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EarlyMetabolic / GH fragment

HGH Fragment 176-191

HGH Fragment 176-191 (AOD9604) is a small piece cut from the tail end of the human growth hormone molecule, designed to burn fat without the muscle-growth or blood-sugar side effects of full growth hormone.

Lose fatEnergy & metabolismJoints & tendonsGrowth hormone
Not FDA-approvedBanned in competitive sports (WADA)No verified human dosingHuman safety data lackingUnregulated product riskInjection or oral only in animal studies

Scientists isolated this fragment from the very end of the human growth hormone molecule in the late 1990s, hoping to keep GH's fat-burning power while leaving behind the parts that make you grow taller, build muscle, and mess with blood sugar. It was developed under the name AOD9604 as a potential obesity drug and reached early-stage human trials in the early 2000s, but no published results from those human trials turn up in the research reviewed here. Today it circulates online as a research chemical marketed for fat loss and, more recently, for joint support, and it is banned in competitive sports. Nearly everything we actually know about whether it works comes from studies in mice, rats, and one study in rabbits.

How strong is the evidence?

Every solid piece of data on what this peptide actually does in a living body comes from animal studies - obese mice, obese rats, and one rabbit knee-arthritis model. A 2004 industry note says human obesity trials (phase IIa) were underway, and a 2026 clinical review mentions it alongside other 'research peptides' people buy online, but no completed human efficacy or safety trial results appear anywhere in the 22 papers reviewed. That makes this a preclinical story with real animal science behind it, not a human-proven one.

Uses

What people use it for

Fat loss / weight-management research

Animal / lab

The original and best-studied use. In obese mice and rats, it consistently reduced weight gain and boosted fat burning without the blood-sugar problems seen with full growth hormone. It reached early human obesity trials in the early 2000s, but no published results from those trials exist in the literature reviewed.

Joint and cartilage support

Animal / lab

One rabbit study injected it directly into arthritic knee joints, alone or combined with hyaluronic acid (the joint-lubricating gel used in real knee-arthritis injections), and found better cartilage protection and less limping with the combination. This is a single animal study, not human evidence.

Used off-label in bodybuilding and sports circles - and tested for as a banned substance

Some human data

Because of its reputed fat-burning effect, it shows up in gray-market physique and performance circles. It is banned by the World Anti-Doping Agency, and several published lab methods exist purely to detect it in athletes' blood and urine.

Potential benefits

What it may help with

  • Sped up fat burning and reduced weight gain in animal studies

    Animal / lab

    In obese mice and rats, it increased the breakdown and burning of stored fat and cut how much weight the animals gained - in the rat study, weight gain was reduced by more than half compared to untreated animals.

  • Didn't cause the blood-sugar problems that full growth hormone does

    Animal / lab

    Unlike regular growth hormone, it didn't raise blood sugar or blunt insulin sensitivity in the animal studies - a key reason it was pursued as a safer alternative for fighting obesity.

  • Doesn't appear to trigger the growth-and-cell-division signals of real growth hormone

    Animal / lab

    Lab tests show it doesn't attach to the regular growth-hormone receptor and doesn't make cells multiply the way full growth hormone does. In theory, that means it wouldn't be expected to cause the tissue-growth or tumor-risk concerns linked to actual growth hormone, though this hasn't been confirmed in long-term human use.

    Studies:11673763
  • May help protect joint cartilage when injected into the joint

    Animal / lab

    In one rabbit study of arthritic knees, weekly injections directly into the joint reduced cartilage damage and shortened the limping period, especially when combined with hyaluronic acid.

    Studies:26275694

What to watch for

Side effects & risks

  • Moderate

    Real-world human safety profile is basically unknown

    No completed human trial results on side effects appear in the literature reviewed. Anyone using it is relying on rodent data and marketing claims, not verified human safety records.

  • Moderate

    Hormone and metabolism shifts reported across similar growth-hormone-axis peptides

    A 2026 clinical review covering AOD9604 alongside related growth-hormone peptides describes reports of prolactin and cortisol changes, appetite changes, blood sugar swings, and fluid retention in people self-administering this class of compounds. It isn't clear how much of this applies specifically to AOD9604 versus the other peptides discussed in the same review.

  • Mild

    Muscle and joint aches, injection-site reactions

    The same review lists muscle or joint aches and injection-site reactions as common complaints across this peptide class, relevant since AOD9604 is typically self-injected.

  • Moderate

    Unregulated product quality risk

    Vials sold as AOD9604 online have been seized and analyzed by drug-testing authorities. Buying from unregulated sources means the real content, purity, and dose of what's in the vial isn't guaranteed - often a bigger practical risk than any effect of the peptide itself.

Dosing

Dosing — what studies used

There is no published, completed human dosing protocol for this peptide - it never made it through human trials with results that appear in the literature. Everything below comes from animal studies. If you see a specific 'human dose' quoted online, it is not backed by any peer-reviewed data in the research reviewed here; it's a gray-market estimate, not a proven or approved regimen.

How it's taken:Oral (rat studies only)Subcutaneous or intraperitoneal injection (mouse studies)Intra-articular injection - directly into the joint (rabbit study)

Obesity / weight-gain research in rats

Animal study

500 micrograms per kilogram of body weight

Once daily · 19 days · Oral

Cut body-weight gain by more than half versus untreated animals and increased fat-burning activity in fat tissue, with no adverse effect on insulin sensitivity.

Obesity research in mice

Animal study

Not stated in the published abstracts

Continuous delivery via mini-pump, or repeated injection · 14 days · Subcutaneous (mini-osmotic pump) or intraperitoneal injection

Used in obese and lean mice to study fat oxidation and weight gain; the exact dose given wasn't reported in these abstracts.

Knee osteoarthritis / cartilage research in rabbits

Animal study

0.25 mg per knee joint (with or without 6 mg hyaluronic acid)

Once weekly · 4 to 7 weeks · Intra-articular injection (directly into the knee joint, ultrasound-guided)

Tested alone and alongside hyaluronic acid in a rabbit knee-arthritis model; the combination outperformed either treatment alone.

It's chemically fragile: lab testing shows it degrades quickly in serum and plasma at room or refrigerator temperature within about a week, though it stays stable much longer in dried blood spots. It's also on the World Anti-Doping Agency's banned list, and multiple lab methods exist solely to detect it in blood and urine.

These figures describe what researchers used in studies. They are not a recommendation or a prescription.

Mechanism

How it works

Growth hormone is a much bigger molecule with many jobs - it makes you grow, builds muscle, and can raise blood sugar. Researchers found that one small piece from its tail end seemed to carry most of the fat-burning instructions on its own, without the growth or blood-sugar effects. That's the piece this product copies. In animal studies, it doesn't lock onto the regular growth-hormone receptor and doesn't make cells multiply the way full growth hormone does - instead it seems to nudge fat cells to release and burn stored fat through a different route. One clue: in obese mice it raised the levels of a fat-cell docking point called the beta-3 receptor, which had been running low, back toward normal. Researchers were careful to note this isn't the peptide flipping that receptor on directly - when they used mice bred without the beta-3 receptor, the peptide could still increase energy burning and fat oxidation in a short-term test, even though its longer-term weight-loss effect was blunted. So the honest picture is that beta-3 is part of the story but not the whole switch, and the exact mechanism is still not fully pinned down. Either way, it increased fat burning and cut weight gain in mice and rats without the blood-sugar side effects seen with real growth hormone.

Who should avoid it

  • Anyone competing in drug-tested sports - it's banned by the World Anti-Doping Agency and detectable in blood and urine
  • Pregnant or breastfeeding people - never studied, no safety data exists
  • Anyone with active cancer or a history of hormone-sensitive tumors - it's derived from growth hormone, and long-term human cancer-risk data doesn't exist
  • People with kidney or liver disease - not studied in this population
  • Anyone expecting it to build muscle, add height, or act like real growth hormone - animal data suggests it specifically does not trigger those effects

Interactions to know

  • No human drug-interaction studies exist for this peptide - it hasn't been formally tested alongside any medication.
  • Its fat-burning effect in animals is linked to the same beta-3 receptor system used by some asthma medications and stimulant drugs - though animal work suggests it doesn't switch that receptor on directly; combining them is unstudied and could theoretically add up, but this is a mechanistic concern, not a documented interaction.
  • Because it's typically bought from unregulated sources, contamination or mislabeling with other peptides is a more realistic practical risk than a true drug interaction.

The papers that matter most

Key studies

  1. 2000animal study (rats)PMID 11146367

    Daily oral dosing cut body-weight gain by more than half in obese rats and boosted fat-burning activity, without harming insulin sensitivity - the foundational efficacy study for this peptide.

    Metabolic studies of a synthetic lipolytic domain (AOD9604) of human growth hormone

  2. 2001animal + lab study (mice, cell assays)PMID 11673763

    Reduced weight gain and increased fat burning in obese mice, but - unlike full growth hormone - didn't bind the growth-hormone receptor or cause cell proliferation and didn't raise blood sugar.

    Increase of fat oxidation and weight loss in obese mice caused by chronic treatment with human growth hormone or a modified C-terminal fragment

  3. 2001animal study (mice)PMID 11713213

    Both the peptide and full growth hormone raised the low beta-3 receptor levels seen in obese mice back toward normal, and their long-term weight-loss effect was blunted in mice bred without that receptor. But the authors specifically concluded the fat-burning action is NOT worked directly through the beta-3 receptor - in a short-term test the peptide still boosted energy burning and fat oxidation in mice lacking it. So beta-3 contributes to fat-burning sensitivity rather than being the direct on-switch.

    The effects of human GH and its lipolytic fragment (AOD9604) on lipid metabolism following chronic treatment in obese mice and beta(3)-AR knock-out mice

  4. 2015animal study (rabbits)PMID 26275694

    Weekly joint injections improved cartilage scores and reduced limping in an arthritis model, especially when combined with hyaluronic acid - the only evidence for a joint-health use.

    Effect of Intra-articular Injection of AOD9604 with or without Hyaluronic Acid in Rabbit Osteoarthritis Model

  5. 2026clinical reviewPMID 42395176

    A 2026 review of self-administered growth-hormone-related peptides (including AOD9604) flags hormonal, metabolic, and musculoskeletal side effects reported across this drug class and notes that rigorous human data for most of these compounds, including this one, is still lacking.

    The emerging landscape of performance-enhancing peptides modulating GH-IGF1 axis: bridging the gap between clinical evidence and patient self-administration

  6. 2004industry development notePMID 15134286

    Confirms that AOD9604 reached phase IIa human obesity trials by 2002 - but no results from those trials are reported here or elsewhere in this literature set.

    AOD-9604 Metabolic

Bottom line

There's genuinely interesting rodent science behind this peptide's fat-burning story, and a single small study hints it might help joints too - but no published human trial has ever confirmed it works or is safe in people. Until real human data shows up, treat any weight-loss or joint claims as unproven, and remember it's a banned substance for tested athletes.

Research papers

Studies we have on file for HGH Fragment 176-191. Tap a title to open it on PubMed. Labels like “animal” or “human trial” are rough guides.

22 papers

Other: 8Human (observational): 4Review article: 3Animal study: 3Lab / cells: 2Human trial: 2
2026Journal of the American Academy of Orthopaedic Surgeons. Global research & reviews

Therapeutic Peptides in Orthopaedics: Applications, Challenges, and Future Directions.

Otherin vitroPMID 41490200

Therapeutic peptides are emerging as promising adjuncts in the management of orthopaedic injuries, grounded in their ability to modulate molecular signaling networks central to cellular medicine. By acting on key pathways such as PI3K/Akt, mTOR, MAPK, TGF-β, and AMPK, peptides exert influence over tissue regeneration, inflammation resolution, and neuromuscular recovery. Wound-healing peptides such as BPC-157, TB-500, and GHK-Cu promote angiogenesis, integrin-mediated extracellular matrix remodeling, and fibroblast activation, whereas growth hormone secretagogues like ipamorelin, CJC-1295, tesamorelin, sermorelin, and AOD-9604 activate IGF-1 signaling and satellite cell repair. Recovery-enhancing agents such as epithalon, delta sleep-inducing peptide, and pinealon target circadian and mitochondrial regulators, and neuroactive peptides like selank, semax, and dihexa enhance brain-derived neurotrophic factor and HGF/c-Met pathways critical to neuroplasticity. Although preclinical studies are promising, there is a current lack of clinical trials. This review integrates current mechanistic insights with orthopaedic relevance, emphasizing safety, efficacy, and future directions for responsible integration into musculoskeletal care.

2004Current opinion in investigational drugs (London, England : 2000)

AOD-9604 Metabolic.

Metabolic is developing AOD-9604 for the potential treatment of obesity. By February 2002, phase IIa trials were underway.

2026Sports medicine (Auckland, N.Z.)

Safety and Efficacy of Approved and Unapproved Peptide Therapies for Musculoskeletal Injuries and Athletic Performance.

Review articlehumanPMID 41966639

Peptides are short chains of amino acids with a unique pharmacological niche between small-molecule drugs and large proteins. Their use in sports medicine is rapidly expanding, driven by patient demand for accelerated injury recovery and performance enhancement. While numerous peptide drugs have undergone a rigorous approval process that evaluates both safety and efficacy, a parallel "gray market" of unapproved compounds has emerged, operating largely outside of regulatory oversight. Our objective is to present the pharmacological mechanisms, safety profiles, and regulatory status of prominent approved and unapproved peptides marketed direct to patients, including AOD-9604 (anti-obesity drug 9604), BPC-157 (body protection compound 157), CJC-1295, FS-344 (follistatin-344), GHK-Cu (glycyl-L-histidyl-L-lysine copper), ipamorelin, MOTS-C (mitochondrial ORF of the 12S rRNA type-c), sermorelin, SS-31 (elamipretide), tesamorelin (Egrifta), Tβ4 (thymosin beta-4), and TB-500 (thymosin beta-4 fragment). Many unapproved peptides demonstrate favorable tissue repair and metabolic outcomes in animal models, but rigorous human safety data are scarce, and there is potential for serious harm to patients. This narrative review focuses on the utilization of peptides in sports medicine, and alternative treatments that may be considered. We provide a framework to navigate patient discussions about peptides to better facilitate evidence-based practices for musculoskeletal healing and athletic performance. We also discuss the placebo effect as a mediator of peptide efficacy, and how social media amplifies this effect.

2001Endocrinology

The effects of human GH and its lipolytic fragment (AOD9604) on lipid metabolism following chronic treatment in obese mice and beta(3)-AR knock-out mice.

Animal studyhumanPMID 11713213

Both human GH (hGH) and a lipolytic fragment (AOD9604) synthesized from its C-terminus are capable of inducing weight loss and increasing lipolytic sensitivity following long-term treatment in mice. One mechanism by which this may occur is through an interaction with the beta-adrenergic pathway, particularly with the beta(3)-adrenergic receptors (beta(3)-AR). Here we describe how hGH and AOD9604 can reduce body weight and body fat in obese mice following 14 d of chronic ip administration. These results correlate with increases in the level of expression of beta(3)-AR RNA, the major lipolytic receptor found in fat cells. Importantly, both hGH and AOD9604 are capable of increasing the repressed levels of beta(3)-AR RNA in obese mice to levels comparable with those in lean mice. The importance of beta(3)-AR was verified when long-term treatment with hGH and AOD9604 in beta(3)-AR knock-out mice failed to produce the change in body weight and increase in lipolysis that was observed in wild-type control mice. However, in an acute experiment, AOD9604 was capable of increasing energy expenditure and fat oxidation in the beta(3)-AR knock-out mice. In conclusion, this study demonstrates that the lipolytic actions of both hGH and AOD9604 are not mediated directly through the beta(3)-AR although both compounds increase beta(3)-AR expression, which may subsequently contribute to enhanced lipolytic sensitivity.

2000Hormone research

Metabolic studies of a synthetic lipolytic domain (AOD9604) of human growth hormone.

Animal studyhumanPMID 11146367

A synthetic analogue (AOD9604) of the lipolytic domain of human growth hormone (hGH) has been studied for its metabolic actions in obese Zucker rats. Daily treatment with an oral dose of AOD9604 of 500 microg/kg body weight for 19 days reduced over 50% (15.8 +/- 0.6 vs. 35.6 +/- 0.8 g) body weight gain of the animals in comparison with the control. The adipose tissues of the AOD9604--treated animals were found to have an increase in lipolytic activity. In contrast to chronic treatment with intact hGH, chronic treatment with AOD9604 showed no adverse effect on insulin sensitivity of the animals, as demonstrated with euglycemic clamp techniques. The results in the present study suggest that the analogue of the hGH lipolytic domain may have the potential to be developed into an orally usable and safe therapeutic agent for obesity.

2015Drug testing and analysis

Detection and in vitro metabolism of AOD9604.

Lab / cellsin vitroPMID 25208511

AOD9604 is a peptide consisting of the C-terminal fragment of human growth hormone from amino acids 177-191 with an additional tyrosine residue at the N-terminus of the peptide. It is reported to mimic the lipolytic properties of growth hormone without the diabetogenic side effects. Therefore, AOD9604 may be used as a performance enhancing drug and is banned by the World Anti-doping Agency (WADA). The peptide is available on several Internet websites and was recently identified in confiscated vials in the USA. To detect abuse of the peptide in athletes, a solid-phase extraction method was validated in urine with a limit of detection of 50&#x2009;pg/mL. The method has good linearity, precision (<20%), specificity and recovery (62%). Six potential metabolites of the peptide were identified after incubation of AOD9604 in serum and urine. Quantification of the metabolites in serum identified a single metabolite, consisting of amino acids CRSVEGSCG, which is significantly more stable than the other metabolites or the parent compound. Screening for AOD9604 and the stable metabolite may potentially allow an increased window of detection.

2015Annals of clinical and laboratory science

Effect of Intra-articular Injection of AOD9604 with or without Hyaluronic Acid in Rabbit Osteoarthritis Model.

Animal studyrabbitPMID 26275694

To investigate the effects of AOD9604 intra-articular injections with or without hyaluronic acid (HA) in a collagenase-induced knee osteoarthritis (OA) rabbit model. Mature New Zealand white rabbits (n=32) were randomly administered 2 mg collagenase type II twice in each knee joint. Weekly injections of 0.6 mL saline (Group 1), 6 mg HA (Group 2), 0.25 mg AOD9604 (Group 3), and 0.25 mg AOD9604 with 6 mg HA (Group 4) were administered for 4-7 weeks after the first intra-articular collagenase injection. The degree of cartilage degeneration was assessed using morphological and histopathological findings, and the degree of lameness was observed at 8 weeks after the first collagenase injection. Mean gross morphological and histopathological scores were significantly higher in Group 1 than in Groups 2, 3, and 4, and the scores were significantly lower in Group 4 than in Groups 2 and 3. The lameness period in Group 4 was significantly shorter than those in Groups 1, 2, and 3. The lameness period in Group 1 was significantly longer than those in Groups 2 and 3. Intra-articular AOD9604 injections using ultrasound guidance enhanced cartilage regeneration, and combined AOD9604 and HA injections were more effective than HA or AOD9604 injections alone in the collagenase-induced knee OA rabbit model.

2026Frontiers in endocrinology

The emerging landscape of performance-enhancing peptides modulating GH-IGF1 axis: bridging the gap between clinical evidence and patient self-administration.

Review articlehumanPMID 42395176

Performance-enhancing drugs (PEDs) marketed as "research compounds" include unregulated peptides intended to modulate the growth hormone-insulin-like growth factor-1 (GH-IGF-1) axis. The agents most commonly encountered in clinical practice and online self-administration protocols include growth hormone-releasing hormone (GHRH) analogues (e.g., sermorelin, tesamorelin, CJC-1295 with Drug Affinity Complex [DAC], CJC-1295 without DAC), growth hormone secretagogues (GHS; e.g., growth hormone-releasing peptide-2 (GHRP-2), growth hormone-releasing peptide-6 (GHRP-6), hexarelin, ipamorelin), the growth hormone (GH) fragment - AOD9604 (hGH 176-191), and insulin-like growth factor-1 (IGF-1) analogues (e.g., pegylated mechano growth factor (PEG-MGF), IGF-1 Long R3 (IGF-1 LR3)). Reported adverse effects span endocrine and metabolic disturbances (including prolactin and cortisol elevations, appetite changes, and dysglycaemia), fluid retention syndromes, musculoskeletal symptoms (myalgia/arthralgia), and injection-site reactions. Given the absence of regulatory approval for physique- or performance-related indications and the uncertainty surrounding product composition, dose, and stacking practices in unregulated supply chains, clinicians increasingly require a pragmatic framework to interpret symptoms and laboratory abnormalities in patients using these compounds. This narrative review contrasts peer-reviewed pharmacokinetic/pharmacodynamic and clinical evidence with commonly encountered online self-administration protocols, stratifying peptides into evidence tiers from regulatory-grade randomized trial data to a complete absence of human studies, and highlights the resulting uncertainty around putative performance and recomposition benefits. We summarise structural characteristics, pharmacologic effects, and commonly reported dosing patterns, and we synthesise clinically relevant adverse effects with particular attention to hormonal imbalance, endocrine-metabolic risk, and biologically plausible but unproven mitogenic concerns. Finally, we propose a clinically oriented assessment algorithm to support exposure history taking, triage of symptom domains, and risk communication without legitimising off-label peptide regimens.

2006Current opinion in investigational drugs (London, England : 2000)

Obesity drugs in clinical development.

Human trialhumanPMID 16625817

A number of anti-obesity drugs are currently undergoing clinical development. These include: (i) centrally-acting drugs, such as the noradrenergic and dopaminergic reuptake inhibitor radafaxine, the endocannabinoid antagonist rimonabant, the selective serotonin 5-HT2c agonist APD-356, and oleoyl-estrone; (ii) drugs that target peripheral episodic satiety signals, such as glucagon-like peptide-1 (exenatide, exenatide-LAR and liraglutide), peptide YY (intranasal PYY3-36 and AC-162325) and amylin (pramlintide); (iii) drugs that block fat absorption, such as the novel lipase inhibitors cetilistat and GT-389255; and (iv) a human growth hormone fragment (AOD-9604) that increases adipose tissue breakdown. Of these, only rimonabant has got as far as completing phase III clinical trials. This review will provide an overview of the most prominent drugs currently undergoing clinical development as potential anti-obesity therapies.

2012Recent patents on endocrine, metabolic & immune drug discovery

Current updates in the medical management of obesity.

Obesity is a chronic medical condition that is expected to become an indirect but leading cause of mortality and morbidity. Obesity results in type 2 diabetes mellitus, insulin resistance, hypertension, dyslipidemia, coronary heart disease. These factors contribute to cardiovascular disease that is a leading cause of death. Therefore, the approach to obesity therapy should be designed to reduce cardiovascular disease risk and mortality. Diet and lifestyle changes remain the cornerstones of therapy for obesity, but the resultant weight loss is often small. For more effective weight loss, individuals have shown to benefit from anti-obesity medications. Anti-Obesity therapy is considered for individuals with a body mass index greater than 30 kg/m2 or ranging from 25 to 30 kg/m2, or individuals with co-morbid conditions. Recent anti-obese medications affect biological mechanisms that suppress appetite and absorb nutrients to regulate body weight. In this review, we discuss the FDA approved anti-obesity drugs and recent patents which include phentermine/topiramate, pramlintide, lorcaserin, AOD9604, oleoyl-estrone, trk-beta antagonists and melanin concentrating hormone that can reduce adiposity at the molecular level.

2001International journal of obesity and related metabolic disorders : journal of the International Association for the Study of Obesity

Increase of fat oxidation and weight loss in obese mice caused by chronic treatment with human growth hormone or a modified C-terminal fragment.

Lab / cellsin vitroPMID 11673763

To observe the chronic effects of human growth hormone (hGH) and AOD9604 (a C-terminal fragment of hGH) on body weight, energy balance, and substrate oxidation rates in obese (ob/ob) and lean C57BL/6Jmice. In vitro assays were used to confirm whether the effects of AOD9604 are mediated through the hGH receptor, and if this peptide is capable of cell proliferation via the hGH receptor. Obese and lean mice were treated with hGH, AOD or saline for 14 days using mini-osmotic pumps. Body weight, caloric intake, resting energy expenditure, fat oxidation, glucose oxidation, and plasma glucose, insulin and glycerol were measured before and after treatment. BaF-BO3 cells transfected with the hGH receptor were used to measure in vitro 125I-hGH receptor binding and cell proliferation. Both hGH and AOD significantly reduced body weight gain in obese mice. This was associated with increased in vivo fat oxidation and increased plasma glycerol levels (an index of lipolysis). Unlike hGH, however, AOD9604 did not induce hyperglycaemia or reduce insulin secretion. AOD9604 does not compete for the hGH receptor and nor does it induce cell proliferation, unlike hGH. Both hGH and its C-terminal fragment reduce body weight gain, increase fat oxidation, and stimulate lipolysis in obese mice, yet AOD9604 does not interact with the hGH receptor. Thus, the concept of hGH behaving as a pro-hormone is further confirmed. This data shows that fragments of hGH can act in a manner novel to traditional hGH-stimulated pathways.

2007Postepy higieny i medycyny doswiadczalnej (Online)

[Obesity: a review of currently used antiobesity drugs and new compounds in clinical development].

Review articlehumanPMID 17971763

This review summarizes data on currently used antiobesity drugs and new compounds under clinical development. Three antiobesity drugs are currently accepted for long-term use. Sibutramine is a noradrenaline and serotonin reuptake inhibitor which reduces body weight by about 4-5 kg but increases heart rate and arterial blood pressure. Orlistat is a gastrointestinal lipase inhibitor which results in mean weight loss by about 3 kg and reduces the incidence of type 2 diabetes in patients with impaired glucose tolerance; however, adverse gastrointestinal effects have been observed. Rimonabant is an endocannabinoid CB1 receptor antagonist which induces a 4-5 kg mean weight loss and improves glycemic and lipid profiles, but it induces anxiety and depressive disorders. Unfortunately, there are no data on the chronic administration of these drugs. Other drugs can induce weight loss, e.g. some antidepressants, antiseizure agents, and antidiabetic drugs. The moderate efficacy of currently used antiobesity drugs has led to an intense effort to identify new, safe antiobesity drugs with better therapeutic profiles. The new antiobesity drugs under clinical development include: 1) agents that affect neurotransmitters in the central nervous system, including noradrenaline and dopamine reuptake inhibitors (bupropion, radafaxine), selective 5HT2C receptor agonists (lorcaserin), and selective 5HT6 receptor antagonists, 2) agents that modulate the activity of neuropeptides influencing food intake, including leptin analogues, human ciliary neurotrophic factor (Axokine), neuropeptide Y antagonists, and melanine-concentrating hormone antagonists, 3) agents that affect the peripheral satiety signals and brain-gut axis, e.g. selective cholecystokinin receptor A agonists, PYY3-36, agents decreasing ghrelin activity, 4) thermogenic agents, e.g. selective beta3 receptor agonists and selective thyroid hormone receptor beta agonists, and 5) others, e.g. human growth hormone fragment (AOD9604) and gastrointestinal lipase inhibitor (cetilistat).

2006Obesity (Silver Spring, Md.)

Potential role of new therapies in modifying cardiovascular risk in overweight patients with metabolic risk factors.

Human trialhumanPMID 16931496

The serotonin, norepinephrine, dopamine, and endocannabinoid systems, as well as a host of other systems, mediate hunger and satiety signals. Weight loss agents that modulate appetite through pure central nervous system pathways (e.g., APD356, a selective serotonin receptor agonist) and peripheral signals to central nervous system pathways (e.g., cholecystokinin receptor agonists and ghrelin receptor antagonists) are in preclinical or early phase studies. Both devices and pharmacological compounds that facilitate weight loss and/or target multiple components of metabolic risk also are in development. One of the medications that has completed extensive phase III clinical trials and may become available in the foreseeable future is rimonabant, a selective cannabinoid 1-receptor antagonist. Drugs that improve adipose tissue function or fatty acid metabolism (e.g., AOD9604) also are in clinical trials. Some currently available medications may reduce metabolic complications without treating obesity per se (e.g., acipimox, pioglitazone). Surgically implanted gastric pacemaker systems that modulate vagus nerve activity and delay gastric emptying are under study.

2014Journal of pharmaceutical and biomedical analysis

Analytical approaches for the detection of emerging therapeutics and non-approved drugs in human doping controls.

Human (observational)humanPMID 24906629

The number and diversity of potentially performance-enhancing substances is continuously growing, fueled by new pharmaceutical developments but also by the inventiveness and, at the same time, unscrupulousness of black-market (designer) drug producers and providers. In terms of sports drug testing, this situation necessitates reactive as well as proactive research and expansion of the analytical armamentarium to ensure timely, adequate, and comprehensive doping controls. This review summarizes literature published over the past 5 years on new drug entities, discontinued therapeutics, and 'tailored' compounds classified as doping agents according to the regulations of the World Anti-Doping Agency, with particular attention to analytical strategies enabling their detection in human blood or urine. Among these compounds, low- and high-molecular mass substances of peptidic (e.g. modified insulin-like growth factor-1, TB-500, hematide/peginesatide, growth hormone releasing peptides, AOD-9604, etc.) and non-peptidic (selective androgen receptor modulators, hypoxia-inducible factor stabilizers, siRNA, S-107 and ARM036/aladorian, etc.) as well as inorganic (cobalt) nature are considered and discussed in terms of specific requirements originating from physicochemical properties, concentration levels, metabolism, and their amenability for chromatographic-mass spectrometric or alternative detection methods.

2005Methods and findings in experimental and clinical pharmacology

Gateways to clinical trials.

Human (observational)humanPMID 15834452

Gateways to Clinical Trials is a guide to the most recent clinical trials in current literature and congresses. The data in the following tables has been retrieved from the Clinical Trials Knowledge Area of Prous Science Integrity, the drug discovery and development portal, http://integrity. prous.com. This issue focuses on the following selection of drugs: ABX-IL-8, Acclaim, adalimumab, AGI-1067, alagebrium chloride, alemtuzumab, Alequel, Androgel, anti-IL-12 MAb, AOD-9604, aripiprazole, atomoxetine hydrochloride; Biphasic insulin aspart, bosentan, botulinum toxin type B, bovine lactoferrin, brivudine; Cantuzumab mertansine, CB-1954, CDB-4124, CEA-TRICOM, choriogonadotropin alfa, cilansetron, CpG-10101, CpG-7909, CTL-102, CTL-102/CB-1954; DAC:GRF, darbepoetin alfa, davanat-1, decitabine, del-1 Genemedicine, dexanabinol, dextofisopam, dnaJP1, dronedarone hydrochloride, dutasteride; Ecogramostim, eletriptan, emtricitabine, EPI-hNE-4, eplerenone, eplivanserin fumarate, erlotinib hydrochloride, ertapenem sodium, escitalopram oxalate, esomeprazole magnesium, etoricoxib, ezetimibe; Falecalcitriol, fingolimod hydrochloride; Gepirone hydrochloride; HBV-ISS, HSV-2 theracine, human insulin; Imatinib mesylate, Indiplon, insulin glargine, ISAtx-247; L612 HuMAb, levodopa/carbidopa/entacapone, lidocaine/prilocaine, LL-2113AD, lucinactant, LY-156735; Meclinertant, metelimumab, morphine hydrochloride, morphine-6-glucuronide; Natalizumab, nimotuzumab, NX-1207, NYVAC-HIV C; Omalizumab, onercept, osanetant; PABA, palosuran sulfate, parathyroid hormone (human recombinant), parecoxib sodium, PBI-1402, PCK-3145, peginterferon alfa-2a, peginterferon alfa-2b, peginterferon alfa-2b/ribavirin, pemetrexed disodium, pimecrolimus, PINC, pregabalin; Ramelteon, rasagiline mesilate, rasburicase, rimonabant hydrochloride, RO-0098557, rofecoxib, rosiglitazone maleate/metformin hydrochloride; Safinamide mesilate, SHL-749, sitaxsentan sodium, sparfosic acid, SprayGel, squalamine, St. John's Wort extract, synthetic human secretin; Taxus, telavancin hydrochloride, telithromycin, temoporfin, tenofovir disoproxil fumarate, tenofovir disoproxil fumarate/emtricitabine, teriparatide, testosterone gel, TG-1024, tirapazamine, travoprost, travoprost/timolol; Valdecoxib, valganciclovir hydrochloride, voriconazole; Ximelagatran.

2003Methods and findings in experimental and clinical pharmacology

Gateways to clinical trials.

Human (observational)humanPMID 14685303

Gateways to Clinical Trials is a guide to the most recent clinical trials in current literature and congresses. The data in the following tables has been retrieved from the Clinical Studies Knowledge Area of Prous Science Integrity, the drug discovery and development portal, http://integrity.prous.com. This issue focuses on the following selection of drugs: Abarelix, ABX-EGF, ademetionine, agomelatine, AMGN-0007, 9-aminocamptothecin, AN-9, anecortave acetate, anidulafungin, AOD-9604, apolizumab, apomate, L-arginine hydrochloride, arzoxifene hydrochloride; Bevacizumab, BP-897, BufferGel; Capravirine, carboxyamidotriazole, carnosine, CC-4047, CEP-701, cerivastatin sodium, clofarabine, conivaptan hydrochloride, CP-461, CS-003; Daptomycin, darifenacin, decitabine, deferasirox, duloxetine hydrochloride; Eberconazole, Ecyd, efalizumab, eglumegad hydrate, EMD-72000, (-)-epigallocatechin gallate, exatecan mesilate, exenatide; Fampridine, fenretinide, ferumoxtran-10; Gadofosveset sodium, garenoxacin mesilate, genistein, glutamine, GPI-15715; Hexyl insulin M2, human insulin, HYB-165; Indisulam, irofulven; KRN-5500, L-796568, laurocapram, lidocaine/prilocaine, lonafarnib, lotrafiban; Melagatran, melatonin, 2-methoxyestradiol, metreleptin, motexafin gadoliniu, motexafin lutetium; Natalizumab, nelarabine, NO-aspirin, NSC-683864; ONO-6126; Pemetrexed disodium, pexelizumab, pirfenidone, PncCRM9, polyglutamate paclitaxel, pramlintide acetate pregabalin, PRO-2000; Ragaglitazar, ramelteon, rasagiline mesilate, rDNA insulin, recombinant glucagon-like peptide-1 (7-36) amide, recombinant human parathyroid hormone (1-84), reolysin RG228, roflumilast, roxifiban acetate, RPI-4610, rubitecan; Safinamide mesilate, solifenacin succinate, SRL-172; T-138067, tafenoquine succinate, tecadenoson, TER-286, tesaglitazar, tetrathiomolybdate, tezosentan disodium, TheraCIM, tigecycline, tipifarnib, tolvaptan, trabectedin, tributyrin, trimegestone, troxacitabine; UCN-01, urokinase alfa; Vinflunine, viscum fraxini 2; Xcellerated T cells, ximelagatran.

2003Methods and findings in experimental and clinical pharmacology

Gateways to clinical trials.

Otherin vitroPMID 14571286

Gateways to Clinical Trials is a guide to the most recent clinical trials in current literature and congresses. The data in the following tables has been retrieved from the Clinical Studies Knowledge Area of Prous Science Integrity, the drug discovery and development portal, http://integrity.prous.com. This issue focuses on the following selection of drugs: Abetimus sodium, adefovir dipivoxil, AGI-1067, alefacept, alemtuzumab, ALVAC-p53, aminolevulinic acid hydrochloride, aminolevulinic acid methyl ester, Anti-CTLA-4 Mab, AOD-9604, apafant, aprinocarsen sodium, arsenic trioxide; Balaglitazone, BIM-23190, bimatoprost, bortezomib, bosentan, BR-1; Canertinib dihydrochloride, CDP-850, cevimeline hydrochloride, cinacalcet hydrochloride, clenoliximab, clevudine, CN-787; D-003, darusentan, deferasirox, desloratadine dexanabinol, duloxetine hydrochloride; E-5564, edaravone, efaproxiral sodium, elvucitabine emfilermin, EN-101, enfuvirtide, entecavir, epithalon, eplerenone, erlotinib hydrochloride, escitalopram oxalate, esomeprazole magnesium, eszopiclone, etilefrine pivalate hydrochloride etoricoxib, everolimus, exenatide; Fidarestat, fondaparinux sodium; Ganstigmine hydrochloride; Homoharringtonine, HuMax-IL-15, hyperimmune IVIG; Imatinib mesylate, IMC-1C11, Inhaled insulin, irofulven, iseganan hydrochloride, ISIS-14803, ISIS-5132, ivabradine hydrochloride; Keratinocyte growth factor; Lafutidine, lanthanum carbonate, LAS-34475, levocetirizine, liraglutide, LY-307161 SR; Magnesium sulfate, maribavir, melatonin, mycobacterium cell wall complex; NN-414, NO-aspirin, nociceptin, nolomirole hydrochloride; Olmesartan medoxomil oral insulin, ospemifene; PDX, perillyl alcohol, pimecrolimus, pitavastatin calcium, pramlintide acetate, prasterone, pregabalin, PRO-542, PV-701, pyrazoloacridine; R-744, ranelic acid distrontium salt, rasburicase, rDNA insulin, resiniferatoxin, reslizumab, ridogrel, riplizumab ropivacaine, rosuvastatin calcium, roxifiban acetate, ruboxistaurin mesilate hydrate; Satraplatin, Sch-58500, semaxanib, sitaxsentan sodium, SMP-114, SU-6668; Teriparatide, tetrathiomolybdate, tipifarnib, tolvaptan, travoprost, treprostinil sodium; Valdecoxib, valganciclovir hydrochloride, vardenafil hydrochloride hydrate, vatalanib succinate; Ximelagatran; Z-335, ziprasidone hydrochloride, zoledronic acid monohydrate, ZYC-00101.

2014Expert review of proteomics

Detecting peptidic drugs, drug candidates and analogs in sports doping: current status and future directions.

Human (observational)humanPMID 25382550

With the growing availability of mature systems and strategies in biotechnology and the continuously expanding knowledge of cellular processes and involved biomolecules, human sports drug testing has become a considerably complex field in the arena of analytical chemistry. Proving the exogenous origin of peptidic drugs and respective analogs at lowest concentration levels in biological specimens (commonly blood, serum and urine) of rather limited volume is required to pursue an action against cheating athletes. Therefore, approaches employing chromatographic-mass spectrometric, electrophoretic, immunological and combined test methods have been required and developed. These allow detecting the misuse of peptidic compounds of lower (such as growth hormone-releasing peptides, ARA-290, TB-500, AOD-9604, CJC-1295, desmopressin, luteinizing hormone-releasing hormones, synacthen, etc.), intermediate (e.g., insulins, IGF-1 and analogs, 'full-length' mechano growth factor, growth hormone, chorionic gonadotropin, erythropoietin, etc.) and higher (e.g., stamulumab) molecular mass with desired specificity and sensitivity. A gap between the technically possible detection and the day-to-day analytical practice, however, still needs to be closed.

2026The Analyst

Rapid and harmonized analytical workflow for the determination of peptidic and non-peptidic doping agents in dried and liquid blood matrices.

Recently, methods for detecting small peptides in dried blood spots have been published. These procedures typically involve multiple sample preparation steps, resulting in labor-intensive and costly workflows. In the present study, we report a fast, streamlined, and harmonized analytical workflow to detect 54 prohibited peptidic and non-peptidic compounds in dried blood spots, serum, and plasma. Sample preparation is based on a single microextraction step using 500 &#xb5;L of a methanol/water (8&#x2009;:&#x2009;2, v/v) mixture. Detection was performed using liquid chromatography coupled with high-resolution mass spectrometry. The validation results showed satisfactory performance with respect to selectivity (no interferences were detected at the retention times of the analytes), detection limits (0.05-1.25 ng mL-1), carry-over (no signals in the negative sample injected after the positive sample), matrix effect (5-33%), extraction yield (15-80%), and extract stability (the target analytes were stable for at least 72 h in the autosampler at 10 &#xb0;C). The method was successfully applied to samples containing sub-ng levels of ibutamoren, confirming that the analytical procedure presented in this study is fit for purpose within the doping-control framework. Stability studies showed that all compounds were stable (variation lower than 15%) for at least two months at -20 &#xb0;C in all the blood matrices considered. At 4 and 22 &#xb0;C, alexamorelin, AOD9604, buserelin, hGH 176-191, kisspeptin-10 and LHRH were extensively degraded after one week in serum and plasma, whereas BPC-157, TB500, vasopressin, lypressin, and terlipressin showed complete degradation only in serum. In contrast, in dried matrices all compounds remained detectable throughout the entire duration of the study, indicating that samples can be transported and stored under non-refrigerated conditions, thereby reducing costs.

2016Journal of separation science

Simplifying and expanding the screening for peptides <2 kDa by direct urine injection, liquid chromatography, and ion mobility mass spectrometry.

The analysis of low-molecular-mass peptides in doping controls has become a mandatory aspect in sports drug testing and, thus, the number of samples that has to be tested for these analytes has been steadily increasing. Several peptides <2 kDa with performance-enhancing properties are covered by the list of prohibited substances of the World Anti-Doping Agency including Desmopressin, LH-RH, Buserelin, Triptorelin, Leuprolide, GHRP-1, GHRP-2, GHRP-3, GHRP-4, GHRP-5,GHRP-6, Alexamorelin, Ipamorelin, Hexarelin, ARA-290, AOD-9604, TB-500 and Anamorelin. With the presented method employing direct urine injection into a liquid chromatograph followed by ion-mobility time-of-flight mass spectrometry, a facile, specific and sensitive assay for the aforementioned peptidic compounds is provided. The accomplished sensitivity allows for limits of detection between 50 and 500&#xa0;pg/mL and thus covers the minimum required performance level of 2 ng/mL accordingly. The method is precise (imprecision <20%) and linear in the estimated working range between 0 and 10 ng/mL. The stability of the peptides in urine was tested, and -20&#xb0;C was found to be the appropriate storage temperature for sports drug testing. Finally, proof-of-concept was shown by analysing elimination study urine samples collected from individuals having administered GHRP-6, GHRP-2, or LHRH.

Quick links (PubMed)

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  • PMID 14685303 2003 · Gateways to clinical trials.
  • PMID 14571286 2003 · Gateways to clinical trials.
  • PMID 25382550 2014 · Detecting peptidic drugs, drug candidates and analogs in sports doping:
  • PMID 42328738 2026 · Rapid and harmonized analytical workflow for the determination of peptid
  • PMID 24124033 2013 · AOD-9604 does not influence the WADA hGH isoform immunoassay.
  • PMID 26578461 2016 · Simplifying and expanding the screening for peptides <2 kDa by direct ur