A reader recently left an interesting
comment on my earlier post about telmisartan. They wrote that they had been
using Dihexa for a couple of months and had noticed new vocalizations and
unexpected progress with toilet training in their child. They also mentioned
another peptide, PEPITEM, which they had come across while reading about bone
metabolism and inflammation.
This comment prompted me to look more
closely at how several topics might intersect biologically: Dihexa, angiotensin
receptor blockers such as telmisartan, the peptide PEPITEM, and conditions like
Pitt-Hopkins syndrome.
What is a
peptide?
Peptides are short chains of amino
acids, the same building blocks that make up proteins. They act as signaling molecules in the body and regulate many biological
processes. Examples of natural peptide hormones include insulin and oxytocin.
Scientists often design synthetic
peptides to mimic or modify these natural signals. Some peptides have become successful medicines. A well-known example is
semaglutide, used to treat diabetes and obesity.
In recent years peptides have become
very popular in longevity and biohacking circles. This is partly because modern biology has discovered many new peptide signaling
systems. These regulate metabolism, immune responses, tissue repair, and brain
plasticity.
Another reason is that peptide
manufacturing has become much cheaper. Automated peptide synthesis now allows laboratories to produce peptides easily. As a result, some research peptides are now sold online.
Many of these compounds are marketed
as “research chemicals”. Examples often discussed online include BPC-157 and
Dihexa. These compounds originated in laboratory research.
However, most of them have not gone
through proper human clinical trials. Their long-term safety and effectiveness are therefore unknown.
Social media and podcasts have
amplified interest in these substances. This has created a large grey market for experimental peptide therapies.
Scientists remain cautious because
peptides can have strong biological effects. Problems can include uncertain purity, incorrect dosing, and lack of safety
data.
Despite these concerns, peptides
remain an important area of medical research. Many future medicines are likely to be peptide-based.
The reason is simple, biology uses
peptides as a major language of cellular communication. They control processes ranging from metabolism to immune function and brain
signaling.
This is why peptides sometimes appear in discussions of neurological conditions.
Many pathways involved in brain development and synaptic plasticity are
regulated by peptide signals.
Dihexa and the
angiotensin system
Dihexa was originally developed from
angiotensin IV, a fragment of angiotensin II that belongs to the
renin–angiotensin system. While this system is best known for regulating blood
pressure, it also has important roles in the brain.
In the 1990s researchers noticed that
angiotensin IV could improve learning and memory in animal experiments. This
led scientists to design molecules that could mimic these effects but cross the
blood–brain barrier and remain stable in the body. One of these molecules was
Dihexa.
Interestingly, Dihexa does not appear
to work primarily through classical angiotensin receptors. Instead it activates
the HGF/MET pathway, which regulates neuronal growth, dendritic branching and
synapse formation. In laboratory experiments Dihexa has shown very strong
synaptogenic effects, meaning it can promote the formation of new synaptic
connections between neurons.
This is why it sometimes appears in
discussions of cognitive enhancement or experimental neurological treatments.
However, it is important to stress that Dihexa has never undergone proper human
clinical trials, so its safety profile and long-term effects remain unknown. It
is somewhat surprising that it is sold online as a “supplement” or research
compound, since it is really a laboratory-designed molecule rather than a
traditional dietary supplement.
BDNF and synaptic
plasticity
Some autism clinicians have
experimented with approaches intended to increase brain levels of BDNF
(brain-derived neurotrophic factor), a key regulator of synaptic plasticity and
neuronal survival.
BDNF promotes dendritic growth,
synapse formation and learning-related plasticity. In many ways it is one of
the brain’s central “growth signals”. Dihexa became famous in neuroscience
circles partly because some laboratory studies suggested it could stimulate
synapse formation even more strongly than BDNF, although those findings were
mainly from cell culture experiments.
The two pathways are different but
converge on similar intracellular signaling networks that regulate synaptic
growth.
Interestingly, one of the most
reliable ways to increase BDNF is not a drug at all but physical exercise.
Exercise stimulates BDNF production in the hippocampus through a combination of
increased neuronal activity, metabolic signaling and muscle-derived molecules
such as irisin. High-impact activity may also stimulate endocrine signals from
bone, including osteocalcin, which can influence brain function.
Angiotensin
receptor blockers and the brain
The drugs discussed in some of my
previous articles—telmisartan, candesartan and losartan—belong to the class of
angiotensin receptor blockers (ARBs). They block the AT1 receptor, which is
activated by angiotensin II.
Although these drugs are prescribed
for hypertension, the brain has its own local renin–angiotensin system. In the
central nervous system angiotensin signaling influences neuroinflammation,
oxidative stress, cerebral blood flow and neuronal excitability.
Blocking the AT1 receptor tends to
reduce inflammatory signaling and shift the balance toward protective pathways.
Telmisartan is particularly
interesting because it also activates the nuclear receptor PPAR-gamma, which
influences mitochondrial function, metabolic signaling and inflammation in
neurons.
Candesartan is often considered one of
the more brain-penetrant ARBs and has shown neuroprotective effects in some
experimental models.
Losartan has attracted attention
because it can reduce excessive TGF-beta signaling, a pathway involved in
inflammation and tissue remodeling.
Telmisartan might theoretically be
more relevant in autism where metabolic stress and inflammation dominate
(because of PPAR-γ activation). Losartan might be more relevant where excessive
tissue-remodeling or TGF-β signaling plays a role. In the brain, tissue
remodeling involves:
- synapse formation and elimination
- growth of dendrites and axons
- restructuring of the extracellular matrix
around neurons
- activation of glial cells
Losartan is used to treat Marfan
syndrome. Marfan syndrome is a systemic connective-tissue disorder that affects
many parts of the body, particularly the heart.
Some studies have reported altered
TGF-β signaling in certain forms of autism, suggesting that immune and
tissue-remodeling pathways may contribute to aspects of neurodevelopment in at
least some individuals. Losartan could theoretically influence these biological
processes.
These mechanisms do not directly
overlap with Dihexa’s synapse-forming activity, but they may influence the
overall biological environment in the brain by reducing inflammatory and
metabolic stress.
The peptide
PEPITEM
The reader also mentioned PEPITEM,
short for “PEPtide Inhibitor of Trans-Endothelial Migration”.
PEPITEM regulates the movement of
immune cells across blood vessel walls. In simple terms, it helps control
whether inflammatory immune cells leave the bloodstream and enter tissues.
This pathway has been studied mainly
in inflammatory diseases. By limiting immune-cell migration, the PEPITEM
pathway can reduce tissue inflammation.
Interestingly, the same pathway also
influences bone metabolism because immune signaling strongly affects osteoclast
activity and bone resorption.
Why bone biology
keeps appearing
One surprising theme linking these
topics is the intersection between inflammation, bone metabolism and the
renin–angiotensin system.
Angiotensin II can stimulate
osteoclast activity and promote bone resorption. Blocking the AT1 receptor with
ARBs may therefore modestly reduce inflammatory bone loss. Some observational
studies have suggested that ARB use may be associated with slightly higher bone
density or lower fracture risk.
Given how closely immune signaling and
bone metabolism interact, it is not surprising that peptides affecting
immune-cell trafficking, like PEPITEM, also influence bone remodeling pathways.
Pitt-Hopkins
syndrome as an example
Pitt-Hopkins syndrome is caused by
mutations in the transcription factor TCF4. This gene regulates many downstream
processes involved in neuronal development, synaptic maturation and network
formation.
In experimental models of Pitt-Hopkins
and related neurodevelopmental disorders, researchers often observe
abnormalities in synaptic development and neuronal connectivity.
Because of this, some therapeutic
ideas have focused on pathways that influence synaptic plasticity, neuronal
growth or inflammatory signaling.
The HGF/MET pathway activated by
Dihexa is one such pathway. The MET gene has also been linked to autism
genetics in several studies, and reduced MET signaling has been associated with
altered cortical connectivity.
This does not mean that Dihexa is a
treatment for Pitt-Hopkins syndrome or autism, but it is certainly plausible.
We saw in previous posts that autism can be broadly divided in hypo/hyper (too little/much) active pro-growth signaling pathways. Pitt Hopkins would be in the hypo category, so increasing activity should be beneficial.
The unknown issue with Dihexa is that it has not be tested thoroughly in humans, so long term use might not be wise, particularly in older people.
The totally safe way to increase pro-growth signaling is via daily aerobic exercise, which comes up again in the next post, which looks at translating recent Alzheimer's research to autism.
A broader pattern
What the reader’s comment illustrates
is something that appears frequently in biomedical research, apparently
unrelated compounds often converge on a small number of biological control
systems.
In this case we see several different
layers of regulation:
– the renin–angiotensin system
influencing inflammation and metabolic signaling
– growth factor pathways such as HGF/MET and BDNF regulating synapse formation
– immune trafficking pathways such as PEPITEM controlling inflammatory cell
migration
– transcriptional regulators such as TCF4 governing neuronal development
Each operates at a different level,
but they all ultimately influence how neurons grow, connect and function.
This does not mean that compounds like
Dihexa or peptides such as PEPITEM will become treatments for neurological
conditions. Most remain at a very early stage of research.
But it does highlight how discoveries
in cardiovascular biology, immunology, bone metabolism and neuroscience
increasingly intersect.
Conclusion
Dihexa and telmisartan start from the same hormonal system but act very differently:
- Dihexa directly stimulates synapse
formation through growth-factor signaling.
- Telmisartan reduces inflammation and
metabolic stress that may impair neuronal function.
The overlap lies mainly in their potential
downstream effects on neuronal plasticity, not in their primary mechanism of
action.
In the case of Pitt Hopkins syndrome
both might be potentially beneficial, although through very different
mechanisms, but no clinical evidence exists.
Dihexa acts by activating the HGF/MET
pathway, which promotes synapse formation, dendritic growth and neuronal
plasticity. Since Pitt-Hopkins syndrome involves impaired neuronal network
development caused by mutations in the TCF4 transcription factor, pathways that
enhance synaptic growth should attract scientific interest.
Telmisartan works in a different way.
By blocking the AT1 receptor of the renin–angiotensin system it reduces
inflammatory signaling and oxidative stress, and it also activates the nuclear
receptor PPAR-γ, which influences mitochondrial metabolism and cellular stress
responses. These effects could potentially improve the cellular environment in
which neurons function.
In simple terms, Dihexa attempts to
directly stimulate synapse formation, whereas telmisartan may reduce biological
stresses that interfere with normal neuronal signaling.
Both approaches therefore touch on
biological processes that are relevant to brain development and plasticity.
Dihexa is used by some autism clinicians in the US.
