Periventricular leukomalacia

Periventricular leukomalacia (PVL) is a form of white-matter brain injury, characterized by the necrosis (more often coagulation) of white matter near the lateral ventricles. It can affect newborns and (less commonly) fetuses; premature infants are at the greatest risk of neonatal encephalopathy which may lead to this condition. Affected individuals generally exhibit motor control problems or other developmental delays, and they often develop cerebral palsy or epilepsy later in life. Periventricular leukomalacia (PVL) is a form of white-matter brain injury, characterized by the necrosis (more often coagulation) of white matter near the lateral ventricles. It can affect newborns and (less commonly) fetuses; premature infants are at the greatest risk of neonatal encephalopathy which may lead to this condition. Affected individuals generally exhibit motor control problems or other developmental delays, and they often develop cerebral palsy or epilepsy later in life. This pathology of the brain was described under various names ('encephalodystrophy', 'ischemic necrosis', 'periventricular infarction', 'coagulation necrosis', 'leukomalacia,' 'softening of the brain', 'infarct periventricular white matter', 'necrosis of white matter', 'diffuse symmetrical periventricular leukoencephalopathy'), and more often by German scientists, but the worldwide dissemination was the term periventricular leukomalacia, introduced in 1962 B. A. Banker and J. C. Larroche. The term can be misleading, as there is no softening of the tissue in PVL. V. V. Vlasyuk and V. P. Tumanov in 1985 published the world's first monograph devoted to PVL. Vlasyuk (1981) first revealed the high incidence of optic radiation lesions and demonstrated that PVL - a persistent process that the old necrosis can join a new, foci of PVL may be at different stages of development. In the process of morphogenesis focuses PVL pass through three stages: 1) necrosis, 2) resorption, and 3) the formation gliosis scars or cysts. Cysts occur when large and confluent focuses of PVL, with mixed necrosis (kollikvacia in the center and coagulation rim at the periphery). Around the foci is generally defined area of other lesions of the brain white matter - the death of prooligodendrocytes, proliferation mikrogliocytes and astrocytes, swelling, bleeding, loss of capillaries, and others (the so-called 'diffuse component PVL'). However, diffuse lesions without necrosis are not PVL. It is often impossible to identify PVL based on the patient’s physical or behavioral characteristics. The white matter in the periventricular regions is involved heavily in motor control, and so individuals with PVL often exhibit motor problems. However, since healthy newborns (especially premature infants) can perform very few specific motor tasks, early deficits are very difficult to identify. As the individual develops, the areas and extent of problems caused by PVL can begin to be identified; however, these problems are usually found after an initial diagnosis has been made. The extent of signs is strongly dependent on the extent of white matter damage: minor damage leads to only minor deficits or delays, while significant white matter damage can cause severe problems with motor coordination or organ function. Some of the most frequent signs include delayed motor development, vision deficits, apneas, low heart rates, and seizures. Delayed motor development of infants affected by PVL has been demonstrated in multiple studies. One of the earliest markers of developmental delays can be seen in the leg movements of affected infants, as early as one month of age. Those with white matter injury often exhibit 'tight coupling' of leg joints (all extending or all flexing) much longer than other infants (premature and full-term). Additionally, infants with PVL may not be able to assume the same positions for sleeping, playing, and feeding as premature or full-term children of the same age. These developmental delays can continue throughout infancy, childhood, and adulthood. Premature infants often exhibit visual impairment and motor deficits in eye control immediately after birth. However, the correction of these deficits occurs 'in a predictable pattern' in healthy premature infants, and infants have vision comparable to full-term infants by 36 to 40 weeks after conception. Infants with PVL often exhibit decreased abilities to maintain a steady gaze on a fixed object and create coordinated eye movements. Additionally, children with PVL often exhibit nystagmus, strabismus, and refractive error. Occurrence of seizures is often reported in children with PVL. In an Israel-based study of infants born between 1995 and 2002, seizures occurred in 102 of 541, or 18.7%, of PVL patients. Seizures are typically seen in more severe cases of PVL, affecting patients with greater amounts of lesions and those born at lower gestational ages and birth weights. Those generally considered to be at greatest risk for PVL are premature, very low birth-weight infants. It is estimated that approximately 3-4% of infants who weigh less than 1,500 g (3.3 lb) have PVL, and 4-10% of those born prior to 33 weeks of gestation (but who survive more than three days postpartum) have the disorder. Gestational CMV infection also produces PVL in neonates.