Voyager CEO Al Sandrock outlines a focused strategy: remain specialists in neurology, but broaden the therapeutic modalities (gene therapy, proteins, oligonucleotides). This allows them to pursue well-validated CNS targets that are considered "undruggable" by traditional small molecules, which have historically been the only option for crossing the blood-brain barrier.

The GSK3 inhibitor was developed for CNS diseases, requiring high specificity and the ability to cross the blood-brain barrier. These same pharmaceutical characteristics—potency and lipophilicity—proved highly advantageous for treating cancer, demonstrating an unexpected but effective therapeutic pivot from neuroscience to oncology.

Instead of targeting the DMPK gene like competitors, Arthex's ATXO1 targets miR23B. This indirectly increases MBNL protein levels to compensate for sequestration while also destabilizing the toxic DMPK foci. This dual mechanism addresses both the downstream protein deficiency and the upstream genetic cause of the disease.

The commercial advantage of one-time CRISPR/Cas9 therapies is shrinking. Advancements in RNA modalities like siRNA now offer durable, long-lasting effects with a potentially safer profile. This creates a challenging risk-reward calculation for permanent gene edits in diseases where both technologies are applicable, especially as investor sentiment sours on CRISPR's long-term safety.

Actuate’s drug was designed to be highly lipophilic (fat-soluble) to cross the blood-brain barrier for CNS treatment. This same property proved crucial for its success in oncology, as it allows the drug to easily penetrate cancer cell membranes and reach the nucleus.

Voyager CEO Al Sandrock explains their AAV capsids are engineered to be so potent at crossing the blood-brain barrier that doses can be an order of magnitude lower than standard. Crucially, the capsids are also designed to *avoid* the liver, directly addressing the toxicity issues that have plagued the field.

Create Medicines chose LNP-delivered RNA for its in vivo platform to give physicians control. Unlike permanent lentiviral approaches, repeatable dosing allows for adapting to tumor antigen escape and managing durability and safety over time. This flexibility is a core strategic advantage for complex diseases like solid tumors.

Voyager's ALPL-based blood-brain barrier shuttle offers a different pharmacokinetic profile than transferrin receptor shuttles. While delivering a lower initial peak concentration (Cmax), it provides a much longer half-life. This steady, sustained exposure is optimal for therapies that require constant pathway blockage, highlighting a key strategic trade-off in delivery system design.

Immusoft balances its portfolio by internally developing a pipeline of genetically defined orphan disease therapies. Simultaneously, it generates early proof-of-concept data for higher-risk, larger markets like CNS and oncology with the explicit goal of securing strategic partnerships for those assets.