Side-by-side · Research reference

DermorphinvsHGH Fragment 176-191

Side-by-side comparison across mechanism, dosage, evidence, side effects, administration, and stack synergies. Citations on every claim where available.

AAnimal-StrongHUMAN-REVIEWED20/47 cited

BAnimal-StrongHUMAN-REVIEWED28/59 cited

Dermorphin

Opioid Peptide · μ-Receptor Agonist · Research Only

~30×Morphine potency

μ-selectiveReceptor typeNegri 1992

D-Ala²Unique featureAmiche 1998

Research only · ICV / SC (animal models)

HGH Fragment 176-191

GH Fragment · Pre-Clinical

50%Weight gain reductionNg 2000

~26 minHalf-life (est.)

No IGF-1 ↑GH axis impact

SQ · IP (animal) · Oral (tested)

01Mechanism of Action

Parameter

Dermorphin

HGH Fragment 176-191

Primary target

μ-opioid receptors (central and peripheral)Negri 1992 Steel 2014

Beta-3 adrenergic receptors on adipocytesHeffernan 2001

Pathway

μ-receptor activation → G-protein coupling → adenylyl cyclase inhibition → neuronal hyperpolarization

Fragment → β3-AR upregulation → Enhanced lipolytic sensitivityHeffernan 2001

Downstream effect

Potent analgesia, reduced nociceptive signaling, opioid-mediated CNS and peripheral effects

Increased lipolysis and beta-3 AR mRNA expression without IGF-1 axis activation

Feedback intact?

N/A — exogenous opioid agonist

N/A — does not interact with GH/IGF-1 axis

Origin

Phyllomedusa sauvagei and P. bicolor frog skin — gene-encoded with natural D-amino acid incorporationAmiche 1998 Mignogna 1992

Synthetic peptide derived from hGH residues 176-191; AOD9604 includes N-terminal tyrosine (177-191)Cox 2015

Antibody development

Site-directed antibodies produced for detection and purificationCucumel 1996

Not reported in available studies

02Dosage Protocols

Parameter

Dermorphin

HGH Fragment 176-191

Legal status

Controlled substance in many jurisdictions · Research only

Not approved for human use.

—

Animal research (ICV)

Low nanomolar to picomolar range

Intracerebroventricular administration in rodent models.

—

Detection limit (doping)

5 pg/mL in equine plasma/urineSteel 2014

High-throughput LC-MS/MS screen developed for racing industry.

—

Duration of action

10–120 minutes (dose-dependent, intrathecal)

—

Evidence basis

Animal studies · In vitro assays

Animal studies only

Human toxicity

Kambô ritual (P. bicolor skin) — violent emesis, vasodilation, fluid shifts, ADH dysregulationTran 2025

—

Animal dose (oral)

—

500 mcg/kg body weightNg 2000

Obese Zucker rats, 19 days.

Animal dose (IP)

—

Not specified (14-day chronic administration)Heffernan 2001

Obese mice, daily IP injection.

Human equivalent dose

—

Not established — no published human RCTs

Frequency

—

Once daily (animal models)

Duration tested

—

14–19 daysHeffernan 2001 Ng 2000

Detection window

—

50 pg/mL LOD in urine; stable metabolite extends detectionCox 2015

WADA-banned; anti-doping testing available.

Oral bioavailability

—

Demonstrated efficacy in animal oral administrationNg 2000

Potential for oral therapeutic development.

03Metabolic / Fat Loss Evidence

Parameter

Dermorphin

HGH Fragment 176-191

Primary fat target

—

Adipose tissue (general) — beta-3 AR mediated lipolysisHeffernan 2001

Weight gain reduction

—

50% reduction vs control (15.8 ± 0.6 g vs 35.6 ± 0.8 g)Ng 2000

Obese Zucker rats, 19 days oral administration.

Body fat reduction

—

Significant decrease in body weight and body fat in obese mice (14 days)Heffernan 2001

Lipolytic activity

—

Increased adipose tissue lipolytic activityNg 2000

Direct measurement in treated animals.

Beta-3 AR expression

—

Upregulated β3-AR mRNA in obese mice to lean-comparable levelsHeffernan 2001

Insulin sensitivity

—

No adverse effect — euglycemic clamp confirmedNg 2000

Contrasts with intact hGH diabetogenic effects.

IGF-1 impact

—

No elevation — fragment does not activate GH/IGF-1 axis

Beta-3 AR dependency

—

Effect abolished in β3-AR knockout miceHeffernan 2001

Confirms β3-AR as primary mechanism.

Route of administration

—

Efficacy demonstrated via oral and IP routesNg 2000 Heffernan 2001

Human evidence

—

None published — pre-clinical only

04Side Effects & Safety

Parameter

Dermorphin

HGH Fragment 176-191

Opioid effects

Respiratory depression, sedation, euphoria, tolerance, dependence risk

—

CNS effects

Analgesia (high-affinity sites), catalepsy (low-affinity sites)Negri 1992

—

Kambô ritual toxicity

Violent emesis, vasodilation, profound fluid shifts, hyponatremia, ADH dysregulation, brain death (case report)Tran 2025

—

Peripheral effects

GI motility inhibition (ileum > vas deferens in vitro)Negri 1992

—

Receptor selectivity caveat

Two μ-receptor subtypes — differential behavioral effects (analgesia vs. catalepsy)Negri 1992

—

Proteolytic stability

Tyr³-Pro⁶ bond relatively unstable; endogenous enzymes may produce tetrapeptide fragmentsCucumel 1996

—

Insulin sensitivity

—

No adverse effects observed in euglycemic clamp (animal)Ng 2000

GH/IGF-1 axis

—

No activation — avoids diabetogenic effects of full GHNg 2000

Human safety data

—

Not available — no published human trials

WADA status

—

Banned as performance-enhancing drugCox 2015

Metabolic profile

—

Six metabolites identified; CRSVEGSCG most stableCox 2015

Detection window implications for doping control.

Absolute Contraindications

Dermorphin

·Human use — not approved by any regulatory authority
·Controlled substance status — possession illegal in many jurisdictions
·Known opioid hypersensitivity or respiratory compromise

HGH Fragment 176-191

·Competitive athletes (WADA-banned)Cox 2015

Relative Contraindications

Dermorphin

·Any context outside approved animal research protocols
·CNS depressant co-administration

HGH Fragment 176-191

·Absence of human safety data — experimental use only

05Administration Protocol

Parameter

Dermorphin

HGH Fragment 176-191

1. Legal and ethical framework

Dermorphin is a controlled substance in many jurisdictions and is not approved for human use. Possession, synthesis, or distribution may be illegal. Use is restricted to licensed research settings under institutional review.

Subcutaneous injection primary route in research context. Oral administration demonstrated efficacy in animal models at 500 mcg/kg.

2. Animal research protocols

In rodent models, intracerebroventricular (ICV) or intrathecal injection is used at nanomolar to picomolar concentrations. Subcutaneous administration also documented. All protocols require IACUC approval.

Once daily dosing used in animal studies. Timing not specified; GH-independent mechanism suggests flexibility.

3. Analytical detection

High-throughput LC-MS/MS screens developed for anti-doping programs detect dermorphin and 17 related peptides in equine and human urine/plasma at limits as low as 5 pg/mL.Steel 2014

Animal protocols: 14–19 days. Human duration not established — no published trials.

4. Kambô ritual (traditional use)

Application of Phyllomedusa bicolor skin secretions to superficial burns. Not recommended — associated with severe toxicity including violent emesis, hyponatremia, and documented case of brain death.Tran 2025

Lyophilized peptide storage per standard peptide protocols. Metabolite stability suggests refrigerated reconstituted solution viable.

5. Detection

—

Detectable in urine via SPE-LC-MS at 50 pg/mL LOD. Extended detection window via stable metabolite CRSVEGSCG.Cox 2015