PMID- 22568102
OWN - NLM
STAT- MEDLINE
DCOM- 20120724
LR  - 20220321
IS  - 0029-0203 (Print)
IS  - 0029-0203 (Linking)
VI  - 116
IP  - 3
DP  - 2012 Mar
TI  - [Polypoidal choroidal vasculopathy].
PG  - 200-31; discussion 232
AB  - Polypoidal choroidal vasculopathy (PCV) is characterized by a branching vascular 
      network with polypoidal lesions under the retinal pigment epithelium (RPE). In 
      Japan, it is classified as a specific form of exudative age-related macular 
      degeneration. However, several issues which we investigated regarding the 
      pathogenesis and treatment of PCV remain unresolved. We investigated the 
      pathogenesis, clinical findings and treatment of PCV. 1. Indocyanine green 
      angiographic findings. There were two different patterns on indocyanine green 
      angiograms. In the first pattern, both feeder and draining vessels were visible 
      and network vessels showed characteristic findings of choroidal 
      neovascularization (CNV). Points of focal dilatation on marginal vessels were 
      comprised of polypoidal lesions. In the second pattern, neither feeder nor 
      draining vessels were visible and there were few network vessels. The points of 
      deformation of network vessels appeared to be polypoidal lesions. The former 
      represents a deformation of CNV, i.e. polypoidal CNV; the latter is thought to 
      result from abnormalities of the choroidal vessels, i.e. PCV in the strict sense. 
      2. Pathological findings of PCV in the strict sense. The histopathological 
      characteristics of PCV in the strict sense, which had been eliminated by 
      vitrectomy, were dilatation and hyalinization of vessels, massive exudative 
      changes in blood plasma, basement membrane-like deposits and scant granulomatous 
      tissue. These vessels were located beneath Bruch's membrane. The findings 
      indicate that PCV in the strict sense arises from hyalinized arteriolosclerosis 
      of choroidal vessels. 3. Optical coherence tomographic findings. A break was 
      found in the high reflective line which revealed Bruch's membrane. Low reflective 
      tissue was observed at the break corresponding to a feeder vessel. The high 
      reflective line which corresponded to the retinal pigment epithelium was uneven, 
      and highly elevated portions of the RPE corresponded to thick network vessels and 
      polypoidal lesions. Feeder vessels are thought to invade via Bruch's membrane to 
      form network vessels and polypoidal lesions at the termini of the network 
      vessels, both of which push the RPE upward. Therefore, polypoidal CNV is thought 
      to represent a deformation of the CNV under the RPE. In PCV in the strict sense, 
      an irregular thickened line with highly reflective substances adhering to the 
      lower portion of it, curved downward corresponding to the site at which the 
      network vessel filling began. A dimple in the RPE was observed which paralleled 
      the curve of the line. The RPE was pushed upward, corresponding to the network 
      vessels. Judging from the results of histopathological studies, abnormal vessels 
      may be pushed up the RPE secondary to an increase in intravascular pressure due 
      to the presence of several dilated vessels and by massive exudation from these 
      vessels within the choroid at network vessels. The dimple in the RPE might be 
      attributable to intra-choroidal pressure being decreased at the point at which 
      network vessel filling began. 4. Genetic findings. There were significant 
      differences in all distributions of ARMS 2 (A69S) between the polypoidal CNV and 
      control groups. In contrast, the distribution of ARMS 2 (A69S) did not differ 
      between the PCV in the strict sense group and the control group. The ARMS 2 
      (A69S) gene is closely related to age-related macular degeneration. Polypoidal 
      CNV was thought to be associated with age-related macular degeneration. 5. 
      Treatment of subfoveal PCV. Mean visual acuity improved 1 year after photodynamic 
      therapy (PDT). Good visual acuity, small lesion size of the network of vessels 
      with polypoidal lesions, and the absence of subfoveal polypoidal lesions were 
      pre-PDT predictors that corresponded to the improvement in vision. However, mean 
      visual acuity had decreased to a level similar to that prior to PDT at 2 and 3 
      years after treatment. In PCV in the strict sense, the branching vascular network 
      persisted after PDT, and polypoidal lesions frequently recurred at the termini. 
      The branching vascular network sometimes expanded and was accompanied by 
      polypoidal CNV or classic CNV. These results indicate that repeated PDT, as 
      monotherapy, has limitations as a long-term treatment for PCV in the strict 
      sense. Intravitreal injection of ranibizumab for eyes with a visual acuity of 0.6 
      or more, which is not a good indication for PDT, achieved improvement in mean 
      visual acuity 1 year after the treatment, though the frequency of polypoidal 
      lesion regression was low. This procedure seems to be useful for eyes with good 
      visual acuity for a period of at least one year. 6. Conclusion. Using indocyanine 
      green angiography, optical coherence tomography and genetic testing, PCV was 
      classified into 2 groups, polypoidal CNV and PCV in the strict sense. PCV in the 
      strict sense was characterized by arteriolsclerosis histopathologically. 
      Polypoidal CNV is thought to represent deformation of CNV under the RPE in 
      age-related macular degeneration, while PCV in the strict sense is thought to be 
      due to choroidal vessel abnormalities. The long-term efficacy of repeated PDT as 
      monotherapy, for subfoveal PCV was limited. Further evaluation is necessary to 
      establish a treatment algorithm for PCV.
FAU - Yuzawa, Mitsuko
AU  - Yuzawa M
AD  - Division of Ophthalmology, Department of Visual Science, Nihon University, School 
      of Medicine, Chiyoda-ku, Tokyo, Japan. yuzawa.mitsuko@nihon-u.ac.jp
LA  - jpn
PT  - English Abstract
PT  - Journal Article
PT  - Research Support, Non-U.S. Gov't
PT  - Review
PL  - Japan
TA  - Nippon Ganka Gakkai Zasshi
JT  - Nippon Ganka Gakkai zasshi
JID - 7505716
SB  - IM
MH  - Choroid/*blood supply
MH  - *Choroid Diseases/diagnosis/drug therapy/genetics/pathology
MH  - Fluorescein Angiography
MH  - Humans
MH  - *Macular Degeneration/diagnosis/drug therapy/genetics/pathology
MH  - Photochemotherapy
EDAT- 2012/05/10 06:00
MHDA- 2012/07/25 06:00
CRDT- 2012/05/10 06:00
PHST- 2012/05/10 06:00 [entrez]
PHST- 2012/05/10 06:00 [pubmed]
PHST- 2012/07/25 06:00 [medline]
AID - 10.4264/numa.71.282 [doi]
PST - ppublish
SO  - Nippon Ganka Gakkai Zasshi. 2012 Mar;116(3):200-31; discussion 232. doi: 
      10.4264/numa.71.282.