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1 hepatocytes 7 days before challenge with a K skin graft.
2 moval of necrotic tissues covered by a split-skin graft.
3 e of donor skin and rejection of third-party skin graft.
4 ific CD8(+) T cells were more abundant after skin graft.
5 ction after challenge with an OVA-expressing skin graft.
6 uces a rapid destruction of the transplanted skin graft.
7 nstruction using a temporary split-thickness skin graft.
8 nely closed with a Vicryl mesh followed by a skin graft.
9 al blood mononuclear cells allogeneic to the skin graft.
10 g the CD8 T cell memory response to a second skin graft.
11 I on recipient DCs during the life span of a skin graft.
12 and cardiac transplants but not conventional skin grafts.
13 mice rejected MHC mismatched murine C57BL/6J skin grafts.
14 arget antigen and to rejection of autologous skin grafts.
15 e could be prevented by simultaneous class I skin grafts.
16 nance was observed in primarily vascularized skin grafts.
17 ve transfer of Ab to SCID mice bearing human skin grafts.
18 in WF recipients after rejection of the ACI skin grafts.
19 and effector function of TCR-tg T cells than skin grafts.
20 lerated rejection of minor H-locus disparate skin grafts.
21 ocus allele (class II) identical third-party skin grafts.
22 nts subsequently received donor-strain MT or skin grafts.
23 female on B6 background) antigen-mismatched skin grafts.
24 s tested using mixed lymphocyte cultures and skin grafts.
25 allograft survival accepted ACI but not PVG skin grafts.
26 e mice that had been transplanted with human skin grafts.
27 orrelated with the involution and loss of Tg skin grafts.
28 two of four animals rejecting delayed donor skin grafts.
29 tivated exocytosis and inflammation in human skin grafts.
30 ly are able to effectively reject allogeneic skin grafts.
31 e marrow permanently accepted K(b) disparate skin grafts.
32 sfer into syngeneic Balb/c hosts bearing HA+ skin grafts.
33 of fibroblasts and keratinocytes in cultured skin grafts.
34 modulation led to permanent acceptance of F1 skin grafts.
35 and prevent normal pigmentation of resulting skin grafts.
36 kin grafts and promptly rejected third-party skin grafts.
37 nor (bm1 or F1) and third-party B10.BR (H-2) skin grafts.
38 olonged survival of minor antigen-mismatched skin grafts.
39 vely, one of them after receiving additional skin grafts.
40 d delayed rejection of subsequent donor-type skin grafts.
41 ficant reduction of mutant Krt75 mRNA in the skin grafts.
42 Four patients (two in each study group) had skin grafts.
43 ere given donor, third-party, and autologous skin grafts.
44 graft and promptly rejected the third-party skin grafts.
45 ) T cells and subsequently the acceptance of skin grafts.
46 nor acceleration of rejection of allogeneic skin grafts.
47 fter simultaneous peptide administration and skin grafting.
48 lass I-disparate bm1 mice 7 d prior to donor skin grafting.
49 Donor-specific tolerance was tested by skin grafting.
50 afts, although incomplete tolerance to donor skin grafting.
51 burn excision and autologous split-thickness skin grafting.
52 well as secondary wound closure by means of skin grafting.
53 s, and then repair with advancement flaps or skin grafting.
54 ignificantly accelerated rejection of OVA(+) skin grafted 7 days after hepatocyte transplantation.
55 imal doses of tacrolimus to induce long-term skin graft acceptance in this stringent transplant model
59 rAAV-K-treated B10.BR animals primed with K skin grafts also accepted secondary K skin grafts in the
60 group 1 animals were tolerant to their donor skin graft and promptly rejected the third-party skin gr
61 ative for this reactivity was immunized by a skin graft and subcutaneous injections of peripheral blo
63 myeloablative regimen were tolerant to donor skin grafts and both primary and secondary donor MT (>90
64 w that antigen-specific Tregs induce, within skin grafts and dendritic cells, the expression of enzym
65 prior priming with allogeneic splenocytes or skin grafts and exhibited features of memory as it could
66 indirect alloresponse against MHC-mismatched skin grafts and hence the generation of IgG alloantibodi
67 n 10, and PD-1 (and PD-L1/PD-L2) in tolerant skin grafts and increased expression of mRNAs for indole
68 evidenced by the acceptance of second donor skin grafts and loss of circulating donor-specific Abs.
73 glutamate is increased in mice that receive skin grafts and that mice treated with glutamate recepto
74 s the rejection of secondary donor-type test skin grafts and to inhibit alloreactive CD8(+) T cell ac
75 ic (H-2d) cardiac grafts and secondary donor skin grafts, and that splenocytes from these tolerant mi
76 the primary graft, three with donor-matched skin grafts, and two with donor class-I peptides to elim
77 al lymphoid organs rejected H-Y incompatible skin grafts as rapidly as wild type mice and exhibited n
80 r histocompatibility complex (MHC) disparate skin grafts at the peak of acute rejection (seven days p
83 we describe bone marrow transplantation and skin grafting between WT and KO mice to assess the contr
84 blockade accelerated MHC class II-mismatched skin graft (bm12 (I-Abm12) into B6 (I-Ab)) rejection in
86 transplantation tolerance to OVA-expressing skin grafts, but Foxp3-independent tolerance when the Ag
87 transferred allogeneic Tregs and allogeneic skin grafts, but tolerance to such allografts that lacke
89 t rejected donor MHC-matched split-thickness skin grafts by day 25, without changes in renal graft fu
90 ol, were always able to prevent rejection of skin grafts by naive CD4(+) T cells, and did so with no
91 Acceptors of VCA were tolerant of a donor skin graft challenge and no anti-donor antibodies were d
92 Long-term acceptors were tolerant to a donor skin graft challenge even in the absence of peripheral b
93 short-term CD4 blockade at the time of first skin graft challenge only delayed alloreactive CD8 activ
94 LPS infusion in conjunction with donor-type skin graft challenge, failed to break Treg-mediated immu
97 h donor-matched skin allografts accept these skin grafts, demonstrating progression to "true" toleran
100 k wave therapy (ESWT) can enhance healing of skin graft donor sites, this study focused on shock wave
103 bred strain CBA do not reject syngeneic male skin grafts even though they mount a T-cell response aga
104 poq-Cre(tg/+)Pparg(fl/fl) mice, coupled with skin graft experiments, showed that the early defects ob
107 n adhesion strength compared with staples in skin graft fixation, and removal force of ~4.5 N cm(-2)
108 ouse system, we transplanted mice with human skin grafts followed by allogeneic populations of PBMCs
110 d as newborns with human HSCs rejected human skin grafts from a histoincompatible donor, indicating t
112 study from this laboratory demonstrated that skin grafts from alpha-1,3 galactosyltransferase knockou
118 ll KA274 reconstituted C57BL/6 mice accepted skin grafts from HLA-A2.1 transgenic mice for more than
119 ensitized eight macaques with two sequential skin grafts from MHC-mismatched donors; four of them wer
122 ould also be prevented locally by implanting skin grafts from normal mice onto the backs of EPP recip
123 h HY-specific Tregs protected syngeneic male skin grafts from rejection by immune-competent recipient
127 ats, as evidenced by acceptance of secondary skin grafts from the hindlimb donor strain and rejection
128 layed donor-specific tolerance also accepted skin grafts from the same, but not a third-party, donor
129 minor histocompatibility Ag (HY)-mismatched skin grafts from TORC2(DC-/-) donors into wild-type reci
132 d the survival of Flt3L(-)/(-) heart or tail skin grafts (H2(b)) in allogeneic wt (BALB/c; H2(d)) rec
134 rn patient who developed skin lesions on her skin-graft harvest and skin-graft recipient (burn) sites
135 lerance does not extend universally to donor skin grafts, however, with two of four animals rejecting
143 ly T-cell-mediated rejection of transplanted skin grafts in mice via the release of a proteolytically
144 e survival of DLA-identical HC donor-derived skin grafts in recipients with MC compared to normal rec
145 Th17 cell lines could inflict on allogeneic skin grafts in the absence of other adaptive lymphocytes
146 with K skin grafts also accepted secondary K skin grafts in the long term (MST>100 days) compared to
148 ily vascularized cardiac allografts mimicked skin grafts in the observed immunodominance, and H60 imm
149 ed in long-term Treg-dependent acceptance of skin grafts in the setting of innate immune signals that
150 n all nine of the surviving HC donor-derived skin grafts in this group, but there was no graft loss a
151 contrast, rejection of ovalbumin transgenic skin grafts in TORC2(DC-/-) recipients was unaffected.
152 nor histocompatibility (H) antigen-disparate skin grafts in vivo and induces MHC-restricted CTL respo
155 mals led to fulminant rejection of heart and skin grafts, in contrast to grafts on group 2 animals th
156 tantially improve healing quality and reduce skin grafting incidents and thus pave the way for clinic
157 monstrated that IL-17 in HPV16 E7 transgenic skin grafts inhibited effective host immune responses ag
158 ody provide a model optimized for both human skin graft integrity and engraftment of a functional hum
161 f the nail unit followed by a full-thickness skin graft is a safe and efficient treatment for SUSCC w
163 Obtaining pigmentary function in autologous skin grafts is a current challenge for burn surgeons as
165 We report that rejection of primary GalT-KO skin grafts led to an anti-xenogeneic humoral response w
172 an survival time in the fully MHC-mismatched skin graft model using this protocol is more than 100 da
179 Rag(-/-) skin graft recipients, resulted in skin graft necrosis in all recipients; the generation an
180 ltrate and no chronic rejection in the donor skin grafts of BCNU treated mice compared no BCNU treate
193 participants whose treatment had failed, had skin grafting, or were coinfected with human immunodefic
197 r CD200 BL/6 recipients of BALB/c cardiac or skin grafts received low-dose rapamycin (0.5 mg/kg) at 3
198 elevated plaques were observed in all human skin grafts receiving BP IgE (n=11), but not control IgE
199 ance was not observed because donor-specific skin graft rechallenge in nonrejecting animals resulted
202 B(high)CD4(+) effector T cells into Rag(-/-) skin graft recipients, resulted in skin graft necrosis i
203 eactive CD4(+) T cells were transferred into skin graft recipients, we observed that a critical CD4(+
205 of the nail unit followed by full-thickness skin graft reconstruction from January 1, 2000, to Augus
206 xcision of the nail unit with full-thickness skin graft reconstruction on a series of patients with S
207 tion and increased apoptosis in vitro and in skin grafts regenerated on mice, which was correlated wi
209 plore the involvement of Langerhans cells in skin graft rejection and describe fascinating results.
211 no inhibition or even acceleration of donor skin graft rejection compared with non-DST control (naiv
212 od subtly yet reproducibly decreases time to skin graft rejection elicited by central but not effecto
214 drug-modified DCs prior to transplantation, skin graft rejection kinetics were similar to those in n
215 diac rejection, chronic renal rejection, and skin graft rejection were compared using CD20 or CD19 mA
216 pecific Treg cells significantly delayed CBK skin graft rejection without any other immunosuppression
217 ates that subsequent to T cell initiation of skin graft rejection, platelets contribute to further T
218 administered systemically in mouse models of skin graft rejection, these nanosensors preferentially a
219 umab (anti-CD3 mAb) and found it could delay skin graft rejection, whereas ipilimumab (anti-CTLA-4 [c
225 G-Neutrophils, were confirmed by third-party skin graft rejection; importantly, a graft-versus-leukem
226 le chimeric transplants, preserved antidonor skin graft responses, and normal serum creatinine levels
227 at presensitization of recipients with donor skin grafts results in rejection of subsequent renal all
228 model of fulminant meningococcemia in human skin grafted SCID mice using the wild-type strain 2C4.3.
229 was not permissive for linked suppression to skin grafts sharing donor and third-party alloantigens,
231 ant rejection, whereas haptoglobin-deficient skin grafts showed delayed acute rejection and antidonor
234 rogeny of bone marrow SP cells and prolonged skin graft survival across this class I MHC barrier unti
236 e that adoptive transfer of B cells prolongs skin graft survival but only when the B cells were isola
239 ctive T cell frequencies exhibited long-term skin graft survival upon CD28/CD154 blockade, whereas si
241 anti-CD40L blockade plus drug-modified DCs, skin graft survival was prolonged, suggesting endogenous
243 ntibody production and resulted in prolonged skin graft survival, suggesting the induction of both T-
251 ect on the rejection of skin, CXCR3-/- donor skin grafts survived significantly longer than WT contro
252 We investigated whether donor CD200 BL/6 skin grafts taken from primary control or CD200 recipien
253 nsferred into lymphopenic recipients of male skin grafts, Th17 lines elicited a damaging reaction wit
254 that can prevent rejection of donor-specific skin grafts that are mediated by naive CD45RB(high)CD4(+
255 rejection of the first MHC class I disparate skin graft, the suppressive environment was maintained,
256 etion in CBA mice that received CBK (H2k+Kb) skin grafts, the expanded Treg cells preferentially accu
258 in penile reconstruction are glansectomy and skin grafting to fashion a neoglans in penile cancer and
259 formed only small skin tumors in orthotopic skin grafts to CXCR2 intact hosts, whereas transformed w
260 se against sequential GalT-KO and allogeneic skin grafts to determine whether such serial grafts coul
265 Mechanical stimulation of DM skin or DM skin graft transplanted onto the WT host resulted in red
266 cells injected under full-thickness COL-EGFP skin grafts transplanted in nonreporter mice developed i
269 have been used in the field of medicine for skin grafts, treatment of burns, and ulcerated skin cond
270 have been used in the field of medicine for skin grafts, treatment of burns, ulcerated skin conditio
272 ells had a significantly higher incidence of skin graft-versus-host disease compared with mice receiv
273 toxicity was observed, except for a grade II skin graft-versus-host disease in the patient treated fo
274 icity in eight patients (38%), grade 1 acute skin graft-versus-host disease in two patients (10%), an
277 been replaced by donor cells, exhibit marked skin graft-vs-host disease, demonstrating that LC can tr
278 nged compared to normal recipients even when skin grafting was delayed until after rejection of the H
279 Survival of DLA-identical HC donor-derived skin grafts was also significantly prolonged compared to
280 after nonmyeloablative conditioning, DST to skin grafts was evaluated in dog leukocyte antigen (DLA)
282 recipients primed with a H-2K-expressing (K) skin graft were injected with rAAV-expressing H-2K (rAAV
290 dvantage was lost when vascularized CXCR3-/- skin grafts were used as donors in the SCID model of rej
291 matched but minor antigen-mismatched tissue (skin) grafts were transplanted into MHC-heterozygous rec
292 marrow prevented rejection of K(b) disparate skin grafts when adoptively transferred into immunodefic
293 emory CD4 T cells lose the ability to reject skin grafts when transiently placed in an environment in
294 geneic PBMCs alone consistently reject human skin grafts, whereas those also receiving Tregs display
296 (BL/6 WT) or CD200(tg) mice received BALB/c skin grafts with rapamycin (1 mg/kg/36 hr) for 7 days.
297 Flt3L(-)/(-) mice rejected BALB/c heart or skin grafts with similar kinetics as B6 wt recipients.
298 MR1-treated mice also accepted a second Tg skin graft without durable production of hBPAG2-specific
300 (82% acceptance, n = 19) as well as to donor skin grafts without recipient immunosuppression (57% acc