibale, J. Hill, "Periventricular hemorrhageintraventricular hemorrhage," Emedicine.com, Available at http://emedicine.medscape.com/ article/976654-overview (accessed on 19 June 2007).

    [19] P. Ballabh, "Intraventricular hemorrhage in premature infants: Mechanism of disease," Pediatr Res. 67(1), 1-8 (2010).

    [20] P. Ballabh, A. Braun, M. Nedergaard, "Anatomic analysis of blood vessels in germinal matrix, cerebral cortex, and white matter in developing infants," Pediatr Res. 56(1), 117-124 (2004).

    [21] M. J. Purves, "The Physiology of the Cerebral Circulation," Syndics of the Cambridge University Press, p. 427 (1972).

    [22] J. A. Bevan, R. D. Bevan, S. P. Duckles, "Adrenergic regulation of vascular smooth muscle," in The Handbook of Physiology. Sec. 2 The Cardiovascular System. Vol. 2 Vascular Smooth Muscle, Chap. 18 pp. 515-566. Am. Physiol. Soc Bethesda (1981).

    [23] D. W. Busija, D. D. Heistad, "Factors involved in the physiological regulation of cerebral circulation," Rev. Physiol. Biochem. Pharmacol. 101, 161-211 (1984).

    [24] T. A. McCalden, "Sympathetic control of the cerebral circulation," J. Auton. Pharmacol. 1, 421-431 (1981).

    [25] P. A. Cassaglia, R. I. Griffiths, A. M. Walker, "Sympathetic nerve activity in the superior cervical ganglia increases in response to imposed increases in arterial pressure," Am. J. Physiol. - Regul. Integr. Comp. Physiol. AJP - Regul. Physiol. 294(4), 1255-1261 (2008).

    [26] J. L. Di Gennaro, D. C. Mack, A. Malakouti, J. J. Zimmerman, W. Armstead, M. S. Vavilala, "Use and effect of vasopressors after pediatric traumatic brain injury," Dev. Neurosci. 32(5-6), 420-430 (2011).

    [27] P. Sookplung, A. Siriussawakul, A. Malakouti, D. Sharma, J. Wang, M. Souter, R. Chesnut, M. Vavilala, "Vasopressor use and effect on blood pressure after severe adult traumatic brain injury," Neurocrit. Care 15(1), 46-54 (2011).

    [28] S. N. Kroppenstedt, U. W. Thomale, M. Griebenow, O. W. Sakowitz, K. D. Schaser, P. S. Mayr, A. W. Unterberg, J. F. Stover, "Effects of early and late intravenous norepinephrine infusion on cerebral perfusion, microcirculation, brain-tissue oxygenation, and edema formation in brain-injured rats," Crit. Care Med. 31(8), 2211-2221 (2003).

    [29] D. Pfister, S. P. Strebel, L. A. Steiner, "Effects of catecholamines on cerebral blood vessels in patients with traumatic brain injury," Eur. J. Anaesthesiol. 42, 98-103 (2008).

    [30] P. Sandor, "Nervous control of the cerebrovascular system: Doubts and facts," Neurochem. Int. 35, 237-259 (1999).

    [31] M. Green, G. Hutchins, "Positron emission tomography assessment of renal perfusion," Semin. Nephrol. 31(6), 291-299 (2011).

    [32] F. Bengel, T. Higuchi, M. Javadi, R. Lautamaki, "Cardiac positron emission tomography," J. Am. Coll. Cardiol. 54(1), 1-5 (2009).

    [33] J. Amerom, C. Kellenberger, S. Yoo, C. Macgowan, "Automated measurement and classification of pulmonary blood flow velocity patterns using phasecontrast MRI and correlation analysis," Magn. Reson. Imaging 27, 38-47 (2009).

    [34] T. Weber, H. von Tengg-Kobligk, A. Kopp- Schneider, J. Ley-Zaporozhan, H. Kauczor, S. Ley, "High-resolution phase-contrast MRI of aortic and pulmonary blood flow during rest and physical exercise using a MRI compatible bicycle ergometer," Eur. J. Radio. 80, 103-108 (2011).

    [35] J. Enmi, T. Hayashi, H. Watabe, H. Moriwaki, N. Yamada, H. Irida, "Measurement of cerebral blood flow with dynamic susceptibility contrast MRI and comparison with O-15 positron emission tomography," Int. Congr. Ser. 1265, 150-158 (2004).

    [36] A. Koretsky, "Early development of arterial spin labeling to measure regional brain blood flow by MRI," NeuroImage 62, 602-607 (2012).

    [37] P. Wintermark, A. Hansen, S. Warfield, D. Dukhovny, S. Soul, "Near-infrared spectroscopy vs magnetic resonance imaging to study brain perfusion in newborns with hypoxic-ischmic encephalopathy treated with hypothermia," NeuroImage (2013) in press, doi: 10.1016/j.neuroimage.2013.04.072.

    [38] M. Ferrari, V. Quaresima V, "A brief review on the history of human functional near-infrared spectroscopy (fNIRS) development and field of application," NeuroImage 63, 921-935 (2012).

    [39] J. Yao, K. Maslov, Y. Shi, L. Taber, L. Wang, "In vivo photoacoustic imaging of transverse blood flow by using Doppler broadening of bandwidth," Opt. Lett. 35(9), 1419-1421 (2010).

    [40] F. Helmchen, D. Kleinfeld, "In vivo measurements of blood flow and glial cell function with two-photon laser-scanning microscopy," Methods Enzymol. 444, 231-254 (2008).

    [41] M. Wintermark, M. Sesay, E. Barbier, K. Borbely, W. Dillon, J. Eastwood, C. Glenn, C. Grandin, S. Pedraza, J.-F. Soustiel, T. Nariai, G. Zaharchuk, J.-M. Caille, V. Dousset, H. Yonas, "Comparative overview of brain perfusion imaging techniques," Stroke 36, E83-E99 (2005).

    [42] E. Hillman, "Optical brain imaging in vivo: Techniques and application from animal to man," J. Biomed. Opt. 12(5), 051402 (2007).

    [43] K. Liem, G. Greisen, "Monitoring of cerebral haemodynamics in newborn infants," Early Hum. Dev. 86, 155-158 (2010).

    [44] V. Srinivasan, S. Sakadzic, I. Gorczynska, S. Ruvinskaya, W. Wu, J. Fujimoto, D. Boas, "Quantitative cerebral blood flow with optical coherence tomography," Opt. Exp. 18(3), 2477-2494 (2010).

    [45] M. Bhattacharjee, P. C. Ashok, K. Divakar Rao, S. K. Majumder, Y. Verma, P. K. Gupta, "Binary tissue classification studies on resected human breast tissue using optical coherence tomography images," J. Innov. Opt. Health Sci. 4(1), 59-66 (2011).

    [46] L. Xiqo, S. Guohua, W. Ling, D. Zhihua, Z. Yudong, "High-speed spectral domain optical coherence tomography signal processing with time-domain interpolation using graphics processing unit," J. Innov. Opt. Health Sci. 4(3), 325-335 (2011).

    [47] Y. Li-Ping, G. Jian-Chen, C. Li-Dek, M. Te-Lun, W. Jheng-Syong, L. Jiann-Der, C. Chien, "Polarizationsensitive optical coherence tomography using a modified balance detector," J. Innov. Opt. Health Sci. 5(4), 1250024 (2012).

    [48] S. Guennadi, D. Alexandre, "Real-time optical monitoring of capillarity grid spatial pattern in epithelium by spatially resolved diffuse reflectance probe," J. Innov. Opt. Health Sci. 5(2), 1250005 (2012).

    [49] O. Semyachkina-Glushkovskaya, O. Tichin, V. Lichagov et al., "The method of modeling of intracranial hemorrhage in newborn rats/Patent RF 072642," 24 October, 2012, p. 130.

    [50] J. J. Volpe, "Intracranial hemorrhage: Germinal matrix hemorrhage," Neurology of the Newborn J. J. Volpe, Ed., pp. 517-288, Saunders Elsevier, Philadelphia (2008).

    [51] H. S. Ghazi-Birry, W. R. Brown, D. M. Moody, V. R. Challa, S. M. Block, D. M. Reboussin, "Human germinal matrix: Venous origin of hemorrhage and vascular characteristics," Am. J. Neuroradiol. 18, 219-229 (1997).

    [52] B. G. Carter, W. Butt, A. Taylor, "ICP and CPP: Excellent predictors of long-term outcome in severely brain-injured children," Childs Nerv. Syst. 24, 245-251 (2008).

    [53] A. Català-Temprano, G. Claret Teruel, F. J. Cambra Lasaosa, O. M. Pons, J. A. Noguera, R. A. Palomeque, "Intracranial pressure and cerebral perfusion pressure as risk factors in children with traumatic brain injury," J. Neurosurg. 106(6), 463-466 (2007).

    [54] P. D. Adelson, S. L. Bratton, N. A. Carney, R. M. Chesnut, H. E. du Coudray, B. Goldstein, P. M. Kochanek, H. C. Miller, M. D. Partington, N. R. Selden, C. R. Warden, D. W. Wright, "Guidelines for the acute medical management of severe traumatic brain injury in infants, children, and adolescents," Pediatr. Crit. Care Med. 4(3), 12-18 (2003).

    [55] S. L. Bratton, R. M. Chestnut, J. Ghajar, F. F. McConnell Hammond, O. A. Harris, R. Hartl, G. T. Manley, A. Nemecek, D. W. Newell, G. Rosenthal, J. Schouten, L. Shutter, S. D. Timmons, J. S. Ullman, W. Videtta, J. E. Wilberger, D. W. Wright, "Guidelines for the management of severe traumatic brain injury," J. Neurotrauma 24(1), 7-13 (2007).

    [56] M. J. Morris, "Ontogeny of a1 and a2-adrenoceptors in rat brain," Brain Res. 190, 268-271 (1980).

    [57] H. K. Happe, "Alpha-2 adrenergic receptor functional coupling to G proteins in rat brain during postnatal development," J. Pharmacol. Exp. Ther. 288, 1134-1142 (1999).

    [58] J. V. Bartolome, R. J. Kavlock, T. Cowdery, L. Orband-Miller, T. A. Slotkin, "Development of adrenergic receptor binding sites in brain regions of the neonatal rat: Effects of prenatal or postnatal exposure to methylmercury," Neurotoxicol. 8, 1-14 (1987).

    [59] P. J. Andrews, D. H. Sleeman, P. F. Statham, A. McQuatt, V. Corruble, P. A. Jones, T. P. Howells, C. S. Macmillan, "Predicting recovery in patients suffering from traumatic brain injury by using admission variables and physiologic data: A comparison between decision tree analysis and logistic regression," J. Neurosurg. 97, 326-336 (2002).

    [60] B. G. Carter, W. Butt, A. Taylor, "ICP and CPP: Excellent predictors of long-term outcome in severely brain-injured children," Childs Nerv. Syst. 24, 245-251 (2008).

    [61] A. Català-Temprano, C. G. Teruel, C. F. J. Lasaosa, O. M. Pons, J. A. Noguera, R. A. Palomeque, "Intracranial pressure and cerebral perfusion pressure as risk factors in children with traumatic brain injury," J. Neurosurg. 106(6), 463-466 (2007).

    [62] I. R. Chamber, P. A. Jones, T. Y. M. Lo, R. J. Forsyth, B. Fulton, P. J. D. Andrews, A. D. Mendelow, R. A. Minns,"Critical thresholds of intracranial pressure and cerebral perfusion pressure related to age in pediatric head injury," J. Neurol. Neurosurg. Psychiatry. 77, 234-240 (2006).

    [63] D. G. Changaris, C. P. McGraw, J. D. Richardson, H. D. Garretson, E. J. Arpin, C. B. Shields, "Correlation of cerebral perfusion pressure and Glasgow Coma Scale to outcome," J. Trauma. 27, 1007-1013 (1987).

    [64] G. L. Clifton, E. R. Miller, S. C. Choi, H. S. Levin, "Fluid thresholds and outcome from severe brain injury," Crit. Care Med. 30, 739-745 (2002).

    [65] C. Downard, F. Hulka, R. J. Mullins, J. Piatt, R. Chesnut, P. Quint, N. C. Mann, "Relationship of cerebral perfusion pressure and survival in pediatric braininjured patients," J. Trauma. 49, 654-658 (2000).

    [66] A. C. Elias-Jones, J. A. Punt, A. E. Turnbull, T. Jaspan, "Management and outcome of severe head injuries in the Trent region 1985-1990," Arch. Dis. Child. 67, 1430-1435 (1992).

    [67] R. M. Hackbarth, K. M. Rzeszutko, G. Sturm, J. Donders, A. S. Kuldanek, D. J. Sanfilippo, "Survival and functional outcome in traumatic brain injury: A retrospective review and analysis of predictive factors," Crit. Care Med. 30, 1630-1635 (2002).

    [68] G. Kaiser, J. Pfenninger, "Effect of neurointensive care upon outcome following severe head injuries in childhood: A preliminary report," Neuropediatrics 15, 68-75 (1984).

    [69] K. Keining, G. Schneider, T. Bardt, A. Unterberg, W. Lanksch, "Bifrontal measurements of brain tissue PO2 in comatose patients," Acta Neurochir. Suppl. 71, 172-183 (1998).

    [70] C. Meyer, D. Lowe, M. Meyer, P. Richardson, G. Neil-Dwyer, "Progressive change in cerebral blood flow during the first three weeks after subarachnoid hemorrhage," Neurosurgery 12, 58-76 (1983).

    [71] Y. Jiang, J. Wu, R. Keep, Y. Hua, J. Hoff, G. Xi, "Hypoxia-inducible factor-1alpha accumulation in the brain after experimental intracerebral hemorrhage," J. Cereb. Blood Flow Metab. 22(6), 689-696 (2002).

    Abstract
    Get PDF
    Figures&Tables (0)
    Equations (0)
    References (71)
    Get Citation
    Copy Citation Text
    OXANA V. SEMYACHKINA-GLUSHKOVSKAYA, VLADISLAV V. LYCHAGOV, OLGA A. BIBIKOVA, IGOR A. SEMYACHKIN-GLUSHKOVSKIY, SERGEY S. SINDEEV, EKATERINA M. ZINCHENKO, MOHHANAD M. KASSIM, AL-FATLE FATEMA ALI, AL HASSANI LEITH, MARIA V. ULANOVA, VALERY V. TUCHIN. THE EXPERIMENTAL STUDY OF STRESS-RELATED PATHOLOGICAL CHANGES IN CEREBRAL VENOUS BLOOD FLOW IN NEWBORN RATS ASSESSED BY DOCT[J]. Journal of Innovative Optical Health Sciences, 2013, 6(3): 1350023
    Download Citation
    Tools
    Share
    Save the article for my favorites
    Paper Information
    Recommended Topics
    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology