🧪 Why New Antifungal Trials Start with Invasive Aspergillosis

When you hear about promising new antifungal medicines such as Olorofim or Fosmanogepix, you may wonder why the first studies always seem to involve people with invasive aspergillosis — not those with chronic pulmonary aspergillosis (CPA) or allergic bronchopulmonary aspergillosis (ABPA).

It might seem unfair, especially when chronic forms of aspergillosis are so common and long-lasting.
But there are good reasons why research has to begin with invasive disease.

Here’s how it works — and why it’s still good news for everyone living with aspergillosis.

⚠️ 1. Invasive Aspergillosis Is the Most Dangerous Form

Invasive aspergillosis happens when Aspergillus spreads deep into the lungs or bloodstream, usually in people with a very weak immune system — for example, after chemotherapy, transplant, or high-dose steroid use.

Without prompt treatment, it can be fatal within days or weeks.
Because it is so serious, regulators such as the MHRA (UK), EMA (Europe) and FDA (USA) allow new drugs for invasive infections to be tested and reviewed much faster than they would for less urgent diseases.

This approach means that if a new antifungal proves helpful and safe, it can reach patients in greatest need more quickly — often saving lives while also building the data needed for later studies in other conditions.

📈 2. It’s Easier to Measure Whether the Drug Works

For invasive disease, the goal is very clear:

The infection either clears up, or it doesn’t.

That makes the results of a study straightforward to interpret.

With chronic or allergic aspergillosis, improvement takes much longer to measure:

  • Scans may take months to show change,

  • Symptoms can fluctuate naturally, and

  • Other lung problems (like COPD or bronchiectasis) can confuse the results.

So trials in chronic disease need larger patient numbers and longer follow-up, which are expensive and take years. Starting with invasive aspergillosis lets researchers get the essential safety and efficacy answers first.

🧾 3. The Regulatory Framework Focuses on Invasive Disease

Drug-approval rules for antifungals were originally designed for the most life-threatening infections.
Official guidance documents — from the EMA, FDA and others — describe exactly how to test new drugs for invasive fungal infections, but there are no formal international standards yet for chronic or allergic aspergillosis.

That means developers start where the rules are clear — and then adapt once regulators, researchers, and clinicians agree on what a “successful outcome” looks like for chronic disease.

⚖️ 4. Safety and Ethics Come First

When a new antifungal is in early testing, doctors don’t yet know all its side-effects or how it behaves during long-term use.
For ethical reasons, it’s safer to begin in patients with very few other treatment options, where the potential benefit outweighs the risk.

As safety data builds up — including how the medicine interacts with other drugs — it becomes safer to test in people with more stable chronic conditions such as CPA.

🩺 5. Once Proven Safe, Use Can Expand

Once a drug like Olorofim or Fosmanogepix:

  • works well in invasive aspergillosis,

  • has solid safety data, and

  • earns its first licence,

the manufacturer and research partners (such as the National Aspergillosis Centre) can propose new studies in CPA or other forms of aspergillosis.

By then, regulators already know the drug’s risk profile, dosing, and monitoring needs — so further approvals for chronic disease can move faster.

🧩 In Summary

Reason Why invasive aspergillosis comes first
Urgency It’s the most life-threatening form, so ethics allow faster testing
Clear results Success or failure can be measured more easily
Existing standards Regulatory guidance already written for invasive disease
Safety first Starts with people who have no other treatment
Builds the base Data from invasive disease supports later CPA/ABPA trials

🌱 Looking Ahead

Starting with invasive aspergillosis is a gateway, not a dead-end.
Every study adds vital knowledge about how these new antifungals work, how safe they are, and which patients might benefit most.

Once enough evidence exists, clinical trials can — and almost certainly will — expand to include chronic pulmonary aspergillosis (CPA) and possibly even allergic forms of the disease.

So while the research focus may begin with the most critical cases, the progress made there ultimately helps everyone living with aspergillosis.

by GAtherton

🩺 Why New Antifungal Medicines Aren’t for Everyone (Yet)

When new medicines are announced, it’s natural to wonder:

“If they’re better than what we already have, why can’t everyone start using them straight away?”

Two new antifungal drugs — Olorofim and Fosmanogepix — are generating real excitement because they work in completely new ways and could help people whose fungal infections no longer respond to existing treatments.

But before any new drug becomes widely available, it must go through a careful process to make sure it’s safe, effective, affordable, and used in the right patients. Here’s why most people with aspergillosis will still be treated with existing antifungal medicines for now.

🧪 1. They’re Still Being Tested

Olorofim and Fosmanogepix are still classed as investigational medicines.
That means they have shown promise in early studies — especially for severe or drug-resistant infections — but they are not yet approved for general medical use.

Regulators such as the MHRA (UK), EMA (Europe), and FDA (USA) require large, carefully controlled studies to confirm:

  • that the drugs are safe for different types of patients,

  • that they work as well as or better than existing treatments, and

  • that the benefits clearly outweigh any risks.

Until that evidence is complete, they can only be prescribed within clinical trials or under special compassionate-use programmes at specialist hospitals.

💨 2. Different Types of Aspergillosis Need Different Treatments

Aspergillosis isn’t one single disease. It includes:

  • Invasive aspergillosis, a dangerous infection in people with weak immune systems.

  • Chronic pulmonary aspergillosis (CPA), a long-term infection in people with lung damage.

  • Allergic bronchopulmonary aspergillosis (ABPA), an allergic reaction rather than a true infection.

The new antifungals are currently being tested only for invasive aspergillosis — the most severe form.
They haven’t yet been studied in chronic or allergic forms like CPA or ABPA, so we don’t yet know if they would work or be safe for those conditions.

💊 3. Current Medicines Still Work Well for Most Patients

Existing antifungal drugs such as itraconazole, voriconazole, posaconazole, and isavuconazole remain effective for most people with aspergillosis.

Doctors already know:

  • how to monitor their levels in the blood,

  • how to manage side-effects, and

  • how to combine them safely with other medicines.

New drugs can bring new possibilities — but they can also bring unknown side-effects or interactions. Doctors need strong, long-term evidence before changing large numbers of patients to new treatments.

💷 4. Cost and Access Take Time

Developing antifungal drugs takes years and costs millions of pounds.
When a new medicine is finally approved, it is often very expensive at first.

In the UK, every new treatment must go through NICE (the National Institute for Health and Care Excellence).
NICE checks:

  • how well it works,

  • how safe it is, and

  • whether the NHS can afford to provide it fairly to all who need it.

Only once NICE recommends a drug can NHS England fund it for routine use — and even then, it may be limited to certain hospitals or patient groups at first.

⚖️ 5. A Step-by-Step Approach Keeps Patients Safe

New medicines are introduced gradually — starting with people who have no other treatment options.
If they prove safe, effective, and affordable in that group, their use can be expanded step by step to include more patients and other forms of disease.

This careful rollout protects patients from unexpected risks and helps prevent early resistance, so the drugs stay effective for longer.

🧭 6. Who Decides When a New Antifungal Can Be Used for CPA?

Bringing a new antifungal from its first approval to wider use in chronic diseases like CPA involves several levels of decision-making:

1️⃣ The Manufacturer

Companies such as Shionogi Europe (Olorofim) or Basilea/Pfizer (Fosmanogepix) design the trials and decide which conditions to test first — usually the most life-threatening ones.
If early results are good, they can plan new studies for CPA or other chronic lung infections.

2️⃣ Clinical Researchers and Specialist Centres

Centres such as the National Aspergillosis Centre (NAC) collect real-world data from patients who receive these drugs through compassionate-use programmes.
If several patients with CPA improve, these results may encourage formal CPA-specific trials.

3️⃣ Regulatory Authorities

Bodies such as the MHRA (UK), EMA (Europe), or FDA (USA) decide which diseases a drug can officially be marketed for.
To add CPA as a licensed use, the company must submit:

  • new clinical trial data,

  • long-term safety information, and

  • a formal request to extend the drug’s licence.

Until that happens, doctors can only prescribe it for CPA off-label — usually within strict hospital governance systems.

4️⃣ NICE and NHS England

Even after regulatory approval, NICE must review cost and benefit before the NHS can fund the drug for CPA.
Without a positive NICE recommendation, it can’t be routinely prescribed in the UK.

5️⃣ Specialist Clinical Networks

Finally, once approved and funded, expert groups like the NAC and national respiratory networks decide how and when the drug should be used — for example:

  • only for patients with azole-resistant CPA,

  • after all standard options have failed, and

  • with careful monitoring.

This information is then built into national and local treatment guidelines.

🔄 Example Pathway: Olorofim’s Future Use for CPA

Stage Who acts What happens
1️⃣ Shionogi Gains approval for invasive aspergillosis
2️⃣ NAC & academic partners Report successful CPA case studies
3️⃣ Shionogi + NAC Launch a formal CPA clinical trial
4️⃣ MHRA / EMA Extend licence to include CPA
5️⃣ NICE Reviews cost-effectiveness for CPA
6️⃣ NHS England Approves CPA use in NHS centres

🩸 In Summary

Reason Why we can’t all switch now
Still in trials Not yet fully approved for use
Different diseases Only tested for invasive aspergillosis so far
Known vs unknown Established drugs work well for most people
Cost and access NHS approval and funding take time
Safe rollout New drugs introduced step-by-step

🌱 Looking Ahead

Both Olorofim and Fosmanogepix represent the most promising antifungal advances in decades.
If they continue to perform well in trials, they could become vital options for people whose infections no longer respond to standard medicines — and, in time, for chronic conditions like chronic pulmonary aspergillosis (CPA).

For now, the safest and most effective approach remains to use proven antifungals under expert supervision, while keeping a close watch on these exciting new developments.

by GAtherton

🌿 New Antifungal Medicines on the Horizon: Olorofim and Fosmanogepix

For many years, doctors have relied on the same small group of antifungal drugs — mainly azoles (like itraconazole and voriconazole), amphotericin, and echinocandins. These have saved lives, but some fungi are becoming resistant, and some people can’t tolerate them because of side-effects or drug interactions.

Two completely new antifungal medicines — Olorofim and Fosmanogepix — are now in the final stages of research. They work in new ways and could help patients whose infections no longer respond to current treatments.

🧬 Olorofim (by F2G Ltd, UK)

How it works:
Olorofim blocks a vital process that fungi need to make DNA. It belongs to a brand-new group called orotomides, and works very differently from other antifungals.

Which infections it targets first:

  • The first planned use will be for people with invasive mould infections (for example, Aspergillus fumigatus and some rare moulds) when existing medicines don’t work or can’t be used.

  • It is especially promising for azole-resistant Aspergillus, which is becoming more common.

How it might help in the future:
Although early studies are focused on severe infections in people with weak immune systems, Olorofim has also shown good results in some patients with chronic pulmonary aspergillosis (CPA) who could not take azoles.
Once it is licensed, hospitals such as the National Aspergillosis Centre may be able to use it for difficult or resistant cases of CPA on a specialist-approval basis.

When it might be available:
F2G has completed late-stage studies and is preparing for regulatory approval.
If all goes well, Olorofim could be available around 2026–2027 in some countries, with the UK likely to follow once it is approved and adopted by the NHS.

⚗️ Fosmanogepix (by Basilea and Pfizer)

How it works:
Fosmanogepix (converted in the body to manogepix) blocks the fungus from making a protective coating around its cell surface. This prevents it from growing and spreading. It belongs to another new group of antifungal drugs.

Which infections it targets first:

  • The first major study is for Candida bloodstream infections (candidemia) and other serious yeast infections.

  • A second study focuses on invasive mould infections, including aspergillosis, in patients with few treatment options.

How it might help in the future:
Once approved for invasive infections, Fosmanogepix could later be tested in longer-term or chronic lung infections, such as CPA, if it proves safe for long-term use.

When it might be available:

  • The first approval (for Candida) may come around 2027.

  • The aspergillosis trial is still running and not expected to finish before 2028–2029, so that indication will follow later.

🩺 What This Means for People with Aspergillosis

Drug New or existing? First use likely for Could later help with When available (approx.)
Olorofim New class (orotomide) Invasive Aspergillus and resistant moulds Difficult or resistant cases of chronic pulmonary aspergillosis (CPA) 2026–2027
Fosmanogepix New class (Gwt1 inhibitor) Candida bloodstream infections Invasive mould infections, possibly CPA later 2027–2029

🧩 In summary

  • These two drugs represent the first completely new antifungal classes in decades.

  • They are being tested mainly for life-threatening fungal infections where current medicines fail.

  • Once approved, they may offer new options for people with resistant or difficult-to-treat forms of aspergillosis, including some patients with CPA.

  • They are not yet available on prescription, but progress looks very promising.

by GAtherton

Understanding Risk from Aspergillosis — and What’s Improving

🧫 How risky is aspergillosis?

The outlook for people with aspergillosis has improved dramatically in the past two decades.
Two things have changed that make a huge difference:

  1. We diagnose it earlier.
    Better scans, blood tests (like galactomannan and PCR), and greater awareness mean the infection or allergic reaction is recognised much sooner.

  2. We treat it better.
    Modern antifungal medicines, steroid-sparing biologics, and specialist clinics have all transformed care and monitoring.

⚖️ Risk of death — managed vs. unmanaged

Type of Aspergillosis If well managed If unmanaged or poorly treated
Allergic (ABPA) Survival > 95 % About 90 % (may progress to chronic lung damage)
Chronic (CPA) 5-year survival ≈ 80–90 % 5-year survival ≈ 50 %
Invasive (IA) 5-year survival ≈ 50–70 % < 20 % (often fatal if untreated)

Across all forms of aspergillosis, the risk of death has fallen by roughly 50 % since the early 2000s.

💊 What’s driven this improvement

  • New antifungal drugs — triazoles (itraconazole, voriconazole, posaconazole, isavuconazole) now form the backbone of long-term therapy.

  • Rapid diagnosis — galactomannan, PCR, and CT scanning detect infection days earlier than before.

  • Improved hospital and ICU care — faster recognition and better ventilation strategies save lives in invasive cases.

  • Specialist clinics and monitoring — regular blood tests, imaging, and drug-level checks prevent deterioration and drug toxicity.

  • Biologic therapies — agents that target allergic inflammation (like anti-IgE or anti-IL-5 biologics) help reduce steroid use and preserve lung function.

🚀 What could make outcomes even better

Researchers and clinicians are optimistic about the next decade.
Future advances are already on the horizon:

Future area How it helps
Next-generation antifungalsOlorofim, Fosmanogepix Active against azole-resistant strains and safer for long-term use
Combination or personalised therapy Matching the right drug and dose to each patient’s response pattern
Routine antifungal-resistance testing Prevents treatment failure by identifying resistant Aspergillus early
Rapid home or bedside testing Detects infection flare-ups before symptoms become severe
Improved imaging and AI-supported analysis Spots fungal cavities or airway changes at an earlier, reversible stage
Global stewardship of agricultural azoles Reduces environmental resistance by limiting unnecessary fungicide use
Patient self-monitoring and digital follow-up Enables early reporting of symptoms and better long-term adherence

⚠️ Potential barriers to further progress

Even with all these advances, several important challenges could slow improvement if left unaddressed:

Barrier Why it matters
Antifungal resistance Aspergillus fumigatus is developing resistance to azoles used both in medicine and agriculture. Resistant strains can make first-line treatment fail unless resistance testing is done.
Delayed or missed diagnosis Symptoms often mimic other lung conditions. Late recognition allows infection or inflammation to cause irreversible damage.
Limited access to specialist care Some regions lack experienced clinicians, diagnostic testing, or antifungal drug availability, increasing global inequality in outcomes.
Drug toxicity and interactions Long-term antifungal therapy can affect the liver or interfere with other medicines if not closely monitored.
Environmental change Warmer, wetter climates and increased composting or construction may raise Aspergillus exposure for vulnerable people.
Healthcare strain and cost Long-term follow-up, monitoring, and expensive new drugs may challenge already stretched healthcare systems.

Each of these barriers needs attention through research, public health policy, and education to ensure the gains of the last 20 years continue.

❤️ The key message

Aspergillosis is still a serious disease, but its outlook is far better than it used to be.
With modern antifungals, biologics, and regular monitoring, most people live many years — and new treatments promise even better results.

Patients can help by:

  • Reporting new symptoms early.

  • Keeping up with regular blood and imaging checks.

  • Asking about resistance testing and treatment options.

  • Staying informed about new drugs and trials.

🌅 A hopeful future

In just twenty years, deaths from aspergillosis have halved.
If we continue improving diagnosis, drug development, and resistance control, survival will rise even higher — turning aspergillosis from a life-threatening infection into a long-term but manageable condition for most people.

by GAtherton

🫁 Understanding Chronic Cough in Aspergillosis

What the latest British Thoracic Society statement means for you

🌬️ Why This Matters

If you live with aspergillosis, Allergic Bronchopulmonary Aspergillosis (ABPA), or bronchiectasis, coughing can dominate your life. It’s tiring, painful, and socially awkward — especially when people assume it means infection.

Doctors used to see cough as just a symptom of another problem, but the British Thoracic Society (BTS) Clinical Statement on Chronic Cough in Adults (2023) recognises something new:

For many people, a cough can become a condition in its own right — caused by airway and nerve hypersensitivity, not just infection.

This matters for aspergillosis patients because fungal allergy and inflammation make the airways especially sensitive.

💡 What Is “Chronic Cough”?

A chronic cough is one lasting eight weeks or more.
It may be:

  • Dry – little or no mucus

  • Productive – thick sputum (common in bronchiectasis or chronic aspergillosis)

  • Triggered by dust, cold air, perfume, or strong scents

For people with aspergillosis, several overlapping causes may exist:

  • Fungal colonisation or infection

  • Allergic inflammation (ABPA)

  • Bronchiectasis and mucus retention

  • Reflux or post-nasal drip

  • Nerve hypersensitivity

This is why one treatment rarely fixes everything — different “treatable traits” must be addressed together.

🧬 Why It Happens

1️⃣ The Hypersensitive Cough Reflex

People with aspergillosis often develop overactive airway nerves — so normal irritants like dust, scent, or cold air trigger coughing fits.

This “cough reflex hypersensitivity” happens because:

  • Ongoing inflammation damages the airway lining.

  • Nerve endings in the throat and lungs become over-responsive.

  • Even mild triggers set off powerful reflexes.

This is a real physiological process, not psychological.
It’s why cough can continue even when infection is under control.

2️⃣ Treatable Traits – Finding the Real Drivers

Treatable Trait What It Means What Helps
Airway infection or colonisation Persistent fungi or bacteria Antifungal or antibiotic therapy, sputum tests
Allergic inflammation ABPA or asthma-type airway swelling Corticosteroids, biologics (e.g., mepolizumab, benralizumab)
Cough reflex hypersensitivity Overactive airway nerves Speech therapy, nerve-modulating medication
Airway clearance problems Mucus that’s hard to shift Physiotherapy, saline or mucolytic therapy
Reflux or postnasal drip Acid or sinus drainage irritation Reflux management, ENT care

Identifying these traits helps your clinician personalise treatment.

💊 Medications That Can Cause or Worsen Cough

The BTS statement highlights that some medicines can trigger or amplify chronic cough — especially in people with already-sensitive lungs.

🔹 ACE Inhibitors (Blood pressure or heart disease)

Examples: Ramipril, Lisinopril, Enalapril, Perindopril

  • Can cause a dry, tickly cough due to bradykinin build-up.

  • Happens in ~1 in 5 users, sometimes months after starting.

  • GP can switch to a similar drug (ARB – e.g., losartan) that doesn’t cause cough.

🔹 Beta Blockers (Heart or migraine medicines)

Examples: Atenolol, Propranolol, Bisoprolol

  • May tighten airways, worsening wheeze or cough.

  • Safer “lung-selective” versions exist but should still be monitored.

🔹 Inhalers

Examples: Fluticasone, Budesonide, Salbutamol

  • Can irritate the throat if used without a spacer or if technique is poor.

  • Always rinse or gargle after use, and ask your pharmacist to review inhaler technique.

🔹 Antifungal or Reflux Medicines

  • Antifungals (itraconazole, voriconazole) don’t directly cause cough, but reflux or nausea can trigger coughing indirectly.

  • PPIs (omeprazole, lansoprazole) usually help reflux-related cough, but long-term use should be reviewed regularly.

🔹 Other Drugs

  • Amiodarone, methotrexate, and some biologics can rarely cause cough due to lung inflammation.

  • Nasal sprays or lozenges with menthol/alcohol may irritate already-sensitive airways.

💬 If you suspect a medicine is contributing, don’t stop it suddenly — speak to your doctor or pharmacist first.
They can review interactions using the
👉 BNF Interactions Checker – NICE Medicines Guidance.

🔍 How Doctors Assess Chronic Cough

BTS recommends a structured pathway:

  1. Basic tests: chest X-ray, spirometry, bloods (eosinophils, IgE), FeNO if available.

  2. Further tests: CT scan, allergy or sputum studies if initial tests are abnormal.

  3. Trait-based review: identifying overlapping issues — fungal, allergic, nerve-related, or reflux-related.

  4. Specialist referral: to a Cough Clinic or Aspergillosis Centre if symptoms persist.

🧴 Pharmacists: Your Safety Specialists

Pharmacists — hospital or community — are crucial for managing long-term cough and medication safety:

  • Check for cough-inducing drugs or interactions.

  • Advise on best timing for antifungal and steroid doses.

  • Help switch to fragrance-free personal or cleaning products.

  • Liaise with your GP and consultant to fine-tune treatment.

🧭 Regular medication reviews every few months can prevent small problems becoming major triggers.

💬 How It Feels — and Why It’s Misunderstood

People with aspergillosis often describe:

“A tickle that turns into a spasm I can’t stop.”
“People think I’m ill, but it’s just the air or perfume.”

This happens because your airway nerves and immune cells are already primed.
Coughing doesn’t mean you’re infectious — it’s your body’s protective reflex in overdrive.

🩺 What Helps Most

  • Optimise your aspergillosis and ABPA treatment.

  • Cough-control physiotherapy or speech therapy for nerve-related cough.

  • Airway clearance techniques for mucus.

  • Identify and avoid irritants: perfume, smoke, strong detergents, cold air.

  • Ask about biologics if inflammation remains active despite steroids.

  • Use nerve-modulating medicines only under specialist advice.

🧘 Emotional Health Matters Too

Living with a chronic cough can cause anxiety, embarrassment, and isolation.
Support from counsellors, CBT therapists, or patient groups helps manage this stress — and can actually reduce cough frequency through better relaxation and breathing control.

🌱 Key Takeaway

Chronic cough in aspergillosis isn’t “just a symptom” — it’s often a mix of airway inflammation, fungal allergy, nerve hypersensitivity, and sometimes side effects of medicines.

The good news is that every contributing factor is treatable once identified — and cough can improve significantly with the right combination of medical, physical, and environmental care.

🔗 Trusted Resources

by GAtherton

🧬 Article 2: When Microbes Turn Hostile – The Evolutionary Pressures Behind Infection

Subtitle: Why stable colonisation sometimes shifts into active disease

Introduction

If microbes can live quietly in the lungs for years, why do they sometimes turn aggressive?
Evolutionary biology and microbiome research show that infection often develops because of environmental pressures — not by design, but as a by-product of survival in a changing ecosystem.

1. Antibiotic Pressure

Repeated antibiotic courses kill sensitive strains and leave behind resistant survivors.
These survivors often produce thicker biofilms and inflammatory molecules, which protect them but also damage airway tissue.
Over time, this selection creates harder-to-treat, more inflammatory strains.

2. Nutrient Competition

Airways are crowded ecosystems.
When nutrients run low, microbes compete by releasing toxins, proteases, and iron-scavenging molecules.
These harm competitors — and incidentally harm the lung.

3. Biofilms and Mutation

Within biofilms, bacteria and fungi evolve quickly.
Mutations can accumulate, producing hypermutator strains that are well adapted to chronic survival but also more inflammatory.

4. Host Factors

Changes in the body — reduced immunity, steroid use, diabetes, or viral infections — relax immune control.
Organisms that were previously contained can now proliferate.
Similarly, damaged or scarred airways provide sheltered niches where microbes thrive.

5. Microbiome Collapse

The healthy lung microbiome helps regulate inflammation and suppress invaders.
When broad antibiotics or infections reduce diversity, opportunists like Pseudomonas or Aspergillus can expand unchecked.

6. Collateral Damage, Not Intent

Most microbes don’t “want” to be pathogenic — they’re simply adapting to survive.
Their survival strategies (biofilms, enzymes, toxins) cause collateral damage to airway tissue.
So, pathogenicity is often an accidental consequence of survival pressure.

7. Cycles of Stability and Flare-Ups

Chronic airway diseases often follow repeating cycles:

  1. Stable colonisation – coexistence with minimal inflammation

  2. Disruption – antibiotics, viral infection, or new strain

  3. Flare-up – inflammation and tissue damage

  4. Partial recovery – new stable community forms

Each cycle leaves the microbial ecosystem slightly altered — selecting for organisms that can survive stress and immune attack.

Evolutionary Summary

Pressure Effect on Microbes Result for Host
Antibiotics Resistant, stress-adapted strains Harder-to-treat infection
Nutrient limitation Toxin and enzyme producers Tissue damage
Immune suppression Less control of microbes Opportunistic growth
Microbiome loss Opportunist expansion Reduced resilience
Biofilm evolution Genetic drift, persistence Chronic inflammation

Key Takeaway

Microbes evolve under pressure from antibiotics, immune stress, and competition.
They don’t plan to harm the host — they adapt to survive.
Unfortunately, those same adaptations often make them more damaging and persistent.

This is why good airway care, careful antibiotic use, and microbiome-friendly approaches are essential to keep the system in balance.

👉 Read also: Colonisation vs Infection in Airways Disease
(Learn how to recognise the difference, when treatment is needed, and how to keep microbial balance.)

by GAtherton

🧬 From Scottish Discovery to American Pharmacy Shelf: The Story of Brensocatib

Sometimes a medicine begins life in one country but reaches patients first in another. The new bronchiectasis drug brensocatib is a perfect example — discovered in Scotland, yet first approved for use in the United States.
Here’s how that happens, and what it tells us about how new treatments make their way to patients.

1️⃣ Discovery in Dundee

At the University of Dundee, scientists in the Drug Discovery Unit (DDU) were studying how certain white blood cells called neutrophils can cause long-term lung damage.
They identified an enzyme, DPP1 (dipeptidyl peptidase I), that activates destructive substances inside these cells.
Blocking DPP1 could calm inflammation without wiping out the body’s defences.
Their research produced a promising new compound — later named brensocatib — which safely switched off this process in lab studies.

2️⃣ Partnering to Go Global

Turning an early discovery into a medicine is an enormous task.
It costs hundreds of millions of pounds and can take 10–15 years.
The Dundee team partnered with Insmed, a biotechnology company based in New Jersey, USA, which had the funding and international trial experience to move brensocatib into large clinical studies.

3️⃣ Worldwide Trials

Insmed led major trials involving hundreds of people with non-cystic fibrosis bronchiectasis in hospitals across North America, Europe, and Asia.
Results showed that brensocatib reduced flare-ups and improved quality of life.
Because Insmed’s main offices and regulatory team are in the U.S., they submitted their results first to the U.S. Food and Drug Administration (FDA).

4️⃣ U.S. Approval

In 2025, the FDA approved brensocatib — the first drug of its kind to treat bronchiectasis.
American patients can now access it while other countries complete their reviews.

5️⃣ What Happens Next in the UK

In the UK, every new medicine goes through two steps:

  • The Medicines and Healthcare products Regulatory Agency (MHRA) checks that it is safe and effective.

  • Then NICE (the National Institute for Health and Care Excellence) reviews how well it works for its cost and decides whether the NHS should fund it.

NICE is expected to make its decision on brensocatib in July 2026.
Even if approved, it may first be offered to those with the most severe or frequent flare-ups while more real-world data are gathered.

💷 What Dundee Gained from Its Discovery

Although Dundee handed over development to a U.S. company, the university continues to benefit in several ways:

  • Financial return: Dundee receives upfront payments, milestone fees for each stage of progress, and royalties on global sales.
    These funds support new drug discovery projects, student training, and research facilities.

  • Scientific impact: Brensocatib’s success highlights the strength of the Drug Discovery Unit’s model, showing that UK universities can produce world-class medicines.

  • Future partnerships: Dundee’s achievement attracts new collaborations and investment, ensuring that more early discoveries have a route to reach patients.

So while the drug is made and sold by Insmed, Dundee’s scientists — and their reinvested funding — continue to play a role in future breakthroughs.

🏭 Manufacturing: Turning Discovery into a Real Medicine

Once a new drug is approved, it still has to be produced safely, at scale, and consistently.
This is often a completely separate operation from the research or licensing stage.

For brensocatib, the chemical process that makes the active ingredient was developed by Dundee and Insmed scientists early on, but large-scale manufacturing is now carried out by specialist pharmaceutical plants under strict international standards known as Good Manufacturing Practice (GMP).

Because brensocatib is a small-molecule oral drug (a tablet, not an injection), it’s made in high-tech chemical manufacturing facilities, not hospitals or biologics plants.
These sites are often in Europe, the U.S., or Asia, depending on where the supply chains, raw materials, and quality-control systems are strongest.

Manufacturing is expensive — it must ensure every tablet is identical in purity, strength, and safety — but it’s also where economies of scale help keep the cost manageable once global production ramps up.

For the NHS and NICE, manufacturing details matter too, because:

  • They affect cost-effectiveness (how much the NHS will pay per course of treatment).

  • They influence availability — whether the company can supply enough medicine to meet demand once approved in the UK.

So, while the discovery began in Dundee and the approval started in the U.S., manufacturing is the bridge that makes it real — transforming a scientific idea into a medicine that can be prescribed to patients worldwide.

🌍 Why This Matters

This journey shows how scientific discovery is global.
A breakthrough can start in a Scottish laboratory, be developed with American funding, tested around the world, manufactured across several continents, and eventually come back to help patients in the UK.
It’s a reminder that international collaboration — between researchers, funders, manufacturers, and regulators — is what turns good science into real treatments.

by GAtherton

🧩 NAC Aspergillosis Research Digest Aspergillosis (October 2025: week 44)

Highlights

  • Pulmonary aspergillosis in chronic lung disease can be severe and life-threatening, especially in patients with underlying interstitial lung conditions. Prompt diagnosis and subtype-targeted treatment are crucial for better outcomes (7).

  • Advanced sinus imaging in dogs improves veterinary precision for diagnosing and treating fungal infections such as aspergillosis (1).

  • Poultry farms in Turkey are best protected against aspergillosis outbreaks through consistent hygiene and environment management (3).

  • Pediatric liver transplant patients remain at high risk of deadly fungal infections, so ongoing immune and drug monitoring is vital (2).

  • New antifungal agents such as isavuconazole are yielding positive results in children, adults, and drug-resistant cases (10).

  • Agricultural fungicide use is driving azole resistance in Aspergillus, prompting urgent "One Health" responses across medicine and farming (8).

  • Research is underway to determine the best antifungal prophylaxis for heart transplant recipients (6).

  • Case studies show severe treatment challenges for aspergillosis in post-tuberculosis and cancer patients (5), (9).

Pulmonary Aspergillosis in Lung Disease

Recent research examined the prevalence and outcomes of aspergillosis among patients with interstitial lung disease (ILD) and chronic respiratory disorders. The study highlights three major forms:

  • Invasive Pulmonary Aspergillosis (IPA): Occurs in roughly 2% of hospitalised ILD patients, presenting with symptoms such as fever, persistent cough, and rapid decline in lung function. Those prescribed steroids or immunosuppressants and showing certain lung scan features are at greater risk. Estimated 3-month mortality can reach 50%.

  • Chronic Cavitary Pulmonary Aspergillosis (CPA): Represents about 0.6% of cases in target populations, with slower onset but significant respiratory impairment over time. Mortality is lower than IPA but remains notable.

  • Allergic Bronchopulmonary Aspergillosis (ABPA): Occurs in about 3% of studied patients, typically with a better prognosis, though delayed care can worsen outcomes.

Diagnostic strategies involve serology, antigen testing, and imaging to distinguish subtypes and select appropriate antifungal therapy. The study urges multidisciplinary care and more effective protocols for immunosuppressed patients (7).

Veterinary and Animal Health

Advanced radiological mapping now allows veterinarians to better diagnose and treat sinus aspergillosis across various breeds. This enhances surgical accuracy and supports targeted case management (1).
Poultry studies highlight aspergillosis as a leading fungal threat, with hygiene as the most effective control tactic (3).

Human Health: Transplant, Immunosuppression, and Infection

Children undergoing liver transplants require ongoing immune suppression, which increases susceptibility to severe fungal infections like aspergillosis. This underscores the value of rigorous therapeutic monitoring (2).
Current protocols are evaluating which antifungal drugs work best in heart transplant recipients to prevent invasive fungal infections (6)

Clinical Complications and Case Reports

Case studies spotlight life-threatening adrenal crisis and aspergillosis in children recovered from TB and adults with leukaemia. Timely diagnosis and combined therapies are essential for recovery (5), (9)
Transplant patients are vulnerable to bacterial and fungal sinus infections, presenting significant diagnostic challenges (4).

Drug Resistance and Novel Treatments

The rise of azole-resistant Aspergillus, driven by agricultural fungicide use, is making some forms of aspergillosis harder to treat. Integrated medical and environmental interventions are needed to slow resistance (8)
New medications, such as isavuconazole, are being adopted for severe and resistant cases in paediatric and adult populations with positive early results (10).

Reference List

  1. Cross-Sectional Radiological and Reconstructive Anatomy of the Paranasal Sinuses in Normal Mesaticephalic Dogs
  2. Pharmacokinetic Monitoring of JAK Inhibitor and Tacrolimus for Safe and Effective Management of Graft-Versus-Host Disease After Pediatric Liver Transplantation
  3. A Review on Aspergillosis in Turkey: As a Main Fungal Disease in Poultry
  4. Necrotizing Pseudomonal Sinusitis in a Transplant Patient
  5. Post‐Tuberculosis Adrenal Crisis in a Young Boy: A Case Report
  6. Antifungal prophylaxis against invasive Candida and Aspergillus infection in adult heart transplant recipients: protocol for a systematic review and meta-analysis
  7. Clinical characteristics and prognosis of pulmonary aspergillosis complicating interstitial lung diseases
  8. Azole fungicides and Aspergillus resistance, five EU agency report highlights the problem for the first time using a One Health approach
  9. Blinatumomab Along With Combined Antifungal Agents for Refractory Adult Acute Lymphoblastic Leukemia With Invasive Aspergillosis: A Case Report
  10. Real-life use of isavuconazole in Spanish children and adolescents

by GAtherton

🌬️ Inhaled Antifungal Treatments for Chronic Pulmonary Aspergillosis (CPA)

Updated: October 2025

💡 Why are inhaled antifungals being developed?

For people living with Chronic Pulmonary Aspergillosis (CPA), treatment usually involves long courses of oral antifungal tablets such as itraconazole, voriconazole, or posaconazole.
These medicines circulate through the whole body to reach the lungs — but sometimes they cause side-effects, interact with other drugs, or fail to reach high enough levels in thick mucus, cavities, or scarred areas of lung tissue.

Inhaled antifungal therapy aims to solve this problem by delivering medicine directly to the lungs using a nebuliser or inhaler device.
This can potentially mean:

  • ✅ Higher drug levels exactly where infection is active

  • ⚡ Faster local action

  • 🚫 Fewer whole-body side-effects

  • 🧩 Fewer drug interactions

This approach is especially promising for patients with localized lung disease, such as CPA or aspergillus bronchitis, where the fungus lives in damaged parts of the lung.

💊 Current inhaled antifungal options (used off-label)

🧪 Nebulised Amphotericin B

At the moment, nebulised amphotericin B is the only inhaled antifungal used in hospitals, although it is off-label for CPA.

It is more commonly used to prevent infection in people who have had a lung transplant or who are severely immunocompromised.
In some specialist centres, it may be used as maintenance therapy or an add-on for CPA if other antifungals have not worked or cannot be tolerated.

Advantages

  • High concentration in lung tissue

  • Minimal effects on other organs (especially the kidneys)

Drawbacks

  • Possible airway irritation (cough, tight chest, wheezing)

  • Requires specialist supervision and appropriate nebuliser equipment

🔬 New treatments in development

💨 Opelconazole (also called PC-945)

Opelconazole is a new inhaled triazole antifungal developed by Pulmocide Ltd in the UK.
It works in the same way as existing azole antifungals — by blocking the fungal enzyme CYP51 — but has been specially designed to stay in the lungs and minimise side-effects elsewhere.

In laboratory and early human studies, opelconazole has shown:

  • Strong activity against Aspergillus fumigatus

  • High and lasting drug levels in the lungs

  • Very low blood levels (reducing risk of toxicity and drug interactions)

  • Good tolerability in early trials

Although not yet licensed, it has been used compassionately in small numbers of patients with difficult-to-treat lung aspergillosis at centres such as Manchester and London.

🧾 Current and recent clinical trials

Trial ID Treatment Condition Purpose / Summary Status
NCT06447402 Nebulised Amphotericin B vs Saline Chronic Pulmonary Aspergillosis Tests whether regular nebulised amphotericin can help prevent CPA relapse compared with saline. Recruiting
NCT03656081 Itraconazole ± Nebulised Liposomal Amphotericin B CPA Compares oral itraconazole alone versus itraconazole plus inhaled amphotericin for symptom and scan improvement. Completed – results pending
NCT05238116 Inhaled Opelconazole + Standard Therapy Refractory Invasive Pulmonary Aspergillosis Phase 3 trial evaluating safety and added benefit of inhaled opelconazole. UK, EU, and US sites. Recruiting
NCT05037851 Inhaled Opelconazole (PC-945) Post-Lung Transplant Prophylaxis Assesses prevention of fungal infection after transplant. Found well tolerated. Completed
PubMed 34058036 Nebulised Amphotericin B vs Oral Itraconazole Pulmonary Aspergilloma (CPA subset) Six-month open study found similar improvement rates between inhaled amphotericin and oral itraconazole. Completed

👉 You can look up any of these studies on ClinicalTrials.gov by entering the trial ID (e.g. NCT06447402).

⚠️ Things to keep in mind

  • Not yet routine — Inhaled antifungals are available only in research or specialist centres.

  • Limited evidence — Most data come from transplant or invasive aspergillosis studies, not chronic infection.

  • Delivery challenges — Damaged or scarred areas of lung may be hard for inhaled drugs to reach.

  • Possible side-effects — Coughing or mild bronchospasm are common; pre-treatment with an inhaler may help.

  • Monitoring still needed — Even with inhaled therapy, your care team will continue to check symptoms, lung scans, and blood markers (such as Aspergillus IgG).

🧭 Questions to ask your specialist

If you are interested in this type of therapy, you could ask:

  • Does my centre offer nebulised amphotericin as part of CPA care?

  • Are there any clinical trials nearby (for example NCT06447402 or NCT05238116)?

  • Could an inhaled antifungal be used with my current oral treatment?

  • What are the side-effects and how are they monitored?

  • What nebuliser device is required and how often would I use it?

🏥 UK research centres involved

Current UK involvement is mainly through:

  • National Aspergillosis Centre, Wythenshawe Hospital (Manchester)

  • Royal Brompton and Harefield Hospitals (London)

  • UK transplant centres participating in Pulmocide’s opelconazole studies

🗝️ Key takeaway

Inhaled antifungal medicines are an exciting development that could make CPA treatment safer and more targeted in the future.
For now, they are mainly available through clinical trials or specialist centres, but the early results are promising — especially for those who have struggled with oral antifungal side-effects or limited success.

If you’re interested, speak to your CPA specialist or the National Aspergillosis Centre team about ongoing research and eligibility.

by GAtherton

🧬 The Story of Brensocatib: A New Way to Calm Lung Inflammation

What Is Brensocatib?

Brensocatib is a new type of anti-inflammatory medicine being developed to protect the lungs from long-term damage caused by overactive immune cells, especially neutrophils.
It is being tested by the company Insmed in people with bronchiectasis, but it may also help those with aspergillosis and other chronic lung diseases where inflammation is a major problem.

Brensocatib is taken as a once-daily tablet—not an injection.

Why Was It Developed?

In conditions like ABPA (Allergic Bronchopulmonary Aspergillosis) and CPA (Chronic Pulmonary Aspergillosis), inflammation is often persistent.
The lungs attract neutrophils, which are immune cells that normally destroy germs.
However, when too many neutrophils gather, they release enzymes that damage healthy lung tissue, thicken mucus, and make infection easier for fungi and bacteria.

Researchers realised that if they could turn down the destructive part of neutrophil activity—without turning off the immune system completely—they might be able to break the cycle of inflammation and infection.

How Brensocatib Works

Brensocatib blocks a switch inside the bone marrow called DPP1 (dipeptidyl peptidase-1).
DPP1’s job is to “activate” enzymes inside newly formed neutrophils before they enter the bloodstream.

By blocking DPP1, brensocatib stops neutrophils from producing harmful enzymes such as neutrophil elastase.
These neutrophils can still travel to the lungs and fight infection, but they cause less collateral damage.

👉 In short: brensocatib reduces lung injury caused by over-active immune cells, not by suppressing immunity itself.

Not a Biologic – A Different Type of Treatment

It’s important to understand that brensocatib is not a biologic.

Feature Biologic drugs (e.g. mepolizumab, dupilumab) Brensocatib
Made from Complex proteins or antibodies Small chemical molecule
How it’s given Injection or infusion Oral tablet
What it targets Specific immune pathways (e.g. IL-5, IL-4) Enzyme activation in neutrophils
Purpose Block inflammatory signals Reduce tissue-damaging enzymes
Typical use Severe asthma, ABPA, autoimmune diseases Bronchiectasis, chronic airway inflammation

So, while biologics act by targeting immune messengers in the bloodstream, brensocatib works deeper—at the level of neutrophil development.
The two approaches are different but potentially complementary.
Some people in future may benefit from a combination, depending on their pattern of inflammation.

The Development Story

  • Early research (2010s): Scientists found that blocking DPP1 prevented lung injury in animal studies.

  • Insmed’s discovery: Brensocatib was developed as an oral, selective DPP1 inhibitor.

  • Phase 2 WILLOW trial (2020): In people with bronchiectasis, brensocatib significantly reduced flare-ups and lowered airway inflammation.

  • Phase 3 ASPEN trial (2022–2025): A large international study now nearing completion; results are expected soon.

If successful, brensocatib could become the first approved DPP1 inhibitor for long-term inflammatory lung disease.

Why This Matters for Aspergillosis Patients

People living with aspergillosis often also have bronchiectasis, where inflammation causes persistent mucus, infection, and breathlessness.
Current treatments such as steroids, antifungals, and biologics can help, but each has limits.

Brensocatib could:

  • Reduce airway inflammation without steroid side-effects

  • Protect lung tissue from further damage

  • Possibly lower the number of flare-ups or infections

  • Work safely alongside antifungals or biologics

It represents a new way of calming inflammation—by modifying neutrophil behaviour rather than blocking the immune system.

What Happens Next

The ASPEN Phase 3 results are expected soon. If positive, Insmed plans to apply for approval in the UK, EU, and USA.
Researchers are also studying brensocatib in:

  • COPD (Chronic Obstructive Pulmonary Disease)

  • Cystic fibrosis

  • Nontuberculous mycobacterial (NTM) infections

If licensed, it could mark the first new oral anti-inflammatory class for chronic lung disease in decades.

Key Take-Home Messages

  • Brensocatib reduces harmful lung inflammation by blocking the enzyme DPP1.

  • It is a small-molecule tablet, not a biologic injection.

  • It aims to protect the lungs by preventing damage from overactive neutrophils.

  • It may offer a steroid-sparing option for chronic airway diseases like bronchiectasis and aspergillosis.

  • It’s currently in final clinical trials, with results expected soon.

💬 Find Out More

by GAtherton