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Items: 1 to 20 of 101

1.

Vacuum chamber-free centrifuge with magnetic bearings.

Park CH, Kim S, Kim KS.

Rev Sci Instrum. 2013 Sep;84(9):095106. doi: 10.1063/1.4820242.

PMID:
24089865
3.

A HIGH SPEED VACUUM CENTRIFUGE SUITABLE FOR THE STUDY OF FILTERABLE VIRUSES.

Bauer JH, Pickels EG.

J Exp Med. 1936 Sep 30;64(4):503-28.

4.

[A new vacuum extraction system with a ball joint and detachment warning--in vitro studies and clinical use].

Korell M, King S, Hepp H.

Z Geburtshilfe Neonatol. 2000 May-Jun;204(3):93-8. German.

PMID:
10909164
5.

A methodology for centrifuge selection for the separation of high solids density cell broths by visualisation of performance using windows of operation.

Salte H, King JM, Baganz F, Hoare M, Titchener-Hooker NJ.

Biotechnol Bioeng. 2006 Dec 20;95(6):1218-27.

PMID:
16865731
6.

AN IMPROVED AIR-DRIVEN TYPE OF ULTRACENTRIFUGE FOR MOLECULAR SEDIMENTATION.

Bauer JH, Pickels EG.

J Exp Med. 1937 Mar 31;65(4):565-86.

7.

Permanent magnetic-levitation of rotating impeller: a decisive breakthrough in the centrifugal pump.

Qian KX, Zeng P, Ru WM, Yuan HY, Feng ZG, Li L.

J Med Eng Technol. 2002 Jan-Feb;26(1):36-8.

PMID:
11924845
8.

Venturi vacuum systems for hypobaric chamber operations.

Robinson R, Swaby G, Sutton T, Fife C, Powell M, Butler BD.

Aviat Space Environ Med. 1997 Nov;68(11):1046-9.

PMID:
9383507
9.
10.

Observations on centrifugation: application to centrifuge development.

Roberts T, Smith M, Roberts B.

Clin Chem. 1999 Nov;45(11):1889-97.

11.

Quantitative approach to control spinning stability of the impeller in the pivot bearing-supported centrifugal pump.

Takami Y, Makinouchi K, Otsuka G, Nosé Y.

Artif Organs. 1997 Dec;21(12):1292-6.

PMID:
9423982
12.

Development of a multipurpose vacuum chamber for serial optical and diffraction experiments with free electron laser radiation.

Rajkovic I, Hallmann J, Grübel S, More R, Quevedo W, Petri M, Techert S.

Rev Sci Instrum. 2010 Apr;81(4):045105. doi: 10.1063/1.3327816.

PMID:
20441366
13.

The effect of the impeller-driver magnetic coupling distance on hemolysis in a compact centrifugal pump.

Nakazawa T, Makinouchi K, Takami Y, Glueck J, Takatani S, Nosé Y.

Artif Organs. 1996 Mar;20(3):252-7.

PMID:
8694696
14.

Wear of surface-engineered metal-on-metal bearings for hip prostheses under adverse conditions with the head loading on the rim of the cup.

Leslie I, Williams S, Isaac G, Hatto P, Ingham E, Fisher J.

Proc Inst Mech Eng H. 2013 Apr;227(4):345-9. doi: 10.1177/0954411912468542. Epub 2012 Dec 6.

PMID:
23637209
15.

Large-scale perfusion culture process for suspended mammalian cells that uses a centrifuge with multiple settling zones.

Takamatsu H, Hamamoto K, Ishimaru K, Yokoyama S, Tokashiki M.

Appl Microbiol Biotechnol. 1996 May;45(4):454-7.

PMID:
8737569
16.

Design analysis and performance assessment of hybrid magnetic bearings for a rotary centrifugal blood pump.

Ren Z, Jahanmir S, Heshmat H, Hunsberger AZ, Walton JF.

ASAIO J. 2009 Jul-Aug;55(4):340-7. doi: 10.1097/MAT.0b013e3181a094c8.

PMID:
19381082
17.
18.

Prototype continuous flow ventricular assist device supported on magnetic bearings.

Allaire PE, Kim HC, Maslen EH, Olsen DB, Bearnson GB.

Artif Organs. 1996 Jun;20(6):582-90.

PMID:
8817961
19.

Comparative wear under different conditions of surface-engineered metal-on-metal bearings for total hip arthroplasty.

Williams S, Isaac G, Hatto P, Stone MH, Ingham E, Fisher J.

J Arthroplasty. 2004 Dec;19(8 Suppl 3):112-7.

PMID:
15578564
20.

Optimization of a vacuum chamber for vibration measurements.

Danyluk M, Dhingra A.

Rev Sci Instrum. 2011 Oct;82(10):105113. doi: 10.1063/1.3652973.

PMID:
22047335
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