Compounds > 3-hydroxybutyric acid
Page last updated: 2024-10-17

3-hydroxybutyric acid and Neoplasms

3-hydroxybutyric acid has been researched along with Neoplasms in 12 studies

3-Hydroxybutyric Acid: BUTYRIC ACID substituted in the beta or 3 position. It is one of the ketone bodies produced in the liver.
3-hydroxybutyric acid : A straight-chain 3-hydroxy monocarboxylic acid comprising a butyric acid core with a single hydroxy substituent in the 3- position; a ketone body whose levels are raised during ketosis, used as an energy source by the brain during fasting in humans. Also used to synthesise biodegradable plastics.

Neoplasms: New abnormal growth of tissue. Malignant neoplasms show a greater degree of anaplasia and have the properties of invasion and metastasis, compared to benign neoplasms.

Research Excerpts

ExcerptRelevanceReference
"In cancer patients with hypersplenism-related thrombocytopenia, PSAE is a safe intervention that effects a durable elevation in platelet counts across a range of malignancies and following the re-initiation of chemotherapy."2.73 ( Aasbrenn, M; Abd El-Aty, AM; Abdu, A; Abraha, HB; Achour, A; Acquaroni, M; Addeo, P; Agback, P; Agback, T; Al-Alwan, M; Al-Mazrou, A; Al-Mohanna, F; Aliste, M; Almquist, J; Andel, J; Ando, M; Angelov, A; Annuar, MSM; Antwi, K; Arroliga, AC; Arruda, SLM; Asch, SM; Averous, G; Ayaz, S; Ayer, GB; Bachellier, P; Ball, S; Banijamali, AR; Barden, TC; Bartoncini, S; Bedanie, G; Bellò, M; Benić, F; Berhe, GG; Bertiger, G; Beumer, JH; Bhandari, B; Bond, DS; Boules, M; Braüner Christensen, J; Brown-Johnson, C; Burgstaller, S; Cao, L; Capasso, C; Carlevato, R; Carvalho, AE; Ceci, F; Chagas, ATA; Chavan, SG; Chen, AP; Chen, HC; Chen, J; Chen, Q; Chen, Y; Chen, YF; Christ, ER; Chu, CW; Covey, JM; Coyne, GO'; Cristea, MC; Currie, MG; Dahdal, DN; Dai, L; Dang, Z; de Abreu, NL; de Carvalho, KMB; de la Plaza Llamas, R; Deandreis, D; Del Prete, S; Dennis, JA; Deur, J; Díaz Candelas, DA; Divyapriya, G; Djanani, A; Dodig, D; Doki, Y; Doroshow, JH; Dos Santos, RC; Durairaj, N; Dutra, ES; Eguchi, H; Eisterer, W; Ekmann, A; Elakkad, A; Evans, WE; Fan, W; Fang, Z; Faria, HP; Farris, SG; Fenoll, J; Fernandez-Botran, R; Flores, P; Fujita, J; Gan, L; Gandara, DR; Gao, X; Garcia, AA; Garrido, I; Gebru, HA; Gerger, A; Germano, P; Ghamande, S; Ghebeh, H; Giver Jensen, T; Go, A; Goichot, B; Goldwater, M; Gontero, P; Greil, R; Gruenberger, B; Guarneri, A; Guo, Y; Gupta, S; Haxholdt Lunn, T; Hayek, AJ; He, ML; Hellín, P; Hepprich, M; Hernández de Rodas, E; Hill, A; Hndeya, AG; Holdsworth, LM; Hookey, L; Howie, W; Hu, G; Huang, JD; Huang, SY; Hubmann, E; Hwang, SY; Imamura, H; Imperiale, A; Jiang, JQ; Jimenez, JL; Jin, F; Jin, H; Johnson, KL; Joseph, A; Juwara, L; Kalapothakis, E; Karami, H; Karayağiz Muslu, G; Kawabata, R; Kerwin, J; Khan, I; Khin, S; Kidanemariam, HG; Kinders, RJ; Klepov, VV; Koehler, S; Korger, M; Kovačić, S; Koyappayil, A; Kroll, MH; Kuban, J; Kummar, S; Kung, HF; Kurokawa, Y; Laengle, F; Lan, J; Leal, HG; Lee, MH; Lemos, KGE; Li, B; Li, G; Li, H; Li, X; Li, Y; Li, Z; Liebl, W; Lillaz, B; Lin, F; Lin, L; Lin, MCM; Lin, Y; Lin, YP; Lipton, RB; Liu, J; Liu, W; Liu, Z; Lu, J; Lu, LY; Lu, YJ; Ludwig, S; Luo, Y; Ma, L; Ma, W; Machado-Coelho, GLL; Mahmoodi, B; Mahoney, M; Mahvash, A; Mansour, FA; Mao, X; Marinho, CC; Masferrer, JL; Matana Kaštelan, Z; Melendez-Araújo, MS; Méndez-Chacón, E; Miletić, D; Miller, B; Miller, E; Miller, SB; Mo, L; Moazzen, M; Mohammadniaei, M; Montaz-Rosset, MS; Mousavi Khaneghah, A; Mühlethaler, K; Mukhopadhyay, S; Mulugeta, A; Nambi, IM; Navarro, S; Nazmara, S; Neumann, HJ; Newman, EM; Nguyen, HTT; Nicolato, AJPG; Nicolotti, DG; Nieva, JJ; Nilvebrant, J; Nocentini, A; Nugent, K; Nunez-Rodriguez, DL; Nygren, PÅ; Oberli, A; Oderda, M; Odisio, B; Oehler, L; Otludil, B; Overman, M; Özdemir, M; Pace, KA; Palm, H; Parchment, RE; Parise, R; Passera, R; Pavlovic, J; Pecherstorfer, M; Peng, Z; Pérez Coll, C; Petzer, A; Philipp-Abbrederis, K; Pichler, P; Piekarz, RL; Pilati, E; Pimentel, JDSM; Posch, F; Prager, G; Pressel, E; Profy, AT; Qi, P; Qi, Y; Qiu, C; Rajasekhar, B; Ramia, JM; Raynor, HA; Reis, VW; Reubi, JC; Ricardi, U; Riedl, JM; Romano, F; Rong, X; Rubinstein, L; Rumboldt, Z; Sabir, S; Safaeinili, N; Sala, BM; Sandoval Castillo, L; Sau, M; Sbhatu, DB; Schulte, T; Scott, V; Shan, H; Shao, Y; Shariatifar, N; Shaw, JG; She, Y; Shen, B; Shernyukov, A; Sheth, RA; Shi, B; Shi, R; Shum, KT; Silva, JC; Singh, A; Sinha, N; Sirajudeen, AAO; Slaven, J; Sliwa, T; Somme, F; Song, S; Steinberg, SM; Subramaniam, R; Suetta, C; Sui, Y; Sun, B; Sun, C; Sun, H; Sun, Y; Supuran, CT; Surger, M; Svartz, G; Takahashi, T; Takeno, A; Tam, AL; Tang, Z; Tanner, JA; Tannich, E; Taye, MG; Tekle, HT; Thomas, GJ; Tian, Y; Tobin, JV; Todd Milne, G; Tong, X; Une, C; Vela, N; Venkateshwaran, U; Villagrán de Tercero, CI; Wakefield, JD; Wampfler, R; Wan, M; Wang, C; Wang, J; Wang, L; Wang, S; Waser, B; Watt, RM; Wei, B; Wei, L; Weldemichael, MY; Wellmann, IA; Wen, A; Wild, D; Wilthoner, K; Winder, T; Wing, RR; Winget, M; Wöll, E; Wong, KL; Wong, KT; Wu, D; Wu, Q; Wu, Y; Xiang, T; Xiang, Z; Xu, F; Xu, L; Yamasaki, M; Yamashita, K; Yan, H; Yan, Y; Yang, C; Yang, H; Yang, J; Yang, N; Yang, Y; Yau, P; Yu, M; Yuan, Q; Zhan, S; Zhang, B; Zhang, H; Zhang, J; Zhang, N; Zhang, Y; Zhao, X; Zheng, BJ; Zheng, H; Zheng, W; Zhou, H; Zhou, X; Zhu, S; Zimmer, DP; Zionts, D; Zitella, A; Zlott, J; Zolfaghari, K; Zuo, D; Zur Loye, HC; Žuža, I, 2007)
"In diabetes, mainly type-1, ketoacidosis is the pathological response to glucose malabsorption."2.66Modulation of Cellular Biochemistry, Epigenetics and Metabolomics by Ketone Bodies. Implications of the Ketogenic Diet in the Physiology of the Organism and Pathological States. ( Balcerczyk, A; Dąbek, A; Pirola, L; Wojtala, M, 2020)
"Compared to normal cells, cancer cells maintain a higher level of reactive oxygen species (ROS) due to the dysfunctional oxidative phosphorylation and they highly rely on glucose for glycolysis and pentose phosphate pathway (PPP) to against the oxidative stress."2.61Multi-dimensional roles of ketone bodies in cancer biology: Opportunities for cancer therapy. ( Aa, J; Feng, S; Liu, J; Wang, G; Wang, H; Zhou, F, 2019)
"The mechanisms underlying cancer cachexia - the proximate cause of at least 20% of cancer-related deaths - have until recently remained rather obscure."1.51Nutraceutical targeting of TLR4 signaling has potential for prevention of cancer cachexia. ( Iloki-Assanga, S; Lujany, LML; McCarty, MF, 2019)

Research

Studies (12)

TimeframeStudies, this research(%)All Research%
pre-19904 (33.33)18.7374
1990's0 (0.00)18.2507
2000's3 (25.00)29.6817
2010's3 (25.00)24.3611
2020's2 (16.67)2.80

Authors

AuthorsStudies
Hwang, CY3
Choe, W3
Yoon, KS3
Ha, J3
Kim, SS3
Yeo, EJ3
Kang, I3
McCarty, MF1
Iloki-Assanga, S1
Lujany, LML1
Feng, S1
Wang, H2
Liu, J2
Aa, J1
Zhou, F1
Wang, G1
Dąbek, A1
Wojtala, M1
Pirola, L1
Balcerczyk, A1
Yang, N1
Tanner, JA1
Zheng, BJ1
Watt, RM1
He, ML1
Lu, LY1
Jiang, JQ1
Shum, KT1
Lin, YP1
Wong, KL1
Lin, MCM1
Kung, HF1
Sun, H1
Huang, JD1
Marinho, CC1
Nicolato, AJPG1
Reis, VW1
Dos Santos, RC1
Silva, JC1
Faria, HP1
Machado-Coelho, GLL1
Sun, Y2
Zhang, N1
Wang, J2
Guo, Y1
Sun, B1
Liu, W1
Zhou, H1
Yang, C1
Wei, L1
Ball, S1
Dennis, JA1
Bedanie, G1
Nugent, K1
Hayek, AJ1
Scott, V1
Yau, P1
Zolfaghari, K1
Goldwater, M1
Almquist, J1
Arroliga, AC1
Ghamande, S1
Wu, Q1
Ma, W1
Shi, R1
Zhang, B1
Mao, X1
Zheng, W1
Sbhatu, DB1
Berhe, GG1
Hndeya, AG1
Abraha, HB1
Abdu, A1
Gebru, HA1
Taye, MG1
Mulugeta, A1
Weldemichael, MY1
Tekle, HT1
Kidanemariam, HG1
Surger, M1
Angelov, A1
Liebl, W1
Hookey, L1
Bertiger, G1
Johnson, KL1
Boules, M1
Ando, M1
Dahdal, DN1
Riedl, JM1
Posch, F1
Prager, G1
Eisterer, W1
Oehler, L1
Sliwa, T1
Wilthoner, K1
Petzer, A1
Pichler, P1
Hubmann, E1
Winder, T1
Burgstaller, S1
Korger, M1
Andel, J1
Greil, R1
Neumann, HJ1
Pecherstorfer, M1
Philipp-Abbrederis, K1
Djanani, A1
Gruenberger, B1
Laengle, F1
Wöll, E1
Gerger, A1
Evans, WE1
Raynor, HA1
Howie, W1
Lipton, RB1
Thomas, GJ1
Wing, RR1
Pavlovic, J1
Farris, SG1
Bond, DS1
Hepprich, M1
Antwi, K1
Waser, B1
Reubi, JC1
Wild, D1
Christ, ER1
Braüner Christensen, J1
Aasbrenn, M1
Sandoval Castillo, L1
Ekmann, A1
Giver Jensen, T1
Pressel, E1
Haxholdt Lunn, T1
Suetta, C1
Palm, H1
Mansour, FA1
Al-Mazrou, A1
Al-Mohanna, F1
Al-Alwan, M1
Ghebeh, H1
Brown-Johnson, C1
Safaeinili, N1
Zionts, D1
Holdsworth, LM1
Shaw, JG1
Asch, SM1
Mahoney, M1
Winget, M1
Luo, Y1
Shan, H1
Gao, X1
Qi, P1
Li, Y2
Li, B1
Rong, X1
Shen, B1
Zhang, H1
Lin, F1
Tang, Z1
Fang, Z1
Peng, Z1
Jimenez, JL1
Ayer, GB1
Klepov, VV1
Pace, KA1
Zur Loye, HC1
Acquaroni, M1
Svartz, G1
Pérez Coll, C1
Otludil, B1
Ayaz, S1
Hill, A1
Elakkad, A1
Kuban, J1
Sabir, S1
Odisio, B1
Huang, SY1
Mahvash, A1
Miller, E1
Kroll, MH1
Overman, M1
Tam, AL1
Gupta, S1
Sheth, RA1
Deandreis, D1
Guarneri, A1
Ceci, F1
Lillaz, B1
Bartoncini, S1
Oderda, M1
Nicolotti, DG1
Pilati, E1
Passera, R1
Zitella, A1
Bellò, M1
Parise, R1
Carlevato, R1
Ricardi, U1
Gontero, P1
Coyne, GO'1
Wang, L2
Zlott, J1
Juwara, L1
Covey, JM1
Beumer, JH1
Cristea, MC1
Newman, EM1
Koehler, S1
Nieva, JJ1
Garcia, AA1
Gandara, DR1
Miller, B1
Khin, S1
Miller, SB1
Steinberg, SM1
Rubinstein, L1
Parchment, RE1
Kinders, RJ1
Piekarz, RL1
Kummar, S1
Chen, AP1
Doroshow, JH1
Li, X2
Chen, J2
Gan, L1
Tian, Y1
Shi, B1
Yang, Y1
Li, G1
Wu, D1
Wen, A1
Wu, Y1
Zhou, X1
Koyappayil, A1
Chavan, SG1
Mohammadniaei, M1
Go, A1
Hwang, SY1
Lee, MH1
Kurokawa, Y1
Yamashita, K1
Kawabata, R1
Fujita, J1
Imamura, H1
Takeno, A1
Takahashi, T1
Yamasaki, M1
Eguchi, H1
Doki, Y1
Schulte, T1
Sala, BM1
Nilvebrant, J1
Nygren, PÅ1
Achour, A1
Shernyukov, A1
Agback, T1
Agback, P1
Karami, H1
Shariatifar, N1
Nazmara, S1
Moazzen, M1
Mahmoodi, B1
Mousavi Khaneghah, A1
Sinha, N1
Mukhopadhyay, S1
Sau, M1
Qi, Y1
Wan, M1
Abd El-Aty, AM1
Li, H2
Cao, L1
She, Y1
Shao, Y1
Jin, F1
Wang, S1
Melendez-Araújo, MS1
Lemos, KGE1
Arruda, SLM1
Dutra, ES1
de Carvalho, KMB1
de la Plaza Llamas, R1
Díaz Candelas, DA1
Ramia, JM1
Zhu, S1
Liu, Z1
Lu, J2
Xiang, Z1
Lan, J1
Yu, M1
Chen, Y2
Sirajudeen, AAO1
Annuar, MSM1
Subramaniam, R1
Somme, F1
Montaz-Rosset, MS1
Averous, G1
Deur, J1
Goichot, B1
Bachellier, P1
Addeo, P1
Imperiale, A1
Xu, L1
Li, Z3
Song, S1
Chen, Q1
Mo, L1
Wang, C1
Fan, W1
Yan, Y1
Tong, X1
Yan, H1
Singh, A1
Chen, HC1
Chen, YF1
Lu, YJ1
Wong, KT1
Chu, CW1
Banijamali, AR1
Carvalho, AE1
Wakefield, JD1
Germano, P1
Barden, TC1
Tobin, JV1
Zimmer, DP1
Masferrer, JL1
Profy, AT1
Currie, MG1
Todd Milne, G1
Zhang, Y1
Yang, H1
Dang, Z1
Zhan, S1
Sun, C1
Hu, G1
Lin, Y1
Yuan, Q1
Karayağiz Muslu, G1
Özdemir, M1
Del Prete, S1
Nocentini, A1
Supuran, CT1
Capasso, C1
Chagas, ATA1
Ludwig, S1
Pimentel, JDSM1
de Abreu, NL1
Nunez-Rodriguez, DL1
Leal, HG1
Kalapothakis, E1
Zhang, J1
Lin, L1
Dodig, D1
Kovačić, S1
Matana Kaštelan, Z1
Žuža, I1
Benić, F1
Slaven, J1
Miletić, D1
Rumboldt, Z1
Fernandez-Botran, R1
Wellmann, IA1
Une, C1
Méndez-Chacón, E1
Hernández de Rodas, E1
Bhandari, B1
Villagrán de Tercero, CI1
Nguyen, HTT1
Romano, F1
Wampfler, R1
Mühlethaler, K1
Tannich, E1
Oberli, A1
Yang, J2
Xiang, T1
Dai, L1
Zhao, X1
Ma, L1
Zuo, D1
Wei, B1
Sui, Y1
Xu, F1
Zheng, H1
Qiu, C1
Jin, H1
Kerwin, J1
Khan, I1
Rajasekhar, B1
Venkateshwaran, U1
Durairaj, N1
Divyapriya, G1
Nambi, IM1
Joseph, A1
Aliste, M1
Garrido, I1
Flores, P1
Hellín, P1
Vela, N1
Navarro, S1
Fenoll, J1
Wu, YL1
Qiu, YK1
Liow, SS1
Loh, XJ1
Sabbatini, P1
Rowand, JL1
Groy, A1
Korenchuk, S1
Liu, Q1
Atkins, C1
Dumble, M1
Anderson, K1
Wilson, BJ1
Emmitte, KA1
Rabindran, SK1
Kumar, R1
EMMELOT, P3
BOS, CJ3
Darzy, KH1
Murray, RD1
Gleeson, HK1
Pezzoli, SS1
Thorner, MO1
Shalet, SM1
Tisdale, MJ1

Reviews

3 reviews available for 3-hydroxybutyric acid and Neoplasms

ArticleYear
Molecular Mechanisms for Ketone Body Metabolism, Signaling Functions, and Therapeutic Potential in Cancer.
    Nutrients, 2022, Nov-21, Volume: 14, Issue:22

    Topics: 3-Hydroxybutyric Acid; Diet, Ketogenic; Humans; Ketone Bodies; Neoplasms; Signal Transduction

2022
Molecular Mechanisms for Ketone Body Metabolism, Signaling Functions, and Therapeutic Potential in Cancer.
    Nutrients, 2022, Nov-21, Volume: 14, Issue:22

    Topics: 3-Hydroxybutyric Acid; Diet, Ketogenic; Humans; Ketone Bodies; Neoplasms; Signal Transduction

2022
Molecular Mechanisms for Ketone Body Metabolism, Signaling Functions, and Therapeutic Potential in Cancer.
    Nutrients, 2022, Nov-21, Volume: 14, Issue:22

    Topics: 3-Hydroxybutyric Acid; Diet, Ketogenic; Humans; Ketone Bodies; Neoplasms; Signal Transduction

2022
Molecular Mechanisms for Ketone Body Metabolism, Signaling Functions, and Therapeutic Potential in Cancer.
    Nutrients, 2022, Nov-21, Volume: 14, Issue:22

    Topics: 3-Hydroxybutyric Acid; Diet, Ketogenic; Humans; Ketone Bodies; Neoplasms; Signal Transduction

2022
Molecular Mechanisms for Ketone Body Metabolism, Signaling Functions, and Therapeutic Potential in Cancer.
    Nutrients, 2022, Nov-21, Volume: 14, Issue:22

    Topics: 3-Hydroxybutyric Acid; Diet, Ketogenic; Humans; Ketone Bodies; Neoplasms; Signal Transduction

2022
Molecular Mechanisms for Ketone Body Metabolism, Signaling Functions, and Therapeutic Potential in Cancer.
    Nutrients, 2022, Nov-21, Volume: 14, Issue:22

    Topics: 3-Hydroxybutyric Acid; Diet, Ketogenic; Humans; Ketone Bodies; Neoplasms; Signal Transduction

2022
Molecular Mechanisms for Ketone Body Metabolism, Signaling Functions, and Therapeutic Potential in Cancer.
    Nutrients, 2022, Nov-21, Volume: 14, Issue:22

    Topics: 3-Hydroxybutyric Acid; Diet, Ketogenic; Humans; Ketone Bodies; Neoplasms; Signal Transduction

2022
Molecular Mechanisms for Ketone Body Metabolism, Signaling Functions, and Therapeutic Potential in Cancer.
    Nutrients, 2022, Nov-21, Volume: 14, Issue:22

    Topics: 3-Hydroxybutyric Acid; Diet, Ketogenic; Humans; Ketone Bodies; Neoplasms; Signal Transduction

2022
Molecular Mechanisms for Ketone Body Metabolism, Signaling Functions, and Therapeutic Potential in Cancer.
    Nutrients, 2022, Nov-21, Volume: 14, Issue:22

    Topics: 3-Hydroxybutyric Acid; Diet, Ketogenic; Humans; Ketone Bodies; Neoplasms; Signal Transduction

2022
Multi-dimensional roles of ketone bodies in cancer biology: Opportunities for cancer therapy.
    Pharmacological research, 2019, Volume: 150

    Topics: 3-Hydroxybutyric Acid; Animals; Diet, Ketogenic; Humans; Ketone Bodies; Liver; Neoplasms

2019
Modulation of Cellular Biochemistry, Epigenetics and Metabolomics by Ketone Bodies. Implications of the Ketogenic Diet in the Physiology of the Organism and Pathological States.
    Nutrients, 2020, Mar-17, Volume: 12, Issue:3

    Topics: 3-Hydroxybutyric Acid; Acetoacetates; Animals; Diabetes Mellitus, Type 1; Diet, Ketogenic; Epigenesi

2020

Trials

1 trial available for 3-hydroxybutyric acid and Neoplasms

ArticleYear
    Angewandte Chemie (Weinheim an der Bergstrasse, Germany), 2007, Aug-27, Volume: 119, Issue:34

    Topics: 3-Hydroxybutyric Acid; Acetazolamide; Acrylates; Administration, Intravenous; Adolescent; Adult; Aer

2007

Other Studies

8 other studies available for 3-hydroxybutyric acid and Neoplasms

ArticleYear
Nutraceutical targeting of TLR4 signaling has potential for prevention of cancer cachexia.
    Medical hypotheses, 2019, Volume: 132

    Topics: 3-Hydroxybutyric Acid; Adipocytes; Biotin; Cachexia; Carnitine; Catechin; Coumaric Acids; Dietary Su

2019
PHB-Based Gels as Delivery Agents of Chemotherapeutics for the Effective Shrinkage of Tumors.
    Advanced healthcare materials, 2016, Volume: 5, Issue:20

    Topics: 3-Hydroxybutyric Acid; Animals; Antineoplastic Agents; Cell Line; Doxorubicin; Drug Carriers; Drug D

2016
Antitumor activity of GSK1904529A, a small-molecule inhibitor of the insulin-like growth factor-I receptor tyrosine kinase.
    Clinical cancer research : an official journal of the American Association for Cancer Research, 2009, May-01, Volume: 15, Issue:9

    Topics: 3-Hydroxybutyric Acid; Animals; Antineoplastic Agents; Apoptosis; Blood Glucose; Blotting, Western;

2009
Factors influencing the oxidation of di-beta-hydroxybutyrate by tumour mitochondria.
    Biochimica et biophysica acta, 1955, Volume: 18, Issue:2

    Topics: 3-Hydroxybutyric Acid; Humans; Ketone Bodies; Mitochondria; Neoplasms; Oxidation-Reduction

1955
Enzymic activities of tumour mitochondria as evidenced by their inhibitory effect on the oxidation of DL-, D- and L-beta-hydroxybutyrate by liver mitochondria.
    Biochimica et biophysica acta, 1956, Volume: 19, Issue:3

    Topics: 3-Hydroxybutyric Acid; Butyrates; Liver; Mitochondria; Mitochondria, Liver; Neoplasms; Oxidation-Red

1956
Fatty acid oxidation in normal and neoplastic tissues; the oxidation of beta-hydroxybutyrate and pyruvate by tumour mitochondria.
    Enzymologia, 1957, Apr-30, Volume: 18, Issue:3

    Topics: 3-Hydroxybutyric Acid; Butyrates; Fatty Acids; Lipid Metabolism; Mitochondria; Neoplasms; Oxidation-

1957
The impact of short-term fasting on the dynamics of 24-hour growth hormone (GH) secretion in patients with severe radiation-induced GH deficiency.
    The Journal of clinical endocrinology and metabolism, 2006, Volume: 91, Issue:3

    Topics: 3-Hydroxybutyric Acid; Adult; Area Under Curve; Bilirubin; Blood Glucose; Cluster Analysis; Eating;

2006
Role of acetoacetyl-CoA synthetase in acetoacetate utilization by tumor cells.
    Cancer biochemistry biophysics, 1984, Volume: 7, Issue:2

    Topics: 3-Hydroxybutyric Acid; Acetate-CoA Ligase; Acetoacetates; Animals; Bone Marrow; Cell Line; Cells, Cu

1984