carbon monoxide and Hemolysis studies

Carbon Monoxide: Carbon monoxide (CO). A poisonous colorless, odorless, tasteless gas. It combines with hemoglobin to form carboxyhemoglobin, which has no oxygen carrying capacity. The resultant oxygen deprivation causes headache, dizziness, decreased pulse and respiratory rates, unconsciousness, and death. (From Merck Index, 11th ed)
carbon monoxide : A one-carbon compound in which the carbon is joined only to a single oxygen. It is a colourless, odourless, tasteless, toxic gas.

Hemolysis: The destruction of ERYTHROCYTES by many different causal agents such as antibodies, bacteria, chemicals, temperature, and changes in tonicity.

Research Excerpts

Excerpt	Relevance	Reference
"Carbon monoxide (CO)-based tests have precisely measured hemolysis for over 40 years."	9.41	Carbon monoxide as a clinical marker of hemolysis. ( Osborne, J; Sobh, M; Trudel, G, 2023)
" The main aims were to inspect the erythrocyte (RBC) survival in GS by using Levitt's carbon monoxide (CO) breath test and to assess its contribution to unconjugated hyperbilirubinemia."	9.34	Carbon monoxide breath test assessment of mild hemolysis in Gilbert's syndrome. ( Kang, LL; Ma, YJ; Zhang, HD, 2020)
"The predominant cause of elevated total/plasma bilirubin (TB) levels is from an increase in bilirubin production primarily because of ongoing hemolysis."	9.12	Neonatal hyperbilirubinemia management: Clinical assessment of bilirubin production. ( Bao, Y; Bhutani, VK; Chen, L; Du, L; Ma, X; Shen, X, 2021)
" Because the catabolism of heme produces equimolar amounts of carbon monoxide (CO) and bilirubin, measurements of end-tidal breath CO (corrected for ambient CO) or ETCOc can serve as an index of hemolysis as well as of bilirubin production from any cause."	8.90	End-tidal carbon monoxide and hemolysis. ( Stevenson, DK; Tidmarsh, GF; Wong, RJ, 2014)
"Carbon monoxide (CO) production from heme catabolism is increased with hemolysis."	7.81	Point-of-care end-tidal carbon monoxide reflects severity of hemolysis in sickle cell anemia. ( Goldrich, A; Lal, A; Marsh, A; Patterson, L, 2015)
" Routine management included measurement of the end tidal carbon monoxide level corrected for ambient carbon monoxide level (ETCOc) within 4 hours after delivery (assessment of hemolysis), > or =1 predischarge bilirubin determination, and additional bilirubin testing as clinically indicated."	7.72	Hyperbilirubinemia among African American, glucose-6-phosphate dehydrogenase-deficient neonates. ( Hammerman, C; Herschel, M; Hoyer, JD; Kaplan, M; Stevenson, DK, 2004)
"Hyperbilirubinemia is a condition of major importance and a source of concern to all involved in the management of the newborn."	6.43	Understanding severe hyperbilirubinemia and preventing kernicterus: adjuncts in the interpretation of neonatal serum bilirubin. ( Hammerman, C; Kaplan, M, 2005)
"When hemolysis is identified, parents are likely to comply with instructions to bring the infant for a TB checkup <24 h after discharge home."	5.43	Measuring End-Tidal Carbon Monoxide of Jaundiced Neonates in the Birth Hospital to Identify Those with Hemolysis. ( Baer, VL; Christensen, RD; Denson, LE; Gerday, E; Lambert, DK; Malleske, DT; Prchal, JT; Shepherd, JG; Weaver Lewis, KA, 2016)
" Before the recent development of practical and inexpensive testing for hemolysis by quantifying carbon monoxide in end-tidal breath, some hemolytic disorders in perinatal patients were not detected until severely problematic hyperbilirubinemia and/or anemia occurred."	5.41	Perinatal Hemolytic Disorders and Identification Using End Tidal Breath Carbon Monoxide. ( Bahr, TM; Christensen, RD; Pakdeeto, S; Supapannachart, S; Zhang, H, 2023)
"Carbon monoxide (CO)-based tests have precisely measured hemolysis for over 40 years."	5.41	Carbon monoxide as a clinical marker of hemolysis. ( Osborne, J; Sobh, M; Trudel, G, 2023)
"Carbon monoxide (CO) has anti-inflammatory properties."	5.35	Inhaled carbon monoxide reduces leukocytosis in a murine model of sickle cell disease. ( Beckman, JD; Belcher, JD; Chen, C; Gulbahce, E; Hebbel, RP; Nguyen, J; Nwaneri, MO; O'Sullivan, MG; Vercellotti, GM; Vineyard, JV, 2009)
" The main aims were to inspect the erythrocyte (RBC) survival in GS by using Levitt's carbon monoxide (CO) breath test and to assess its contribution to unconjugated hyperbilirubinemia."	5.34	Carbon monoxide breath test assessment of mild hemolysis in Gilbert's syndrome. ( Kang, LL; Ma, YJ; Zhang, HD, 2020)
"The predominant cause of elevated total/plasma bilirubin (TB) levels is from an increase in bilirubin production primarily because of ongoing hemolysis."	5.12	Neonatal hyperbilirubinemia management: Clinical assessment of bilirubin production. ( Bao, Y; Bhutani, VK; Chen, L; Du, L; Ma, X; Shen, X, 2021)
" Because the catabolism of heme produces equimolar amounts of carbon monoxide (CO) and bilirubin, measurements of end-tidal breath CO (corrected for ambient CO) or ETCOc can serve as an index of hemolysis as well as of bilirubin production from any cause."	4.90	End-tidal carbon monoxide and hemolysis. ( Stevenson, DK; Tidmarsh, GF; Wong, RJ, 2014)
"To establish a reference nomogram for end-tidal CO corrected for ambient CO (ETCOc) levels in term and late-preterm Chinese newborns and then assess its efficacy to identify hemolytic hyperbilirubinemia."	4.12	An End-Tidal Carbon Monoxide Nomogram for Term and Late-Preterm Chinese Newborns. ( Bao, Y; Du, L; He, Y; Ma, L; Sun, L; Wu, J; Xu, C; Zhang, H; Zhu, J, 2022)
"Carboxyhemoglobin (COHb) is an index of endogenous carbon monoxide formation during the hem degradation process and could be used to confirm hemolysis in neonates."	4.12	Clinical Factors Influencing Endogenous Carbon Monoxide Production and Carboxyhemoglobin Levels in Neonates. ( Lozar Krivec, J; Lozar Manfreda, K; Paro-Panjan, D, 2022)
"Increased bilirubin production due to hemolysis can lead to severe neonatal hyperbilirubinemia and, if left untreated, to bilirubin neurotoxicity."	3.91	Bilirubin Production Is Increased in Newborn Mice Exposed to Isoflurane. ( Burgess, J; Iwatani, S; Kalish, F; Stevenson, DK; Wong, RJ, 2019)
"Carbon monoxide (CO) production from heme catabolism is increased with hemolysis."	3.81	Point-of-care end-tidal carbon monoxide reflects severity of hemolysis in sickle cell anemia. ( Goldrich, A; Lal, A; Marsh, A; Patterson, L, 2015)
" Routine management included measurement of the end tidal carbon monoxide level corrected for ambient carbon monoxide level (ETCOc) within 4 hours after delivery (assessment of hemolysis), > or =1 predischarge bilirubin determination, and additional bilirubin testing as clinically indicated."	3.72	Hyperbilirubinemia among African American, glucose-6-phosphate dehydrogenase-deficient neonates. ( Hammerman, C; Herschel, M; Hoyer, JD; Kaplan, M; Stevenson, DK, 2004)
" alkaline methanolysis, bilirubin, bilirubin conjugation, carbon monoxide, carboxyhemoglobin, gas chromatography, hemolysis, high performance liquid chromatography, physiologic jaundice."	3.71	Imbalance between production and conjugation of bilirubin: a fundamental concept in the mechanism of neonatal jaundice. ( Hammerman, C; Kaplan, M; Muraca, M; Rubaltelli, FF; Stevenson, DK; Vilei, MT; Vreman, HJ, 2002)
" In this study the effect of sulfur, sulfur compounds, thiol-containing compounds, and thiol inhibitors on AsH(3)-induced disruption of membrane transport and hemolysis in human erythrocytes was investigated in vitro."	3.70	The effects of sulfur, thiol, and thiol inhibitor compounds on arsine-induced toxicity in the human erythrocyte membrane. ( Ayala-Fierro, F; Carter, DE; Rael, LT, 2000)
"The role of increased heme catabolism in neonatal hyperbilirubinemia was investigated in rhesus (Macaca mulatta) neonates through the measurement of carbon monoxide excretion rates (VECO), blood carboxyhemoglobin content (HbCO), and plasma bilirubin concentrations."	3.67	Carbon monoxide excretion as an index of bilirubin production in rhesus monkeys. ( Gale, R; Rodgers, PA; Stevenson, DK; Vreman, HJ, 1989)
" Erythrocyte hemolysis and lifespan were evaluated in the five groups of rats by quantitation of radioactive carbon monoxide exhaled in the breath which arises from the breakdown of the previously labeled hemoglobin."	3.66	Effect of weightlessness and centrifugation on red cell survival in rats subjected to space flight. ( Landaw, SA; Leon, HA; Serova, LV, 1980)
"Hyperbilirubinemia risk was assessed by plotting TB values as a function of ETCOc."	2.82	Identification of neonatal haemolysis: an approach to predischarge management of neonatal hyperbilirubinemia. ( Aby, JL; Bhutani, VK; Castillo Cuadrado, ME; Srinivas, S; Stevenson, DK; Wong, RJ, 2016)
"Hyperbilirubinemia is a condition of major importance and a source of concern to all involved in the management of the newborn."	2.43	Understanding severe hyperbilirubinemia and preventing kernicterus: adjuncts in the interpretation of neonatal serum bilirubin. ( Hammerman, C; Kaplan, M, 2005)
"When hemolysis is identified, parents are likely to comply with instructions to bring the infant for a TB checkup <24 h after discharge home."	1.43	Measuring End-Tidal Carbon Monoxide of Jaundiced Neonates in the Birth Hospital to Identify Those with Hemolysis. ( Baer, VL; Christensen, RD; Denson, LE; Gerday, E; Lambert, DK; Malleske, DT; Prchal, JT; Shepherd, JG; Weaver Lewis, KA, 2016)
"Carbon monoxide (CO) has anti-inflammatory properties."	1.35	Inhaled carbon monoxide reduces leukocytosis in a murine model of sickle cell disease. ( Beckman, JD; Belcher, JD; Chen, C; Gulbahce, E; Hebbel, RP; Nguyen, J; Nwaneri, MO; O'Sullivan, MG; Vercellotti, GM; Vineyard, JV, 2009)
"Neonatal jaundice is the result of an imbalance between bilirubin production and elimination, and our objective was to clarify the contribution of an increase in bilirubin production to hyperbilirubinemia in newborns."	1.33	The contribution of hemolysis to early jaundice in normal newborns. ( Kring, E; Maisels, MJ, 2006)

Timeframe	Studies, this research(%)	All Research%
pre-1990	60 (56.07)	18.7374
1990's	7 (6.54)	18.2507
2000's	12 (11.21)	29.6817
2010's	16 (14.95)	24.3611
2020's	12 (11.21)	2.80

Trial	Phase	Enrollment	Study Type	Start Date	Status
Clinical Value of ETCOc in the Diagnosis and Treatment of ABO Hemolytic Disease of the Newborn[NCT05842109]		112 participants (Anticipated)	Observational	2023-05-01	Not yet recruiting
End-Alveolar Carbon Monoxide as a Measure of Erythrocyte Survival and Hemolytic Severity in Sickle Cell Disease[NCT01547793]		106 participants (Actual)	Observational	2012-01-26	Completed
Determining the Prevalence and Prognosis of Secondary Pulmonary Hypertension in Adult Patients With Sickle Cell Anemia[NCT00011648]		986 participants (Actual)	Observational	2008-02-19	Completed
Study on the Intelligent Follow-up Management Model of Neonatal Jaundice After Discharge Based on Early Multi-dimensional Indicators and Internet Communications[NCT05365984]		2,500 participants (Anticipated)	Interventional	2022-05-31	Not yet recruiting
HEMolysis in a Percutaneous Axial Flow Left Ventricular Assist Device, Effects of Pentoxifylline in a Randomized Controlled Trial[NCT04391231]	Phase 4	50 participants (Anticipated)	Interventional	2021-09-15	Not yet recruiting
End Tidal Carbon Monoxide (ETCO) : A Tool to Aid Identification of Neonatal Hemolysis[NCT05475223]		350 participants (Anticipated)	Interventional	2022-07-29	Not yet recruiting
Point-of-Care End-Tidal Carbon Monoxide Measurement to Screen for Sickle Cell Disease[NCT02530242]		32 participants (Actual)	Interventional	2015-07-31	Completed
BilirubinProduction in Healthy Term Infants as Measured by Carbon Monoxide in Breath[NCT01203410]		535 participants (Actual)	Observational	1991-11-30	Completed
[information is prepared from clinicaltrials.gov, extracted Sep-2024]

Intervention	ppm (Median)
End-tidal Carbon Monoxide Subjects	4.35
End-tidal Carbon Monoxide Controls	.80

Article	Year
Perinatal Hemolytic Disorders and Identification Using End Tidal Breath Carbon Monoxide. Current pediatric reviews, 2023, Volume: 19, Issue:4 Topics: Carbon Monoxide; Cell Death; Female; Hemolysis; Humans; Hyperbilirubinemia; Infant, Newborn; Infant,	2023
Carbon monoxide as a clinical marker of hemolysis. American journal of hematology, 2023, Volume: 98, Issue:7 Topics: Biomarkers; Carbon Monoxide; Carboxyhemoglobin; Hemolysis; Humans; Smoking	2023
Neonatal hyperbilirubinemia management: Clinical assessment of bilirubin production. Seminars in perinatology, 2021, Volume: 45, Issue:1 Topics: Bilirubin; Carbon Monoxide; Hemolysis; Humans; Hyperbilirubinemia; Hyperbilirubinemia, Neonatal; Inf	2021
Increased carbon monoxide production by hemeoxygenase-1 caused by device-mediated hemolysis: thrombotic phantom menace? Artificial organs, 2013, Volume: 37, Issue:11 Topics: Animals; Blood Coagulation; Carbon Monoxide; Heart-Assist Devices; Heme Oxygenase-1; Hemolysis; Huma	2013
End-tidal carbon monoxide and hemolysis. Journal of perinatology : official journal of the California Perinatal Association, 2014, Volume: 34, Issue:8 Topics: Breath Tests; Carbon Monoxide; Hemolysis; Humans; Hyperbilirubinemia, Neonatal; Infant, Newborn; Tid	2014
End-tidal carbon monoxide and hemolysis. Journal of perinatology : official journal of the California Perinatal Association, 2014, Volume: 34, Issue:8 Topics: Breath Tests; Carbon Monoxide; Hemolysis; Humans; Hyperbilirubinemia, Neonatal; Infant, Newborn; Tid	2014
End-tidal carbon monoxide and hemolysis. Journal of perinatology : official journal of the California Perinatal Association, 2014, Volume: 34, Issue:8 Topics: Breath Tests; Carbon Monoxide; Hemolysis; Humans; Hyperbilirubinemia, Neonatal; Infant, Newborn; Tid	2014
End-tidal carbon monoxide and hemolysis. Journal of perinatology : official journal of the California Perinatal Association, 2014, Volume: 34, Issue:8 Topics: Breath Tests; Carbon Monoxide; Hemolysis; Humans; Hyperbilirubinemia, Neonatal; Infant, Newborn; Tid	2014
Neonatal hemolysis and risk of bilirubin-induced neurologic dysfunction. Seminars in fetal & neonatal medicine, 2015, Volume: 20, Issue:1 Topics: Carbon Monoxide; Genetic Predisposition to Disease; Glucosephosphate Dehydrogenase Deficiency; Hemol	2015
Understanding severe hyperbilirubinemia and preventing kernicterus: adjuncts in the interpretation of neonatal serum bilirubin. Clinica chimica acta; international journal of clinical chemistry, 2005, Volume: 356, Issue:1-2 Topics: Bilirubin; Blood Group Incompatibility; Carbon Monoxide; Hemolysis; Humans; Hyperbilirubinemia; Infa	2005
Hemolysis in sickle cell disease. Archives of internal medicine, 1974, Volume: 133, Issue:4 Topics: Adolescent; Adult; Anemia, Sickle Cell; Carbon Monoxide; Carbon Radioisotopes; Child; Chromium Radio	1974

Article	Year
Carbon monoxide breath test assessment of mild hemolysis in Gilbert's syndrome. Medicine, 2020, Volume: 99, Issue:7 Topics: Adult; Breath Tests; Carbon Monoxide; Erythrocytes; Female; Gilbert Disease; Hemolysis; Humans; Hype	2020
Lactate dehydrogenase to carboxyhemoglobin ratio as a biomarker of heme release to heme processing is associated with higher tricuspid regurgitant jet velocity and early death in sickle cell disease. American journal of hematology, 2021, 09-01, Volume: 96, Issue:9 Topics: Adult; Anemia, Sickle Cell; Biomarkers; Carbon Monoxide; Carboxyhemoglobin; Heme; Hemolysis; Humans;	2021
Lactate dehydrogenase to carboxyhemoglobin ratio as a biomarker of heme release to heme processing is associated with higher tricuspid regurgitant jet velocity and early death in sickle cell disease. American journal of hematology, 2021, 09-01, Volume: 96, Issue:9 Topics: Adult; Anemia, Sickle Cell; Biomarkers; Carbon Monoxide; Carboxyhemoglobin; Heme; Hemolysis; Humans;	2021
Lactate dehydrogenase to carboxyhemoglobin ratio as a biomarker of heme release to heme processing is associated with higher tricuspid regurgitant jet velocity and early death in sickle cell disease. American journal of hematology, 2021, 09-01, Volume: 96, Issue:9 Topics: Adult; Anemia, Sickle Cell; Biomarkers; Carbon Monoxide; Carboxyhemoglobin; Heme; Hemolysis; Humans;	2021
Lactate dehydrogenase to carboxyhemoglobin ratio as a biomarker of heme release to heme processing is associated with higher tricuspid regurgitant jet velocity and early death in sickle cell disease. American journal of hematology, 2021, 09-01, Volume: 96, Issue:9 Topics: Adult; Anemia, Sickle Cell; Biomarkers; Carbon Monoxide; Carboxyhemoglobin; Heme; Hemolysis; Humans;	2021
Identification of neonatal haemolysis: an approach to predischarge management of neonatal hyperbilirubinemia. Acta paediatrica (Oslo, Norway : 1992), 2016, Volume: 105, Issue:5 Topics: Algorithms; Bilirubin; Biomarkers; Carbon Monoxide; Clinical Decision-Making; Decision Support Techn	2016

carbon monoxide and Hemolysis

Research Excerpts

Research

Studies (107)

Authors

Clinical Trials (8)

Trial Overview

Trial Outcomes

End-Tidal Carbon Monoxide

Reviews

Trials

Other Studies

Authors	Studies
Pakdeeto, S	2
Christensen, TR	1
Bahr, TM	2
Gerday, E	2
Sheffield, MJ	1
Christensen, KS	1
Supapannachart, S	2
Nuntnarumit, P	1
Sukwiset, S	1
Ohls, RK	1
Christensen, RD	5
Bao, Y	2
Zhu, J	1
Ma, L	1
Zhang, H	2
Sun, L	1
Xu, C	1
Wu, J	1
He, Y	1
Du, L	2
Osborne, J	1
Sobh, M	1
Trudel, G	2
Stevenson, DK	13
Wong, RJ	6
Ostrander, CR	1
Maric, I	1
Vreman, HJ	7
Cohen, RS	1
Shahin, N	1
Louati, H	1
Kang, LL	1
Ma, YJ	1
Zhang, HD	1
Maisels, MJ	4
Kring, EA	2
Coffey, MP	1
Ma, X	1
Shen, X	1
Chen, L	1
Bhutani, VK	3
Lozar Krivec, J	1
Lozar Manfreda, K	1
Paro-Panjan, D	1
van Vuren, AJ	1
Minniti, CP	1
Mendelsohn, L	1
Baird, JH	1
Kato, GJ	1
van Beers, EJ	1
Ye, L	1
Ji, Y	1
Zhou, C	1
Luo, J	1
Zhang, L	1
Jing, L	1
Zhao, X	1
Guo, J	1
Gao, Q	1
Peng, G	1
Li, Y	2
Li, J	1
Fan, H	1
Yang, W	1
Yang, Y	1
Ma, Y	1
Zhang, F	1
Schutzman, DL	1
Castillo Cuadrado, ME	2
Aby, JL	2
Bogen, DL	1
Watchko, JF	1
Iwatani, S	1
Burgess, J	1
Kalish, F	1
Belcher, JD	2
Gomperts, E	1
Nguyen, J	2
Chen, C	2
Abdulla, F	1
Kiser, ZM	1
Gallo, D	1
Levy, H	1
Otterbein, LE	2
Vercellotti, GM	2
Oh, JY	1
Williams, A	1
Patel, RP	1
Nielsen, VG	1
Pearson, EC	1
Smith, MC	1
Tidmarsh, GF	1
Lambert, DK	2
Henry, E	1
Yaish, HM	1
Prchal, JT	2
Lal, A	1
Patterson, L	1
Goldrich, A	1
Marsh, A	1
Malleske, DT	1
Baer, VL	1
Denson, LE	1
Weaver Lewis, KA	1
Shepherd, JG	1
Srinivas, S	1
Beckman, JD	1
Vineyard, JV	1
Nwaneri, MO	1
O'Sullivan, MG	1
Gulbahce, E	1
Hebbel, RP	1
Borland, CD	1
Dunningham, H	1
Bottrill, F	1
Vuylsteke, A	1
Yilmaz, C	1
Dane, DM	1
Hsia, CC	1
Zavorsky, GS	1
Gough, CE	1
Eastwood, A	1
Saunders, PU	1
Anson, JM	1
Gore, CJ	1
Lang, E	1
Qadri, SM	1
Jilani, K	1
Zelenak, C	1
Lupescu, A	1
Schleicher, E	1
Lang, F	1
Seixas, JD	1
Mukhopadhyay, A	1
Santos-Silva, T	1
Gallo, DJ	1
Rodrigues, SS	1
Guerreiro, BH	1
Gonçalves, AM	1
Penacho, N	1
Marques, AR	1
Coelho, AC	1
Reis, PM	1
Romão, MJ	1
Romão, CC	1
Kaplan, M	4
Muraca, M	1
Hammerman, C	4
Rubaltelli, FF	1
Vilei, MT	1
LAGERCRANTZ, R	1
ENGSTEDT, L	1
IBRING, G	1
HALLBERG, L	1
Javier, MC	1
Krauss, A	1
Nesin, M	1
Herschel, M	1
Hoyer, JD	1
Sylvester, KP	2
Patey, RA	1
Rafferty, GF	1
Rees, D	1
Thein, SL	2
Greenough, A	2
Desai, SR	1
Wells, AU	1
Hansell, DM	1
Awogbade, M	1
Kring, E	1
Dodge, JT	1
Cohen, G	1
Kayden, HJ	1
Phillips, GB	1
Wranne, L	2
Sullivan, B	1
Riggs, A	2
Lerner, R	1
Werner, B	2
Asaba, H	1
Ternstedt, B	1
Elmqvist, E	1
Gachon, AM	1
Ghaddab, M	1
Kitzis, A	1
Wajcman, H	1
Dastugue, B	1
Lindahl, J	1
Leon, HA	2
Serova, LV	1
Landaw, SA	6
Seidman, DS	1
Shiloh, M	1
Gale, R	2
Oh, W	1
Fanaroff, AA	1
Wright, LL	1
Lemons, JA	1
Wright, E	1
Shankaran, S	1
Tyson, JE	1
Korones, SB	1
Leiter, C	1
Abramov, A	1
Shipulina, N	1
Hunt, RC	1
Shaklai, N	1
Smith, A	1
Forster, RE	1
Voelkel, NF	1
Allard, JD	1
Anderson, SM	1
Burke, TJ	1
Rael, LT	1
Ayala-Fierro, F	1
Carter, DE	1
Haynes, JM	1
St Pierre, JT	1
Wohlfeil, ER	1
Woehlck, HJ	1
Gottschall, JL	1
Poole, W	1
Hysell, DK	1
Moore, W	1
Hinners, R	1
Malanchuk, M	1
Miller, R	1
Stara, JF	1
Kellogg, EW	1
Fridovich, I	1
Klug, E	1
Sassa, S	1
Kappas, A	1
Bernstein, SE	2
Alvares, AP	1
Rodgers, PA	2
De Flora, A	1
Benatti, U	1
Guida, L	1
Bellelli, A	1
Benedetti, PL	1
Coletta, M	1
Ippoliti, R	1
Brunori, M	1
Solanki, DL	1
McCurdy, PR	1
Cuttitta, FF	1
Schechter, GP	1
Mosca, A	1
Carpinelli, A	1
Paleari, R	1
Carenini, A	1
Bonini, P	1
Franzini, C	1
Engel, RR	4
Modler, S	1
Matsen, JM	2
Petryka, ZJ	1
Chapman, SS	1
Schwartz, S	1
Larkin, EC	1
Adams, JD	1
Williams, WT	1
Duncan, DM	1
Wallace, HW	5
Coburn, RF	2
Brouillard, RP	1
Bensinger, TA	2
Gillette, PN	1
Glader, BE	1
Conrad, ME	1
Tan, AL	1
Noble, RW	1
Berk, PD	1
Rodkey, FL	4
Blaschke, TF	1
Collison, HA	3
Waggoner, JG	1
O'Neal, JD	2
Uddin, DE	1
Hamilton, MN	1
Edelstein, SJ	1
Rudolph, SA	1
Gill, SJ	1
Pawlak, AL	1
Pettit, JE	1
Williams, ED	1
Glass, HI	1
Lewis, SM	1
Szur, L	1
Wicks, CJ	1
Sjöstrand, T	1
Bonaventura, J	1
Schroeder, WA	1
Fang, S	1
Krill, CE	1
Kosower, NS	2
Marikovsky, Y	1
Wertheim, B	1
Danon, D	1
Gydell, K	1
Song, KR	1
Kosower, EM	1
Fällström, SP	3
Blakemore, WS	4
Habboushe, F	1
Shepard, CE	1
Winchell, HS	2
Vorosmarti, J	1
Bradley, ME	1
Linaweaver, PG	1
Kleckner, JC	1
Armstrong, FW	1
Kenepp, DL	1
Bottini, E	1
Lucarelli, P	1
Spennati, GF	1
Businco, L	1
Palmarino, R	1
Russell, ES	1
Bjure, J	1
Astrup, P	1
Garby, L	1
de Verdier, CH	1
Kutchai, H	1
Staub, NC	1
Aggarwal, SJ	1
Coltman, CA	1
Dudley, GM	1
Leverett, SD	1