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1 is clotting factor to treat individuals with hemophilia A.
2 FVIII inhibitors, and patients with acquired hemophilia A.
3 s is the basis of modern treatment of severe hemophilia A.
4 (LV)-mediated human platelet gene therapy of hemophilia A.
5 y treated males aged >/=12 years with severe hemophilia A.
6 elet-derived FVIII can improve hemostasis in hemophilia A.
7 obulin G1 (IgG1) in 165 patients with severe hemophilia A.
8 mice of 2 different strain backgrounds with hemophilia A.
9 pic variability is well recognized in severe hemophilia A.
10 cement products enable comprehensive care in hemophilia A.
11 lso arise spontaneously in cases of acquired hemophilia A.
12 variability found among patients with severe hemophilia A.
13 ng previously untreated patients with severe hemophilia A.
14 nt impediment to the effective management of hemophilia A.
15 required to prevent bleeding associated with hemophilia A.
16 the importance of F8 genotyping in nonsevere hemophilia A.
17 ombinant) impair the effective management of hemophilia A.
18 152 patients (1-65 years of age) with severe hemophilia A.
19 he immune response to FVIII in patients with hemophilia A.
20 of F8 gene mutations in patients with severe hemophilia A.
21 al mechanisms and therapeutic development in hemophilia A.
22 on and less frequent dosing in patients with hemophilia A.
23 d by discrete cell populations would correct hemophilia A.
24 approach to reduce inhibitor development in hemophilia A.
25 factor VIII (FVIII) replacement therapy for hemophilia A.
26 l mechanism for secretion defects leading to hemophilia A.
27 rotein and gene transfer-based therapies for hemophilia A.
28 r VIII (fVIII) results in moderate to severe hemophilia A.
29 improve treatment options for patients with hemophilia A.
30 n to factor VIII (FVIII) in a mouse model of hemophilia A.
31 us for on-demand treatment for patients with hemophilia A.
32 y and may deliver effective gene therapy for hemophilia A.
33 n preclinical studies of novel therapies for hemophilia A.
34 ically appropriate gene addition therapy for hemophilia A.
35 icity--toward successful treatment of murine hemophilia A.
36 auses the human congenital bleeding disorder hemophilia A.
37 offers a potential gene therapy strategy for hemophilia A.
38 other hemorrhages in young boys with severe hemophilia A.
39 fective in treating bleeding associated with hemophilia A.
40 ng-term and safe treatment for patients with hemophilia A.
41 ion as a therapeutic option for persons with hemophilia A.
42 and could represent a curative treatment for hemophilia A.
43 issense mutations lead to moderate to severe hemophilia A.
44 es (inhibitors) is the major complication in hemophilia A.
45 VIII alloantibody formation in patients with hemophilia A.
46 III (AAV5-hFVIII-SQ) in nine men with severe hemophilia A.
47 the life-span among participants with severe hemophilia A.
48 outcomes with gene therapy in patients with hemophilia A.
49 potential use of ADHLSCs in the treatment of hemophilia A.
50 lating this strategy to clinical therapy for hemophilia A.
51 sent in inhibitor plasmas from patients with hemophilia A.
52 of previously untreated patients with severe hemophilia A.
53 ries is 30% for hemophilia A, 37% for severe hemophilia A, 24% for hemophilia B, and 27% for severe h
54 rities of hemophilia A, 6.0 cases for severe hemophilia A, 3.8 cases for all severities of hemophilia
55 vantage for high-income countries is 30% for hemophilia A, 37% for severe hemophilia A, 24% for hemop
56 rities of hemophilia A, 9.5 cases for severe hemophilia A, 5.0 cases for all severities of hemophilia
57 0 males) is 17.1 cases for all severities of hemophilia A, 6.0 cases for severe hemophilia A, 3.8 cas
58 0 males) is 24.6 cases for all severities of hemophilia A, 9.5 cases for severe hemophilia A, 5.0 cas
62 early-phase study involving men with severe hemophilia A, a single intravenous injection of BIVV001
63 are a major complication in the treatment of hemophilia A, affecting approximately 20% to 30% of pati
64 tuting serum F8 activity in a mouse model of hemophilia A after hydrodynamic injection of Cas9-sgAlb
65 odies (inhibitors) in patients with acquired hemophilia A (AHA) and congenital hemophilia A (HA) are
71 tabases detailing >2100 unique mutations for hemophilia A and >1100 mutations for hemophilia B, these
78 ARC19499 corrects thrombin generation in hemophilia A and B plasma and restores clotting in FVIII
81 ed bleeding disorders, including carriers of hemophilia A and B, or with von Willebrand disease, have
85 nt of inhibitory antibodies in patients with hemophilia A and discuss how these findings may be inter
89 e tool, particularly in patients with severe hemophilia A and good risk profiles, and leads to a retu
93 II) antibodies that develop in patients with hemophilia A and in murine hemophilia A models, clinical
94 problems characteristic of individuals with hemophilias A and B suggest a link between specific defe
95 ents in intrinsic factor Xase function, i.e. hemophilias A and B, result in an impaired capacity to m
96 forts to extend AAV-mediated gene therapy to hemophilia A, and alternate approaches that may be usefu
97 ity criteria (male sex, age <6 years, severe hemophilia A, and no previous treatment with any factor
101 developed and tested our pipeline using the hemophilia A & B MIP design from the "My Life, Our Futur
102 tion and sickle cell anemia, thalassemia, or hemophilia A/B or von Willebrand disease were enrolled a
103 h sickle cell disease, beta-thalassemia, and hemophilia A/B or von Willebrand disease, respectively.
104 generate comparable curative fVIII levels in hemophilia A BALB/c mice after reduced-intensity total b
106 normalize plasma FVIII level and activity in hemophilia A, but does not prevent the inhibitory effect
107 ns for the use of pFVIII in gene therapy for hemophilia A, but may also have physiologic consequences
108 ucts have improved the care of patients with hemophilia A, but the short half-life of these products
109 These findings lay the foundation for curing hemophilia A by NHEJ knock-in of BDDF8 at Alb introns af
110 tly change the treatment paradigm for severe hemophilia A by providing optimal protection against all
114 Approximately 30% of patients with severe hemophilia A develop inhibitory anti-factor VIII (fVIII)
116 icacy in 2 global tests of hemostasis in the hemophilia A dog model indicate that further evaluation
117 hallenges with cFVIII-BDD in young and adult hemophilia A dogs did not induce the formation of neutra
118 to AAV-FVIII dogs and treatment-naive severe hemophilia A dogs for a multiweek dose-escalating period
122 ficacy and safety in dogs with hemophilia A (hemophilia A dogs) with minimally increased hemostasis a
128 ; plasma samples of 237 patients with severe hemophilia A enrolled in the SIPPET trial were collected
129 icles can be adapted to hemophilic patients (hemophilia A (F-VIII deficient) and hemophilia B (F-IX d
131 aluated 574 consecutive patients with severe hemophilia A (factor VIII activity, <0.01 IU per millili
132 ated men (18 to 65 years of age) with severe hemophilia A (factor VIII activity, <1%) to receive a si
135 nd biologic results in 15 adults with severe hemophilia A (factor VIII level, <=1 IU per deciliter) w
136 The risk for inhibitor development in mild hemophilia A (factor VIII levels between 5 and 40 U/dL)
137 factor VIII (FVIII) is used in patients with hemophilia A for treatment of bleeding episodes or for p
138 eotide repeat expansions in diseases such as hemophilia A, fragile X syndrome, Hunter syndrome, and F
143 e can affect hemostasis in a canine model of hemophilia, a good predictor of efficacy of hemophilia t
145 h acquired hemophilia A (AHA) and congenital hemophilia A (HA) are primarily directed to the A2 and C
150 factor VIII (FVIII) inhibitors seen in black hemophilia A (HA) patients is not due to a mismatch betw
159 ors for replacement therapy of patients with hemophilia A has raised the life expectancy of these lif
160 vel recombinant FVIII (rFVIII) therapies for hemophilia A have been in clinical development, which ai
161 approximately 50% of individuals with severe hemophilia A) have been grouped with the former on the b
162 ansfer of a factor VIII (FVIII) plasmid into hemophilia A (HemA) mice achieved supraphysiologic FVIII
164 e potential efficacy and safety in dogs with hemophilia A (hemophilia A dogs) with minimally increase
165 ts with inherited bleeding disorders such as hemophilia A, hemophilia B, and von Willebrand disease.
166 in previously untreated patients with severe hemophilia A, high-dosed intensive FVIII treatment incre
168 e very early phenotypic expression of severe hemophilia A in 621 consecutively enrolled, well-charact
169 a factor VIII concentrate for patients with hemophilia A including efficacy, availability, risk of t
170 od from F8-/-/PN-1-/- and from patients with hemophilia A incubated with a PN-1-neutralizing antibody
171 inhibitory Abs to factor VIII in people with hemophilia A indicate a complex process involving multip
172 y in previously treated subjects with severe hemophilia A investigated safety and pharmacokinetics of
180 proven benefits, prophylactic treatment for hemophilia A is hampered by the short half-life of facto
181 nsequences and result in a potential "cure." Hemophilia A is often complicated by the development of
182 t complication of treatment in patients with hemophilia A is the development of alloantibodies that i
183 n complication of treatment of patients with hemophilia A is the development of anti-factor VIII (fVI
184 with severe cases of congenital or acquired hemophilia A is the development of inhibitor antibodies
187 or previously untreated children with severe hemophilia A, it is unclear whether the type of factor V
189 ibodies (inhibitors) in patients with severe hemophilia A may depend on the concentrate used for repl
190 factor VIII (hFVIII) plasmid gene therapy in hemophilia A mice also leads to strong humoral responses
191 olerance to hFVIII in hFVIII plasmid-treated hemophilia A mice and allowed persistent, high-level FVI
192 olerance in syngeneic hFVIII plasmid-treated hemophilia A mice and reduced the production of antibodi
193 blood outgrowth endothelial cells (BOECs) to hemophilia A mice and showed that these cells remained s
194 ious times after transplantation (7-90 days) hemophilia A mice and their control mice counterparts we
195 or VIII (fVIII) C2 domain immune response in hemophilia A mice consists of antibodies that can be div
197 lasma FVIII levels increased in transplanted hemophilia A mice during this period to 8% to 12% of wil
198 -type mice through 50 weeks, while untreated hemophilia A mice exhibited no detectable FVIII activity
199 derived mesenchymal stromal cells, protected hemophilia A mice from bleeding challenge with appearanc
201 ower expression levels relative to mFVIIa in hemophilia A mice or in hemophilia B mice with inhibitor
202 urther, plasma FVIII activity in the treated hemophilia A mice was nearly identical to that in wild-t
204 responses against coagulation factor VIII in hemophilia A mice, even in animals previously sensitized
205 2bF8) gene therapy can improve hemostasis in hemophilia A mice, even in the presence of inhibitory an
207 ssion in platelets can restore hemostasis in hemophilia A mice, this approach has not been studied in
217 in patients with hemophilia A and in murine hemophilia A models, clinically termed "inhibitors," bin
218 Ferriere et al present an emicizumab-adapted hemophilia A mouse bleeding model that can help answer t
221 therapy can be lifesaving for patients with hemophilia A, neutralizing alloantibodies to FVIII, know
222 study presents mortality in 6018 people with hemophilia A or B in the United Kingdom during 1977 to 1
223 d 4 through 18 years with moderate or severe hemophilia A or B were monitored for bleeds for up to 1
224 and 25 participants with moderate or severe hemophilia A or B who did not have inhibitory alloantibo
225 sed thrombin generation in participants with hemophilia A or B who did not have inhibitory alloantibo
227 s, and the wave did not form in plasmas from hemophilia A or C patients who lack factors VIII and XI,
228 potency of ADHLSCs to control bleeding in a hemophilia A patient and assess the biodistribution of t
232 ompetence and inhibitor status by evaluating hemophilia A patients harboring F8-null mutations that w
234 ve and 174 inhibitor-negative Italian severe hemophilia A patients using a TaqMan genotyping assay.
235 on that affects approximately one-quarter of hemophilia A patients who have access to replacement the
239 o FVIII is a serious problem in treatment of hemophilia A patients, we investigated the potential of
252 ependent prolongation of clot lysis times in hemophilia A plasma and loss of TM-stimulated conversion
253 bin generation measurements in platelet-rich hemophilia A plasma revealed competition for TF, which p
254 ects were compared with 4 inhibitor-positive hemophilia A plasma samples with inhibitor titers of 1 B
255 lot lysis assay on TM-expressing cells using hemophilia A plasma, NAc-Hep prevented PF4-mediated inhi
256 untreated or minimally treated patients with hemophilia A; plasma samples of 237 patients with severe
257 velopment was investigated in all 407 severe hemophilia A previously untreated patients born in the U
258 Among 235 randomized patients with severe hemophilia A previously untreated with FVIII concentrate
259 different categories of patients with severe hemophilia A: previously untreated patients, multiply tr
260 VIII form a severe complication in nonsevere hemophilia A, profoundly aggravating the bleeding patter
261 ne tolerance induction(ITI) in patients with hemophilia A refractory to replacement therapy after the
263 ver, corrections of the propagation phase in hemophilia A required rFVIIa concentrations above the ra
264 h AAV5-hFVIII-SQ vector in participants with hemophilia A resulted in sustained, clinically relevant
265 r prophylaxis and treatment of patients with hemophilia A. rFVIIIFc is a recombinant fusion protein c
266 c epitope in FVIII were isolated from a mild hemophilia A subject (the proband) 19 weeks and 21 month
267 recombinant T-cell receptor obtained from a hemophilia A subject's T-cell clone, into expanded human
269 purified human anti-fVIIIAb, isolated from a hemophilia A subject, was used as a calibrator with a de
270 150 healthy donors and 39 inhibitor-negative hemophilia A subjects were compared with 4 inhibitor-pos
271 M, whereas 13 (33%) of the 39 inhibitor-free hemophilia A subjects were positive for anti-fVIIIAb in
273 the FVIII variant K1967I is associated with hemophilia A, suggests that these residues contribute to
274 man use of a new nonsubstitutive therapy for hemophilia A that can potentially be disruptive to the w
277 non-FVIII alternative to reduce bleeding in hemophilia A, the question of how much clotting is enoug
278 eas substitution of FVIII is the mainstay of hemophilia A therapy, treatment of patients with inhibit
280 Therefore, BM transplantation corrected hemophilia A through donor-derived mononuclear cells and
281 actor VIII inhibitors arise in patients with hemophilia A throughout life with a bimodal risk, being
282 factor VIII gene (F8) in black patients with hemophilia A to identify causative mutations and the bac
283 We randomly assigned young boys with severe hemophilia A to regular infusions of recombinant factor
284 actor VIII (FVIII), the protein deficient in hemophilia A, to elucidate the relationship between prot
286 its by diminishing bleeding complications in hemophilia A via restoration of TAFIa-mediated protectio
288 nhibitor development in patients with severe hemophilia A, we applied whole-exome sequencing (WES) an
289 g this strategy into the canine (c) model of hemophilia A, we increased cFVIII transgene expression b
291 pment of liver-directed AAV gene therapy for hemophilia A, while emphasizing the importance of long-t
292 ciation study (GWAS) involving patients with hemophilia A who were exposed to but uninfected with hum
293 e of anti-FVIII NNAs in patients with severe hemophilia A who were not previously exposed to FVIII co
295 ealthy individuals, patients with congenital hemophilia A with and without FVIII inhibitors, and pati
297 epopulation of the livers of mice that model hemophilia A with healthy endothelial cells restored pla
300 or VIII (FVIII) as a replacement therapy for hemophilia A would significantly improve treatment optio