Objective To observe the systemic inhalation anesthetic effects of preterm children with different gestational ages under ocular fundus examination, and to assess its safety. Methods Fifty-one preterm children with retinopathy of prematurity (ROP) were included in the study. These kids were divided into 2 groups, group Ⅰ included 24 kids with a corrected gestational age of 33 to <44 weeks, and group Ⅱ included 27 kids with a corrected gestational age of 44 to 64 weeks. The preterm months were same (t=-1.3.P>0.05), but the body weights were different (t=-10.5.P<0.05) between these two groups. Anesthesia was induced by inhalation of 6% sevoflurane, and the period from the beginning of inhalation to disappearance of body movement was the induction time. 6% sevoflurane was inhaled continuously for another period of the induction time, and then the concentration of sevoflurane was adjusted to a maintenance concentration. The initial maintenance concentration was 3%, and was adjusted by 0.5% each time. Sequential method was used to determine the subsequent maintenance concentration. If the preceding patient had not moved during the maintenance period, the sevoflurane concentration was decreased by 0.5% for the next patient. If the preceding patient had moved during the maintenance period, the sevoflurane concentration was increased by 0.5% for the next patient. Respiratory depression and cough during the induction and maintenance period, duration of anesthesia and recovery time were recorded. Choking and vomiting during drinking or milk-feeding in one hour after the ocular fundus examination were also recorded. Results The effective inhale concentration in 50% patient of sevoflurane was 2.5% in group Ⅰ, 2.9% in group Ⅱ. The average maintenance concentration was (2.5plusmn;0.5)% in group Ⅰ, (3.0plusmn;0.5)% in group Ⅱ. The difference was statistically significant (t=-3.3.P<0.05). The average duration of anesthesia and the average awake time were the same (t=0.04 and -1.0 respectively.P>0.05) between these two groups. The average induction time was significantly shorter in group Ⅰ than in group Ⅱ, the difference was statistically significant (t=-4.9.P<0.05). All patients were successfully completed the ocular examination. No respiratory depression or cough occurred during and after the examination. No choking and vomiting during drinking or milkfeeding in one hour after the ocular fundus examination. Conclusion Anesthesia with inhaled sevoflurane by a face mask is safe for preterm outpatients undergoing fundus examination.
ObjectiveTo analysis the fundus characteristics of fundus fluorescein angiography (FFA) of retinopathy of prematurity (ROP). MethodsEighty-four cases (168 eyes) who were diagnosed with ROP by a binocular indirect ophthalmoscope were included in the study. Among the 84 cases, there were 2 cases (4 eyes) of stage 1 ROP, 26 cases (52 eyes) of stage 2 ROP, 40 cases (80 eyes) of stage 3 ROP, 4 cases (8 eyes) of stage 4 ROP, and 4 cases (8 eyes) of stage 5 ROP, 9 cases (18 eyes) of plus disease, 8 cases (16 eyes) of aggressive posterior ROP (APROP). All infants received FFA with RetCam Ⅱ under general anesthesia and mydriasis. The retinal vein morphology, capillary filling state, neovascularization morphology and fluorescein leakage were observed. ResultsFFA revealed increased branching, expansion and tortuous peripheral retinal capillaries, increased capillary permeability with a small amount of fluorescein leakage in stage 1 ROP. There was a clear dividing line between the vascular area and the remote avascular area. In stage 2, the peripheral branches of temporal retinal blood vessels increased, and parallel distributed like a broom. The capillary end anastomosed with each other to form a loop. The fibrous tissues at the lesion edge proliferated as a ridge, with popcorn phenomenon. In stage 3, the ridge continued broadening, and the neovascular fibrous membrane formed breakthrough internal limiting membrane, stretched into the vitreous with a lot of fluorescein leakage. The ridge and remote avascular zone demarcated clearly. In stage 4 and 5, the vessel changes had similar phenomenon with the stage 2 and 3 in undetached retina, but the vessels in the detached retina expanded with fluorescein leakage. As for plus disease, the retinal arterioles in the posterior pole were tortuous, there were a large number of non-perfusion area in the peripheral retina with hemorrhage and obscured fluorescence. The retinal vessels in posterior pole in AP-ROP were also tortuous, and the capillaries were extreme expanded, while there were very few tortuous vessels and no capillary formation in the other part of retina.At the avascular zone boundaries, there were a large group of neovascularization with fluorescein leakage. ConclusionsThe demarcation line separating the avascular from the vascularized retinal regions is formed in stage 1, 2 and 3, and the amount of fluorescein leakage gradually increase from stage 1 to stage 3 ROP. The detached retina of stage 4 and stage 5 has an unclear focal length in the FFA. The plus disease mainly has arteriolar tortuosity in the posterior pole retina. In the AP-ROP cases, both of the arterioles and venules in posterior pole of retina are tortuous and expanding with neovascularization leakage of fluorescein.
ObjectiveTo retrospectively analyze incidence and trends of retinopathy of prematurity (ROP) from 2004 to 2013 in Shenzhen. MethodsA total of 9100 preterm children (5401 males, 3699 females) were screened for ROP in Shenzhen from January 2004 to June 2013 using binocular ophthalmoscope or RetCam Ⅱ. First examination was performed from 4-6 weeks after birth. The birth weight was 520-2990 g with an average of (1710±410) g.The gestational age were 24-36 weeks with an average of (31.57±1.99) weeks. The gestational age of 208 children were <28 weeks, 3608 children were 28-32 weeks, 3553 children was 33-34 weeks, 1731 children was >34 weeks. The ocular findings were recorded according to the International Classification of ROP and The Early Treatment for ROP. Only the more aggressive eye of bilateral asymmetrical cases was counted for statistical purpose, and the cases required surgeries were defined as severe cases. The 10 years period was divided into first phase (2004-2008) and second phase (2009-2013). The incidence of ROP and severe ROP of these two phases was compared and statistics was analyzed. ResultsIn the past 10 years, the overall incidence of ROP and sever ROP in Shenzhen was 12.49% and 4.99% in this screen. The children were divided into 4 groups according to the birth weight, the ROP incidences of birth weight <1000 g, 1000-1499 g, 1500-1999 g and ≥2000 g were 62.62%, 28.40%, 11.34% and 3.63% respectively. The severe ROP incidences were 34.95%, 12.21%, 3.73% and 0.49% respectively in these birth weight groups. The children were divided into 4 groups according to gestational weeks, the ROP incidences of gestational age <28 weeks, 28-32 weeks, 33-34 weeks and >34 weeks were 67.31%, 25.27%, 7.22% and 3.87% respectively. Severe ROP incidences were 37.02%, 10.71%, 1.79% and 0.68% in these gestational age groups respectively. ROP and severe ROP incidences were decreased from 14.64% at first phase to 11.47% at second phase, and from 6.52% at first phase to 4.26% second phase respectively, the differences were statistical significant (χ2=26.96, 26.61; P<0.05). ROP and severe ROP incidence in <1000 g birth weight group at second phase were much less than the first phase (χ2=13.676, 5.271; P<0.05). In <28 weeks gestational age group, the ROP incidence was the same in first phase and second phase (χ2=0.843, P>0.05), but the severe ROP incidence at second phase was much less the first phase (χ2=4.757,P<0.05). ConclusionFrom 2004 to 2013, the incidences of ROP and severe ROP have decreased significantly in Shenzhen.