Browsing by Author "K. Agarwal"

Now showing 1 - 4 of 4

Adolescent school child
(1976) A.M. Tripathi; K. Agarwal; S. Sen
[No abstract available]
Autoclaved partially decalcified bone as osteogenic substances--an experimental study.
(1991) S.K. Saraf; K. Agarwal; S.M. Tuli; S. Khanna
A large osteoperiosteal gap was created in rabbit's ulna. A total of 18 allogenic decalbone grafts in left ulnar gap and 20 autoclaved allogenic decalbone grafts on right ulnar gaps were implanted. Five gaps were left unbridged to serve as controls. The results were assessed by clinical, radiological, macroscopic, histological and tetracycline fluorescent studies. It is observed that whereas the decalbone can successfully bridge a large gap in a vast majority of cases; the standard autoclaving of decalbone denatures its proteins which melt and cover the outer surface. The union, incorporation and remodelling of autoclaved decalbone grafts are slower as compared to that with unautoclaved decalbone.
Challenges in QCD matter physics --The scientific programme of the Compressed Baryonic Matter experiment at FAIR
(Springer New York LLC, 2017) T. Ablyazimov; A. Abuhoza; R.P. Adak; M. Adamczyk; K. Agarwal; M.M. Aggarwal; Z. Ahammed; F. Ahmad; N. Ahmad; S. Ahmad; A. Akindinov; P. Akishin; E. Akishina; T. Akishina; V. Akishina; A. Akram; M. Al-Turany; I. Alekseev; E. Alexandrov; I. Alexandrov; S. Amar-Youcef; M. Anđelić; O. Andreeva; C. Andrei; A. Andronic; Yu. Anisimov; H. Appelshäuser; D. Argintaru; E. Atkin; S. Avdeev; R. Averbeck; M.D. Azmi; V. Baban; M. Bach; E. Badura; S. Bähr; T. Balog; M. Balzer; E. Bao; N. Baranova; T. Barczyk; D. Bartoş; S. Bashir; M. Baszczyk; O. Batenkov; V. Baublis; M. Baznat; J. Becker; K.-H. Becker; S. Belogurov; D. Belyakov; J. Bendarouach; I. Berceanu; A. Bercuci; A. Berdnikov; Y. Berdnikov; R. Berendes; G. Berezin; C. Bergmann; D. Bertini; O. Bertini; C. Beşliu; O. Bezshyyko; P.P. Bhaduri; A. Bhasin; A.K. Bhati; B. Bhattacharjee; A. Bhattacharyya; T.K. Bhattacharyya; S. Biswas; T. Blank; D. Blau; V. Blinov; C. Blume; Yu. Bocharov; J. Book; T. Breitner; U. Brüning; J. Brzychczyk; A. Bubak; H. Büsching; T. Bus; V. Butuzov; A. Bychkov; A. Byszuk; Xu Cai; M. Cãlin; Ping Cao; G. Caragheorgheopol; I. Carević; V. Cătănescu; A. Chakrabarti; S. Chattopadhyay; A. Chaus; Hongfang Chen; LuYao Chen; Jianping Cheng; V. Chepurnov; H. Cherif; A. Chernogorov; M.I. Ciobanu; G. Claus; F. Constantin; M. Csanád; N. D’Ascenzo; Supriya Das; Susovan Das; J. de Cuveland; B. Debnath; D. Dementiev; Wendi Deng; Zhi Deng; H. Deppe; I. Deppner; O. Derenovskaya; C.A. Deveaux; M. Deveaux; K. Dey; M. Dey; P. Dillenseger; V. Dobyrn; D. Doering; Sheng Dong; A. Dorokhov; M. Dreschmann; A. Drozd; A.K. Dubey; S. Dubnichka; Z. Dubnichkova; M. Dürr; L. Dutka; M. Dželalija; V.V. Elsha; D. Emschermann; H. Engel; V. Eremin; T. Eşanu; J. Eschke; D. Eschweiler; Huanhuan Fan; Xingming Fan; M. Farooq; O. Fateev; Shengqin Feng; S.P.D. Figuli; I. Filozova; D. Finogeev; P. Fischer; H. Flemming; J. Förtsch; U. Frankenfeld; V. Friese; E. Friske; I. Fröhlich; J. Frühauf; J. Gajda; T. Galatyuk; G. Gangopadhyay; C. García Chávez; J. Gebelein; P. Ghosh; S.K. Ghosh; S. Gläßel; M. Goffe; L. Golinka-Bezshyyko; V. Golovatyuk; S. Golovnya; V. Golovtsov; M. Golubeva; D. Golubkov; A. Gómez Ramírez; S. Gorbunov; S. Gorokhov; D. Gottschalk; P. Gryboś; A. Grzeszczuk; F. Guber; K. Gudima; M. Gumiński; A. Gupta; Yu. Gusakov; Dong Han; H. Hartmann; Shue He; J. Hehner; N. Heine; A. Herghelegiu; N. Herrmann; B. Heß; J.M. Heuser; A. Himmi; C. Höhne; R. Holzmann; Dongdong Hu; Guangming Huang; Xinjie Huang; D. Hutter; A. Ierusalimov; E.-M. Ilgenfritz; M. Irfan; D. Ivanischev; M. Ivanov; P. Ivanov; Valery Ivanov; Victor Ivanov; Vladimir Ivanov; A. Ivashkin; K. Jaaskelainen; H. Jahan; V. Jain; V. Jakovlev; T. Janson; Di Jiang; A. Jipa; I. Kadenko; P. Kähler; B. Kämpfer; V. Kalinin; J. Kallunkathariyil; K.-H. Kampert; E. Kaptur; R. Karabowicz; O. Karavichev; T. Karavicheva; D. Karmanov; V. Karnaukhov; E. Karpechev; K. Kasiński; G. Kasprowicz; M. Kaur; A. Kazantsev; U. Kebschull; G. Kekelidze; M.M. Khan; S.A. Khan; A. Khanzadeev; F. Khasanov; A. Khvorostukhin; V. Kirakosyan; M. Kirejczyk; A. Kiryakov; M. Kiš; I. Kisel; P. Kisel; S. Kiselev; T. Kiss; P. Klaus; R. Kłeczek; Ch. Klein-Bösing; V. Kleipa; V. Klochkov; P. Kmon; K. Koch; L. Kochenda; P. Koczoń; W. Koenig; M. Kohn; B.W. Kolb; A. Kolosova; B. Komkov; M. Korolev; I. Korolko; R. Kotte; A. Kovalchuk; S. Kowalski; M. Koziel; G. Kozlov; V. Kozlov; V. Kramarenko; P. Kravtsov; E. Krebs; C. Kreidl; I. Kres; D. Kresan; G. Kretschmar; M. Krieger; A.V. Kryanev; E. Kryshen; M. Kuc; W. Kucewicz; V. Kucher; L. Kudin; A. Kugler; Ajit Kumar; Ashwini Kumar; L. Kumar; J. Kunkel; A. Kurepin; N. Kurepin; A. Kurilkin; P. Kurilkin; V. Kushpil; S. Kuznetsov; V. Kyva; V. Ladygin; C. Lara; P. Larionov; A. Laso García; E. Lavrik; I. Lazanu; A. Lebedev; S. Lebedev; E. Lebedeva; J. Lehnert; J. Lehrbach; Y. Leifels; F. Lemke; Cheng Li; Qiyan Li; Xin Li; Yuanjing Li; V. Lindenstruth; B. Linnik; Feng Liu; I. Lobanov; E. Lobanova; S. Löchner; P.-A. Loizeau; S.A. Lone; J.A. Lucio Martínez; Xiaofeng Luo; A. Lymanets; Pengfei Lyu; A. Maevskaya; S. Mahajan; D.P. Mahapatra; T. Mahmoud; P. Maj; Z. Majka; A. Malakhov; E. Malankin; D. Malkevich; O. Malyatina; H. Malygina; M.M. Mandal; S. Mandal; V. Manko; S. Manz; A.M. Marin Garcia; J. Markert; S. Masciocchi; T. Matulewicz; L. Meder; M. Merkin; V. Mialkovski; J. Michel; N. Miftakhov; L. Mik; K. Mikhailov; V. Mikhaylov; B. Milanović; V. Militsija; D. Miskowiec; I. Momot; T. Morhardt; S. Morozov; W.F.J. Müller; C. Müntz; S. Mukherjee; C.E. Muñoz Castillo; Yu. Murin; R. Najman; C. Nandi; E. Nandy; L. Naumann; T. Nayak; A. Nedosekin; V.S. Negi; W. Niebur; V. Nikulin; D. Normanov; A. Oancea; Kunsu Oh; Yu. Onishchuk; G. Ososkov; P. Otfinowski; E. Ovcharenko; S. Pal; I. Panasenko; N.R. Panda; S. Parzhitskiy; V. Patel; C. Pauly; M. Penschuck; D. Peshekhonov; V. Peshekhonov; V. Petráček; M. Petri; M. Petriş; A. Petrovici; M. Petrovici; A. Petrovskiy; O. Petukhov; D. Pfeifer; K. Piasecki; J. Pieper; J. Pietraszko; R. Płaneta; V. Plotnikov; V. Plujko; J. Pluta; A. Pop; V. Pospisil; K. Poźniak; A. Prakash; S.K. Prasad; M. Prokudin; I. Pshenichnov; M. Pugach; V. Pugatch; S. Querchfeld; S. Rabtsun; L. Radulescu; S. Raha; F. Rami; R. Raniwala; S. Raniwala; A. Raportirenko; J. Rautenberg; J. Rauza; R. Ray; S. Razin; P. Reichelt; S. Reinecke; A. Reinefeld; A. Reshetin; C. Ristea; O. Ristea; A. Rodriguez Rodriguez; F. Roether; R. Romaniuk; A. Rost; E. Rostchin; I. Rostovtseva; Amitava Roy; Ankhi Roy; J. Rożynek; Yu. Ryabov; A. Sadovsky; R. Sahoo; P.K. Sahu; S.K. Sahu; J. Saini; S. Samanta; S.S. Sambyal; V. Samsonov; J. Sánchez Rosado; O. Sander; S. Sarangi; T. Satława; S. Sau; V. Saveliev; S. Schatral; C. Schiaua; F. Schintke; C.J. Schmidt; H.R. Schmidt; K. Schmidt; J. Scholten; K. Schweda; F. Seck; S. Seddiki; I. Selyuzhenkov; A. Semennikov; A. Senger; P. Senger; A. Shabanov; A. Shabunov; Ming Shao; A.D. Sheremetiev; Shusu Shi; N. Shumeiko; V. Shumikhin; I. Sibiryak; B. Sikora; A. Simakov; C. Simon; C. Simons; R.N. Singaraju; A.K. Singh; B.K. Singh; C.P. Singh; V. Singhal; M. Singla; P. Sitzmann; K. Siwek-Wilczyńska; L. Škoda; I. Skwira-Chalot; I. Som; Guofeng Song; Jihye Song; Z. Sosin; D. Soyk; P. Staszel; M. Strikhanov; S. Strohauer; J. Stroth; C. Sturm; R. Sultanov; Yongjie Sun; D. Svirida; O. Svoboda; A. Szabó; R. Szczygieł; R. Talukdar; Zebo Tang; M. Tanha; J. Tarasiuk; O. Tarassenkova; M.-G. Târzilă; M. Teklishyn; T. Tischler; P. Tlustý; T. Tölyhi; A. Toia; N. Topil’skaya; M. Träger; S. Tripathy; I. Tsakov; Yu. Tsyupa; A. Turowiecki; N.G. Tuturas; F. Uhlig; E. Usenko; I. Valin; D. Varga; I. Vassiliev; O. Vasylyev; E. Verbitskaya; W. Verhoeven; A. Veshikov; R. Visinka; Y.P. Viyogi; S. Volkov; A. Volochniuk; A. Vorobiev; Aleksey Voronin; Alexander Voronin; V. Vovchenko; M. Vznuzdaev; Dong Wang; Xi-Wei Wang; Yaping Wang; Yi Wang; M. Weber; C. Wendisch; J.P. Wessels; M. Wiebusch; J. Wiechula; D. Wielanek; A. Wieloch; A. Wilms; N. Winckler; M. Winter; K. Wiśniewski; Gy. Wolf; Sanguk Won; Ke-Jun Wu; J. Wüstenfeld; Changzhou Xiang; Nu Xu; Junfeng Yang; Rongxing Yang; Zhongbao Yin; In-Kwon Yoo; B. Yuldashev; I. Yushmanov; W. Zabołotny; Yu. Zaitsev; N.I. Zamiatin; Yu. Zanevsky; M. Zhalov; Yifei Zhang; Yu Zhang; Lei Zhao; Jiajun Zheng; Sheng Zheng; Daicui Zhou; Jing Zhou; Xianglei Zhu; A. Zinchenko; W. Zipper; M. Żoładź; P. Zrelov; V. Zryuev; P. Zumbruch; M. Zyzak
Substantial experimental and theoretical efforts worldwide are devoted to explore the phase diagram of strongly interacting matter. At LHC and top RHIC energies, QCD matter is studied at very high temperatures and nearly vanishing net-baryon densities. There is evidence that a Quark-Gluon-Plasma (QGP) was created at experiments at RHIC and LHC. The transition from the QGP back to the hadron gas is found to be a smooth cross over. For larger net-baryon densities and lower temperatures, it is expected that the QCD phase diagram exhibits a rich structure, such as a first-order phase transition between hadronic and partonic matter which terminates in a critical point, or exotic phases like quarkyonic matter. The discovery of these landmarks would be a breakthrough in our understanding of the strong interaction and is therefore in the focus of various high-energy heavy-ion research programs. The Compressed Baryonic Matter (CBM) experiment at FAIR will play a unique role in the exploration of the QCD phase diagram in the region of high net-baryon densities, because it is designed to run at unprecedented interaction rates. High-rate operation is the key prerequisite for high-precision measurements of multi-differential observables and of rare diagnostic probes which are sensitive to the dense phase of the nuclear fireball. The goal of the CBM experiment at SIS100 (sNN= 2.7--4.9 GeV) is to discover fundamental properties of QCD matter: the phase structure at large baryon-chemical potentials (μB> 500 MeV), effects of chiral symmetry, and the equation of state at high density as it is expected to occur in the core of neutron stars. In this article, we review the motivation for and the physics programme of CBM, including activities before the start of data taking in 2024, in the context of the worldwide efforts to explore high-density QCD matter. © 2017, SIF, Springer-Verlag Berlin Heidelberg.
Evaluation of the effect of mode and duration of labor on maternofetal transfer of IgG at term in Indian mothers
(1984) R.M. Gupta; D. Sharma; K. Agarwal; M. Kumar
Paired maternal and cord serum IgG, IgA, and IgM were estimated in 100 full term normal birth weight neonates and their mothers delivered either per vaginum, by elective Caesarian section or by emergency Caesarian section. Neonates delivered per vaginum revealed significantly higher cord serum IgG levels (1168 ± 153 mg%, p<0.001) as compared to those delivered by emergency Caesarian section (956.25 ± 192.20) or elective Caesarian section (971.00 ± 245.12 mg%). Each group was further analyzed according to the duration of labor into those delivering in 10 hours or less, 11-20 hours, 21-30 hours, and more than 30 hours. The data revealed that labor of more than 20 hours significantly contributed to the materno-fetal transfer of IgG resulting in a lessening of the difference in cord serum IgG of neonates delivered per vaginum and by emergency Caesarian section. In the emergency Caesarian section group, patients delivering after 30 hours of labor had significantly higher levels of IgG (1050.00 ± 108.00 mg%) than the group delivering within 10 hours (880.77 ± 146.54 mg%). It appears that primarily the maternofetal transfer of IgG is modulated by the route of delivery but later uterine contractions may also contribute to it significantly.