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Prepublished online as a Blood First Edition Paper on September 12, 2002; DOI 10.1182/blood-2002-03-0944.
HEMOSTASIS, THROMBOSIS, AND VASCULAR BIOLOGY
From the Departments of Pediatrics and Blood
Transfusion, Nara Medical University, Kashihara, Japan;
the Division of Transfusion Medicine, National Cardiovascular Center,
Suita, Osaka, Japan; and the Center for Molecular
Medicine, Jichi Medical School, Kawachi-gun, Tochigi,
Japan.
To explore the mechanisms that underlie the bleeding tendency in
type 2A and 2B von Willebrand disease (VWD), we analyzed the mural
thrombus generation process on a collagen surface under physiologic
blood flow in a perfusion chamber using whole blood from these VWD
patients. At a low shear rate (50 s The contributions of von Willebrand factor
(VWF) to platelet plug formation at sites of vessel disruption are
fundamental to primary hemostasis.1-4 Indeed, patients
with von Willebrand disease (VWD) who congenitally lack VWF exhibit a
bleeding tendency.5,6 This prevalent bleeding disorder is
currently categorized as 3 major types: type 1 (partial) and type 3 (complete) are both quantitative defects of VWF, whereas type 2 is
characterized by a qualitative or functional defect in VWF, despite
significant plasma levels of this protein.7,8
Among type 2 VWD, a subtype (2A) is recognized in which larger VWF
multimers are completely lacking in the plasma.7,8 The
thrombogenic activities of VWF, which have so far been evaluated based
mainly on the platelet aggregability in the presence of ristocetin, are
strictly dependent on its multimeric structure, so that bleeding
symptoms in type 2A VWD are clearly explained by defective
ristocetin-induced platelet aggregation (RIPA) in a classical platelet
aggregometer.2,8 By contrast, enhanced RIPA is observed in
blood of subtype 2B patients due to the increased or spontaneous
binding of their VWF to the platelet membrane receptor glycoprotein
(GP) Ib To clarify the mechanisms that underlie the bleeding tendency in type
2A and 2B VWD, we analyzed the real-time process of mural thrombus
generation, from initial platelet adhesion to spatial thrombus
development, on a type I collagen-coated glass surface under
physiologic flow conditions with various shear rates in blood of these
VWD patients. Consistent with the clinical bleeding symptoms and
defective RIPA, the observation by epifluorescence microscopy confirmed
that thrombus generation in type 2A VWD blood was highly impaired under
flow conditions of high shear rates. This impairment became more
prominent with increasing shear rates, indicating the critical
shear-dependent functions of larger VWF multimers under flowing blood.
In type 2B VWD, thrombus generation under high shear was less defective
compared with type 2A. However, when the height and volume of type 2B
thrombi finally generated were analyzed in detail by confocal laser
scanning microscopy (CLSM), the spatial development of mural thrombi
was significantly reduced, even if initial platelet adhesion occurred
normally, providing a mechanism to explain the bleeding tendency in
these patients.
Materials
Patient profiles
Blood collection and platelet labeling This work was approved by the institutional review board of Nara Medical University Hospital. After informed consent, blood was collected from patients and healthy volunteers using argatroban (final concentration 240 µmol/L) as an anticoagulant.17-19 Anticoagulated whole blood was kept at 37°C and used in perfusion studies within 30 minutes after blood collection. Mepacrine (final concentration 10 µmol/L) was added to the blood prior to perfusion to label platelets, allowing visualization of platelet-surface interaction with epifluorescence videomicroscopy.Flow chamber and epifluorescence videomicroscopy Type I collagen-coated glass coverslips were prepared as described17-19 and placed in a parallel plate flow chamber that varies shear rate in a linear manner.17-20 In brief, this chamber was designed to reproduce shear rates starting from a predetermined maximum value at the entrance and falling to zero at the exit.21 The chamber was assembled and mounted on a microscope (BX60, Olympus, Tokyo, Japan) equipped with epifluorescent illumination (BX-FLA, Olympus) and a CCD camera system (U-VPT-N, Olympus) as described.17-19 Whole blood containing mepacrine-labeled platelets was aspirated through the chamber by a syringe pump (model CFV-3200, Nihon Kohden, Tokyo, Japan) at a constant flow in a 37°C thermostatic air bath (model UI-50, Iuchi, Osaka, Japan).19-22 Unless otherwise indicated, the entire thrombus generation process, from initial platelet-surface interaction to platelet aggregate accumulation on the surface, was observed in real time at positions of the flow chamber corresponding to 50 s 1 and 1500 s1 and recorded with a
videocassette recorder (Hi8 VIEWCAM, Sharp, Osaka,
Japan).19-22 The wall shear rate of 50 s1 or
1500 s1 is considered to be a typical low or high shear
flow, respectively.17,19,21 In some experiments, perfusion
with higher wall shear rates was also performed by changing flow rate.
Time-course images of thrombus formation in videotape were digitized by a frame grabber (DIG98, DITECT, Tokyo, Japan) and subjected to computer-assisted analysis with an image processing application (Win ROOF, Mitani, Fukui, Japan). Platelet adherence to the surface was evaluated using Win ROOF software to determine the percentage of the area covered by adhering platelets in a defined area (surface coverage) after background subtraction, setting the threshold value and binarization of each image.19,21,22 Confocal laser scanning microscopy (CLSM) Platelet thrombi generated on a collagen-coated surface were fixed at 7 minutes after the initial platelet-surface interaction by gradual exchange of whole blood with fixation buffer (0.1 M phosphate-buffered saline [PBS] containing 4% paraformaldehyde, pH 7.4) at 37°C under continuous flow for 10 minutes. In preliminary experiments, the entire fixation process in perfusion of blood containing mepacrine-labeled platelets was observed in real time by epifluorescence microscopy to confirm fixation of the generated platelet thrombi without collapse or detachment from the collagen surface. After fixation, the perfusion chamber was disassembled, and a coverslip was rinsed 3 times with PBS, mounted in Dako fluorescent mounting medium (DAKO, Carpinteria, CA) as an antifade medium, and viewed by CLSM (MRC-600, Nippon Bio-Rad Laboratories, Tokyo, Japan). Mepacrine fluorescence corresponding to platelets was examined at an excitation wavelength of 488 nm with a barrier filter at 500 nm. Specimens were viewed at 1-µm intervals from the collagen surface to a height of 60 µm from the surface. Each image was digitized after background subtraction to calculate thrombus height and volume in a frame with the assistance of Win ROOF software.Fluorescence labeling of monoclonal antibodies The F(ab')2 fractions of anti-VWF or antifibrinogen IgG were concentrated to 1 to 3 mg/mL, dialyzed with 20 nmol/L phosphate-buffered saline (pH 7.35), and labeled using FluoroLink MAb Cy2 or Cy3 labeling kit according to the manufacturer's protocol. Cy2 and Cy3 produce a green and orange signal, respectively. These fluorescence-labeled F(ab')2 fractions were stored at 4°C until used.Evaluation of VWF and fibrinogen distribution within thrombi In some experiments when platelets were not labeled with mepacrine, a coverslip fixed with paraformaldehyde was double-stained with 100 µL of a solution mixture of Cy2-labeled anti-VWF and Cy3-labeled antifibrinogen F(ab')2 (each at 0.24 µg mL) for 2 hours at 37°C and viewed with CLSM. These conditions for immunohistochemical staining were determined in preliminary experiments that confirmed the sufficient infiltration of fluorescence-labeled antibodies into thrombi that is, the portions furthest from the
outside surface were stained. Cy2 fluorescence (green) was examined at
an excitation wavelength of 488 nm with a barrier filter at 500 nm,
whereas Cy3 fluorescence (orange) was at an excitation wavelength of
529 nm with a barrier filter at 550 nm to assess the distribution of
fibrinogen and VWF within thrombi.
Thrombus generation on a collagen surface in type 2A VWD under flow conditions In perfusion of healthy control blood, platelets increasingly accumulate on a collagen surface as a function of time when observed with an epifluorescence microscopy in real time under both low and high shear rate conditions.19 The extent of thrombus generation in all type 2A patients examined here was comparable to that of a healthy control under a low shear rate (50 s1), whereas
thrombus generation was significantly reduced in all type 2A patients
examined under a typical high shear rate condition (1500 s1), as judged by visual recognition (Figure
2) and time-course changes in surface
coverage (Table 2). Application of
various shear rates to a patient's blood confirmed the comparable
surface coverage of thrombi finally generated in a type 2A patient and in a healthy control at lower shear rates (340 s1 or
less) as well as the apparent reduction of thrombus generation at shear
rates above 630 s1 (Figure
3). These observations clearly indicate
the critical involvement of larger VWF multimers in mural thrombus
generation on a collagen surface under flow conditions with high
shear rates.
Thrombus generation on a collagen surface in type 2B VWD under flow conditions Thrombus generation in type 2B VWD patients, like that in type 2A, was normal at a low shear rate (50 s1) (Figure 2) but
variable under a typical high shear rate (1500 s1)that
is, significantly reduced in 2 patients (2B-1 and -2) and normal in the
other 2 patients (2B-3 and -4) as judged by visual recognition (Figure
2) and surface coverage (Table 2). However, when higher shear rates
were applied, thrombus generation in a type 2B patient whose thrombus
generation was comparable to normal at a shear rate of 1500 s1 was apparently reduced at shear rates above 2040 s1, although it was more resistant to increasing shear
rates than that in a type 2A patient (Figure 3).
Confocal laser scanning microscopy (CLSM) of thrombi generated at a
shear rate of 1500 s 1
in type 2B VWD patients (2B-3, -4) whose thrombus generation at this
shear rate was initially judged as normal by epifluorescence microscopy
(Figure 2 and Table 2) showed that the height and volume of type 2B
thrombi were about half those of control thrombi, although surface
coverage was comparable to normal (Figure
4). Thus, 3-dimensional thrombus
development was impaired in these type 2B patients even at a shear rate
of 1500 s1, whereas 2-dimensional expansion occurred
normally. Indeed, the significant reduction in spatial thrombus
development in the type 2B patient was also observed on a collagen
surface preincubated with purified normal VWF containing highest VWF
multimers, where initial platelet adhesion must occur normally (Figure
4). In contrast, addition of purified VWF to type 2B VWD blood
completely reversed the defective spatial thrombus development in these
patients (Figure 4). In addition, the immunohistochemical staining
revealed that VWF, as compared with fibrinogen, was poorly integrated
into type 2B VWD thrombi (Figure 5).
These results suggest that an insufficient adhesive function of VWF,
rather than a platelet insufficiency, circulating in blood of the type
2B VWD patient accounts for defective spatial thrombus development
under high shear rate conditions.
Our experimental approach involving perfusion of whole blood from VWD patients through a flow chamber visibly reproduces the in vivo hemostatic events occurring under physiologic blood flow conditions. Thus, our findings might be more physiologically relevant than those obtained in previous closed stirring experimental systems such as a classic platelet aggregometer. Our data demonstrating the selective reduction of mural thrombus generation in type 2A VWD under high shear rates are more likely to reflect the lack of larger VWF multimers than the mild decrease of VWF antigen in these patient plasmas because type 1 VWD patients, whose VWF antigen levels in plasma are more than 30%, showed thrombus generation comparable to normal control under such flow conditions (results not shown). However, thrombus generation in type 2A under high shear rate is apparently less impaired than in type 3 VWD in which almost no platelet-surface interaction was observed in the same experimental conditions.19 Indeed, significant platelet adhesion and subsequent aggregation were confirmed in all type 2A VWD patients in the present study (Figure 2 and Table 2). In contrast, RIPA of type 2A VWD, like that in type 3 VWD, was completely defective as determined by classic platelet aggregometer. In addition, no significant improvement of the reduced thrombus generation in type 2A VWD patients could be observed by the preadsorption of collagen surface with normal multimeric VWF (results not shown). Thus, the pathogenic bleeding in type 2A VWD is assumed to be due to impaired mural thrombus growth rather than the lack of initial platelet adhesion to a thrombogenic surface typically observed in type 3 VWD. The smaller VWF multimers circulating in a type 2A patient's plasma, albeit in a slow and insufficient way, can play a role especially at the stage of initial platelet adhesion, while only highly multimerized VWF can conduct subsequent thrombus growth by contributing to local VWF density. Impaired platelet aggregation in type 2B VWD patients has never been
demonstrated so far in closed stirring experimental systems in vitro
such as a classic platelet aggregometer or cone-and-plate type
viscometer using platelet-rich plasma from
patients.9,10,23 Indeed, our epifluorescence microscopy
analysis failed to clearly demonstrate reduced thrombus generation in
some type 2B VWD patients at a typical high shear rate. However,
application of higher shear rates or the use of CLSM in this
experimental system successfully revealed the impairment of thrombus
growth in type 2B patients. Note that 2-dimensional thrombus expansion,
including initial platelet adhesion, does occur in type 2B VWD (Figure
2 and Table 2), consistent with the results of the previous flow study
that VWF synthesized by endothelial cells from a type 2B patient
normally supported platelet adhesion24 and with recent
flow study results indicating that a recombinant GP Ib
The molecular mechanisms underlying impaired thrombus generation in
type 2B VWD under high shear rates appear to be more complex, and it
remains unclear why an enhanced reactivity of type 2B VWF with platelet
GP Ib It has also been hypothesized that platelets flowing in type 2B VWD
blood may not function properly at a thrombogenic surface, because the
VWF binding site within GP Ib Together, our results confirm the shear rate-dependent reduction of thrombus generation in both type 2A and 2B VWD under physiologic flow conditions, a finding that has never been clearly demonstrable in previous in vitro soluble-phase platelet aggregation assays. This reduction may explain the bleeding tendency seen in these diseases and points to a critical function for larger VWF multimers at a stage of spatial growth of mural thrombi under high shear rate conditions, essential for proper hemostasis.
We thank M. Hoffman for editorial assistance.
Submitted April 5, 2002; accepted September 2, 2002.
Prepublished online as Blood First Edition Paper, September 12, 2002; DOI 10.1182/blood-2002-03-0944.
Supported in part by a grant from the Ministry of Education, Culture, Sports, Science and Technology of Japan to M.S. (nos. 11670780 and 13671074).
The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked "advertisement" in accordance with 18 U.S.C. section 1734.
Reprints: Mitsuhiko Sugimoto, Department of Pediatrics, Nara Medical University, 840 Shijo-cho, Kashihara, Nara 634-8522, Japan; e-mail: sugi-ped{at}naramed-u.ac.jp.
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  Y. Shida, K. Nishio, M. Sugimoto, T. Mizuno, M. Hamada, S. Kato, M. Matsumoto, K. Okuchi, Y. Fujimura, and A. Yoshioka Functional imaging of shear-dependent activity of ADAMTS13 in regulating mural thrombus growth under whole blood flow conditions Blood, February 1, 2008; 111(3): 1295 - 1298. [Abstract] [Full Text] [PDF]
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F. Banno, K. Kokame, T. Okuda, S. Honda, S. Miyata, H. Kato, Y. Tomiyama, and T. Miyata Complete deficiency in ADAMTS13 is prothrombotic, but it alone is not sufficient to cause thrombotic thrombocytopenic purpura Blood, April 15, 2006; 107(8): 3161 - 3166. [Abstract] [Full Text] [PDF]
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M. Mekrache, C. Bachelot-Loza, N. Ajzenberg, A. Saci, P. Legendre, and D. Baruch Activation of pp125FAK by type 2B recombinant von Willebrand factor binding to platelet GPIb at a high shear rate occurs independently of {alpha}IIb{beta}3 engagement Blood, June 1, 2003; 101(11): 4363 - 4371. [Abstract] [Full Text] [PDF]
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Abstract
Introduction
.
3 plays an essential role.
