S2'-subsite variations between human and mouse enzymes (plasmin, factor XIa, kallikrein) elucidate inhibition differences by tissue factor pathway inhibitor -2 domain1-wild-type, Leu17Arg-mutant and aprotinin.

Essentials Current antifibrinolytics - aminocaproic acid and tranexamic acid-can cause seizures or renal injury. KD1L17R -KT , aprotinin and tranexamic acid were tested in a modified mouse tail-amputation model. S2'-subsite variations between human and mouse factor XIa result in vastly different inhibition profiles. KD1L17R -KT reduces blood loss and D-dimer levels in mouse with unobserved seizures or renal injury. SUMMARY: Background Using tissue factor pathway inhibitor (TFPI)-2 Kunitz domain1 (KD1), we obtained a bifunctional antifibrinolytic molecule (KD1L17R -KT ) with C-terminal lysine (kringle domain binding) and P2'-residue arginine (improved specificity towards plasmin). KD1L17R -KT strongly inhibited human plasmin (hPm), with no inhibition of human kallikrein (hKLK) or factor XIa (hXIa). Furthermore, KD1L17R -KT reduced blood loss comparable to aprotinin in a mouse liver-laceration model of organ hemorrhage. However, effectiveness of these antifibrinolytic agents in a model of hemorrhage mimicking extremity trauma and their inhibition efficiencies for mouse enzymes (mPm, mKLK or mXIa) remain to be determined. Objective To determine potential differences in inhibition constants of various antifibrinolytic agents against mouse and human enzymes and test their effectiveness in a modified mouse tail-amputation hemorrhage model. Methods/Results Unexpectedly, mXIa was inhibited with ~ 17-fold increased affinity by aprotinin (Ki ~ 20 nm) and with measurable affinity for KD1L17R -KT (Ki ~ 3 µm); in contrast, KD1WT -VT inhibited hXIa or mXIa with similar affinity. Compared with hPm, mPm had ~ 3-fold reduced affinity, whereas species specificity for hKLK and mKLK was comparable for each inhibitor. S2'-subsite variations largely accounted for the observed differences. KD1L17R -KT and aprotinin were more effective than KD1WT -VT or tranexamic acid in inhibiting tPA-induced mouse plasma clot lysis. Further, KD1L17R -KT was more effective than KD1WT -VT and was comparable to aprotinin and tranexamic acid in reducing blood loss and D-dimer levels in the mouse tail-amputation model. Conclusions Inhibitor potencies differ between antifibrinolytic agents against human and mouse enzymes. KD1L17R -KT is effective in reducing blood loss in a tail-amputation model that mimics extremity injury.

Analysis of the factor XI variant Arg184Gly suggests a structural basis for factor IX binding to factor XIa.

BACKGROUND: A patient with factor XI (FXI) deficiency was reported with an Arg184Gly substitution in the FXI A3 domain. The A3 domain contains an exosite required for binding of FIX to activated FXI (FXIa). OBJECTIVE: To test the effects of the Arg184Gly substitution on FIX activation, and to characterize the FIX-binding site on FXIa. METHODS: Recombinant FXIa and FIX variants were used to identify residues involved in FIX activation by FXIa. Analysis of the FXI structure was used to identify potential FIX-binding sites. RESULTS: The Km for FIX activation by FXIa-Gly184 was approximately three-fold higher than for FXIa, suggesting that Arg184 is part of the exosite. Arg184 and the adjacent residues, Ile183 and Asp185, contribute to charged and hydrophobic areas that are not present in the FXI homolog prekallikrein (PK). Replacing residues 183-185 with alanine abolished exosite activity, similarly to replacement of the entire A3 domain with the A3 domain from PK (FXIa/PKA3). Reintroducing FXI residues 183-185 into FXIa/PKA3 partially restored the exosite, and replacing residues 183-185 and 260-264 completely restored exosite function. FIX in which the Ω-loop (residues 4-11) was replaced with the FVII Ω-loop was activated poorly by FXIa, suggesting that the FIX Ω-loop binds to FXIa. CONCLUSIONS: The results support a model in which the Ω-loop of FIX binds to an area on FXIa composed of residues from the N-terminus and C-terminus of the A3 domain. These residues are buried in zymogen FXI, and must be exposed upon conversion to FXIa to permit FIX binding.

Easy method of centralized fixation of endotracheal tube in cleft lip and palate surgery.

As we all know that fixation of endotracheal tube is very important aspect in cleft palate and maxillofacial surgery. During cleft palate and oral surgery various methods of fixation and modified tubes are deviced to make surgery safer and ergonomically better. Our method consist of 3 point fixation of tube (RAE) with dynaplast, which is freely available, cheap and good Adhesive quality. Dynaplast divided into 3 phalanges (one central and two lateral) and one portion undivided as central limb. This undivided central limb is fixed in centre of chin and other 3 phalanges wrap around tube on either side. This fixation totally takes away any lateral movements of tube. This method can be used with any tube (RAE/ Oxford/Flexometallic). Our method is described for its simplicity, ease and convinence and result which impart universally similar results with all different members of our anesthetist team.

National programme for prevention of burn injuries.

The estimated annual burn incidence in India is approximately 6-7 million per year. The high incidence is attributed to illiteracy, poverty and low level safety consciousness in the population. The situation becomes further grim due to the absence of organized burn care at primary and secondary health care level. But the silver lining is that 90% of burn injuries are preventable. An initiative at national level is need of the hour to reduce incidence so as to galvanize the available resources for more effective and standardized treatment delivery. The National Programme for Prevention of Burn Injuries is the endeavor in this line. The goal of National programme for prevention of burn injuries (NPPBI) would be to ensure prevention and capacity building of infrastructure and manpower at all levels of health care delivery system in order to reduce incidence, provide timely and adequate treatment to burn patients to reduce mortality, complications and provide effective rehabilitation to the survivors. Another objective of the programme will be to establish a central burn registry. The programme will be launched in the current Five Year Plan in Medical colleges and their adjoining district hospitals in few states. Subsequently, in the next five year plan it will be rolled out in all the medical colleges and districts hospitals of the country so that burn care is provided as close to the site of accident as possible and patients need not to travel to big cities for burn care. The programme would essentially have three components i.e. Preventive programme, Burn injury management programme and Burn injury rehabilitation programme.

Fibronectin-adherent monocytes express tissue factor and tissue factor pathway inhibitor whereas endotoxin-stimulated monocytes primarily express tissue factor: physiologic and pathologic implications.

BACKGROUND: Monocytes are critical cells in initiating physiologic and/or pathologic tissue factor (TF)-induced intravascular and extravascular coagulation. Monocytes constitutively express small amounts of TF and tissue factor pathway inhibitor (TFPI). Non-adherent lipopolysaccharide (LPS)-stimulated monocytes express significant amounts of TF; however, increased expression of TFPI by these cells is controversial. Further, whether fibronectin-adherent monocytes (mimicking conditions in the extravascular space) express sufficient TFPI to inhibit TF-procoagulant activity (PCA) is unknown. OBJECTIVE: To compare TF and TFPI expression by fibronectin-adherent and LPS-stimulated non-adherent monocytes. METHODS: Monocytes were isolated from normal peripheral blood, adhered to fibronectin or stimulated with lipopolysaccharide (LPS) under non-adherent conditions and examined for expression of TF and TFPI using quantitative real-time reverse transcription-polymerase chain reaction (RT-PCR), ELISA and factor X (FX) activation. RESULTS: Under LPS-free conditions, the fibronectin-adherent monocyte TF mRNA, antigen and activity were markedly upregulated. Notably, cell and microparticle (MP)-associated TF and alternatively spliced TF (asTF) were all upregulated. TFPI mRNA and antigen were also upregulated in the fibronectin-adherent monocytes, which significantly inhibited TF-PCA. TFPI mRNAs for both alpha and beta forms were detected. The peak in TFPI activity occurred in tandem with the peak in TF-PCA. In contrast, LPS-stimulated monocytes, which expressed cell and MP-associated TF and asTF, demonstrated only minimal expression of TFPI as determined by mRNA, antigen or inhibition of TF activity. CONCLUSION: Both LPS-stimulated and fibronectin-adherent monocytes demonstrate a procoagulant phenotype by expressing TF but only fibronectin-adherent monocytes express significant amounts of TFPI to control thrombin generation and fibrin formation in the context of extravascular space.

A cross-reactive material positive variant of coagulation factor XI (FXIP520L) with a catalytic defect.

Inherited deficiency of the trypsin-like protease factor (F) XI is associated with a mild to moderate bleeding diathesis. In most cases, FXI protein is reduced in plasma, and examples of dysfunctional circulating FXI variants are rare. We characterized the defect in one such variant with a proline to leucine substitution at residue 520. FXI Pro520 corresponds to chymotrypsin Pro161, and is conserved in most members of the chymotrypsin protease family. Recombinant FXI containing this substitution will be referred to as FXI(P161L). k(cat) for cleavage of chromogenic substrates and for activation of the natural FXIa substrate FIX is approximately 3-fold lower for activated FXI(P161L) (FXIa(P161L)) than for wild-type FXIa (FXIa(WT)), consistent with an abnormal protease active site. Inhibition of FXIa(P161L) by diisopropyl fluorophosphate is 2.4-fold slower than for FXIa(WT), suggesting distortion of the protease oxyanion hole. Binding to p-aminobenzamidine, a probe for the integrity of the S1 substrate-binding site, was similar for FXIa(WT) and FXIa(P161L). Rates of carbamylation of Ile16 were also similar for FXIa(WT) and FXIa(P161L), indicating that the critical salt bridge between Ile16 and Asp194 forms normally during protease activation. Cumulatively, the data demonstrate that Pro161 is required for normal active site oxyanion hole conformation in FXIa. Examination of the FXIa crystal structure and modeling studies indicate that Pro161 forms several hydrophobic contacts with adjacent amino acids that stabilize active site conformation. Leucine can be incorporated at position 161 in FXIa, but would not form the extensive stabilizing network of hydrophobic interactions formed by Pro161.

Reconstruction of abdominal wall by whole thigh flap.

Closure of extensive abdominal wall defects can be a very challenging task as there are no known large local or free vascularized flaps available that could cover the entire abdomen. Tensor fascia latae (TFL) has been widely used for abdominal wall reconstruction [Hill HL, Nahai F, Vasocnez LO. The tensor fascia lata myocutaneous free flap. Plast Reconstr Surg 1978;61:517-22]. However, the dimensions of the standard TFL flap limit its use in cases of large full thickness abdominal wall defects. Therefore, we have used an ingenious technique of raising the entire thigh skin as a fasciocutaneous flap (whole thigh flap) based on the concept of fusion of angiosomal territories, to reconstruct such a defect following excision of a large abdominal wall tumour.

The first epidermal growth factor-like domains of factor Xa and factor IXa are important for the activation of the factor VII--tissue factor complex.

During tissue factor (TF)-induced coagulation, the factor (F)VIIa-TF complex activates factor (F)X and factor (F)IX. Through positive feedback, the generated FXa and FIXa activate FVII-TF. The first epidermal growth factor-like (EGF1) domains of FX and FIX serve as important TF-recognition motifs when FVIIa-TF activates FX or FIX. Here, we investigated the role of EGF1 domains of FXa and FIXa during the activation of FVII-TF and inhibition by tissue factor pathway inhibitor (TFPI). FXaPCEGF1 (EGF1 domain of FXa replaced with that of protein C), and FXaQ49P (EGF1 domain mutant with impaired calcium-binding), and the corresponding FIXa mutants were generated, and their abilities to activate FVII-TF were compared with the wild-type (WT) enzymes. In the absence of TF, the rates of FVII activation were similar between WT enzymes and mutant FXa and FIXa proteases. In the presence of either soluble TF (sTF) or relipidated TF, each mutant of FXa or FIXa activated FVII-TF at a slower rate than the corresponding WT enzyme. Kinetics of inhibition of the amidolytic activity of WT and the mutant FXa proteases by either two-domain or full-length TFPI were similar. However, compared with the complex of TFPI-FXaWT, the abilities of the complexes of TFPI-FXa mutants to inhibit FVIIa-TF were impaired. We conclude that the EGF1 domains of FXa and FIXa are important for the activation of FVII-TF and for the formation of FVIIa-TF-FXa-TFPI complex.

The osseofasciocutaneous flap: a new method to transfer fibula along with a sufficient amount of skin.

We describe a new technique of bone transfer, using a deep fascial blood supply to transfer bone together with a large area of skin. The viability of this flap and further confirmation by isotope scanning have established that the bone transfer is vascularised. This provides a simple solution to the complex problem of leg trauma with massive skin and bone loss.

Structure and biology of tissue factor pathway inhibitor.

Human tissue factor pathway inhibitor (TFPI) is a modular protein comprised of three Kunitz type domains flanked by peptide segments that are less structured. The sequential order of the elements are: an N-terminal acidic region followed by the first Kunitz domain (K1), a linker region, a second Kunitz domain (K2), a second linker region, the third Kunitz domain (K3), and the C-terminal basic region. The K1 domain inhibits factor VIIa complexed to tissue factor (TF) while the K2 domain inhibits factor Xa. No direct protease inhibiting functions have been demonstrated for the K3 domain. Importantly, the Xa-TFPI complex is a much more potent inhibitor of the VIIa-TF than TFPI by itself. Furthermore, the C-terminal basic region of TFPI is required for rapid physiologic inhibition of coagulation and is needed for the inhibition of smooth muscle cell proliferation. Although a number of additional targets for attachment have been reported, the C-terminal basic region appears to play an important role in binding of TFPI to cell surfaces. A primary site of TFPI synthesis is endothelium and the endothelium-bound TFPI contributes to the antithrombotic potential of the vascular endothelium. Further, increased levels of plasma TFPI under septic conditions may represent endothelial dysfunction. We have proposed that the extravascular cells that synthesize TF also synthesize TFPI providing dual components necessary for the regulation of clotting in their microenvironment. Like the TF synthesis in these cells is augmented by serum, so is the case with the TFPI gene expression. TFPI gene knock out mice reveal embryonic lethality suggesting a possible role of this protein in early development. Since TF-induced coagulation is thought to play a significant role in many disease states, including disseminated intravascular clotting, sepsis, acute lung injury and cancer, recombinant TFPI may be a beneficial therapeutic agent in these disease states to attenuate pathologic clotting. The purpose of this review is to outline recent developments in the field related to the structural specificity and biology of TFPI.

Factor IXa:factor VIIIa interaction. helix 330-338 of factor ixa interacts with residues 558-565 and spatially adjacent regions of the a2 subunit of factor VIIIa.

The physiologic activator of factor X consists of a complex of factor IXa, factor VIIIa, Ca(2+) and a suitable phospholipid surface. In one study, helix 330 (162 in chymotrypsin) of the protease domain of factor IXa was implicated in binding to factor VIIIa. In another study, residues 558-565 of the A2 subunit of factor VIIIa were implicated in binding to factor IXa. We now provide data, which indicate that the helix 330 of factor IXa interacts with the 558-565 region of the A2 subunit. Thus, the ability of the isolated A2 subunit was severely impaired in potentiating factor X activation by IXa(R333Q) and by a helix replacement mutant (IXa(helixVII) in which helix 330-338 is replaced by that of factor VII) but it was normal for an epidermal growth factor 1 replacement mutant (IXa(PCEGF1) in which epidermal growth factor 1 domain is replaced by that of protein C). Further, affinity of each 5-dimethylaminonaphthalene-1-sulfonyl (dansyl)-Glu-Gly-Arg-IXa (dEGR-IXa) with the A2 subunit was determined from its ability to inhibit wild-type IXa in the tenase assay and from the changes in dansyl fluorescence emission signal upon its binding to the A2 subunit. Apparent K(d(A2)) values are: dEGR-IXa(WT) or dEGR-IXa(PCEGF1) approximately 100 nm, dEGR-IXa(R333Q) approximately 1.8 micrometer, and dEGR-IXa(helixVII) >10 micrometer. In additional experiments, we measured the affinities of these factor IXa molecules for a peptide comprising residues 558-565 of the A2 subunit. Apparent K(d(peptide)) values are: dEGR-IXa(WT) or dEGR-IXa(PCEGF1) approximately 4 micrometer, and dEGR-IXa(R333Q) approximately 62 micrometer. Thus as compared with the wild-type or PCEGF1 mutant, the affinity of the R333Q mutant for the A2 subunit or the A2 558-565 peptide is similarly reduced. These data support a conclusion that the helix 330 of factor IXa interacts with the A2 558-565 sequence. This information was used to model the interface between the IXa protease domain and the A2 subunit, which is also provided herein.

Thermodynamic linkage between the S1 site, the Na+ site, and the Ca2+ site in the protease domain of human coagulation factor xa. Studies on catalytic efficiency and inhibitor binding.

The serine protease domain of factor Xa (FXa) contains a sodium as well as a calcium-binding site. Here, we investigated the functional significance of these two cation-binding sites and their thermodynamic links to the S1 site. Kinetic data reveal that Na(+) binds to the substrate bound FXa with K(d) approximately 39 mm in the absence and approximately 9.5 mm in the presence of Ca(2+). Sodium-bound FXa (sodium-Xa) has approximately 18-fold increased catalytic efficiency ( approximately 4.5-fold decrease in K(m) and approximately 4-fold increase in k(cat)) in hydrolyzing S-2222 (benzoyl-Ile-Glu-Gly-Arg-p-nitroanilide), and Ca(2+) further increases this k(cat) approximately 1.4-fold. Ca(2+) binds to the protease domain of substrate bound FXa with K(d) approximately 705 microm in the absence and approximately 175 microm in the presence of Na(+). Ca(2+) binding to the protease domain of FXa (Xa-calcium) has no effect on the K(m) but increases the k(cat) approximately 4-fold in hydrolyzing S-2222, and Na(+) further increases this k(cat) approximately 1.4-fold. In agreement with the K(m) data, sodium-Xa has approximately 5-fold increased affinity in its interaction with p-aminobenzamidine (S1 site probe) and approximately 4-fold increased rate in binding to the two-domain tissue factor pathway inhibitor; Ca(2+) (+/-Na(+)) has no effect on these interactions. Antithrombin binds to Xa-calcium with a approximately 4-fold faster rate, to sodium-Xa with a approximately 24-fold faster rate and to sodium-Xa-calcium with a approximately 28-fold faster rate. Thus, Ca(2+) and Na(+) together increase the catalytic efficiency of FXa approximately 28-fold. Na(+) enhances Ca(2+) binding, and Ca(2+) enhances Na(+) binding. Further, Na(+) enhances S1 site occupancy, and S1 site occupancy enhances Na(+) binding. Therefore, Na(+) site is thermodynamically linked to the S1 site as well as to the protease domain Ca(2+) site, whereas Ca(2+) site is only linked to the Na(+) site. The significance of these findings is that during physiologic coagulation, most of the FXa formed will exist as sodium-Xa-calcium, which has maximum biologic activity.

Abdominoperineal electrical injury involving urogenital organs.

Although the incidence of electrical burns is not very high this incidence is rising in India. The residual effects of electrical burns are sometimes very severe and long lasting, if not managed properly. This case report is of a patient who sustained severe electrical burns over his left arm, lower abdomen and perineal area. The injuries were so severe that life-saving disarticulation of the limb together with excision of the involved pubic bone and genitalia and suprapubic urinary diversion was done. During follow up an unusual finding was noticed. There was a peritubal leak with no drainage from the catheter and on removal of the catheter, a manual examination of the urinary bladder revealed a stone which was removed at the same time. Following removal of the stone two ureteric openings with the trigone were seen and it was concluded that the granulating tissue was actually the posterior wall of the bladder. This was then mobilized and reposited into the abdomen. The deficient lower abdomen was reconstructed with a tensor fascia lata flap. A penile reconstruction for the patient is under consideration.

Large transverse fasciocutaneous leg flap: whole leg flap.

Large defects of leg and sole often need massive tissue transfer. As an alternative to microvascular transfer, we have developed a fasciocutaneous flap in which almost the whole of the skin of the opposite leg is transferred based just on the septocutaneous perforators of the posterior tibial artery. The flap has been used as a cross-leg fasciocutaneous flap with potential for use as a free flap by taking a segment of the posterior tibial artery. Our experience with 11 cases is presented. Two patients suffered marginal necrosis while donor site problems were seen in another two patients. We have found this flap to be safe, technically easy and with minimal donor-site morbidity.