Request Demo
Last update 15 Jun 2026
Chengdu Medical College
Last update 15 Jun 2026
Overview
Tags
Infectious Diseases
Nervous System Diseases
Digestive System Disorders
Small molecule drug
Chemical drugs
siRNA
Disease domain score
A glimpse into the focused therapeutic areas
Technology Platform
Most used technologies in drug development
Targets
Most frequently developed targets
Related
Target |
Mechanism |
Active Org. |
Originator Org. |
Active Indication |
Inactive Indication |
Drug Highest Phase |
First Approval Ctry. / Loc. |
First Approval Date |
Target |
Mechanism |
Active Org. |
Originator Org. |
Active Indication |
Inactive Indication |
Drug Highest Phase |
First Approval Ctry. / Loc. |
First Approval Date |
Target |
Mechanism |
Active Org. |
Originator Org. |
Active Indication |
Inactive Indication |
Drug Highest Phase |
First Approval Ctry. / Loc. |
First Approval Date |
NCT07538986
A Cluster Randomized Controlled Trial Study on How AI Critical Appraisal Training Enhances Critical Thinking in Nursing Students
ChiCTR2500107080
To explore the application of VR technology in the management of acute pain in patients with fractures
ChiCTR2500105263
Construction and empirical study of a navigation management model for stroke patients based on the slow disease trajectory
100 Clinical Results associated with Chengdu Medical College
Login to view more data
Login to view more data
31 Dec 2026JOURNAL OF ENZYME INHIBITION AND MEDICINAL CHEMISTRY
LDH isozymes as targets for cancer therapy
Review
Author: Hou, Yiqian ; Zhang, Qinglian ; Wang, Meilin ; He, Qinghua ; Zhao, Yanying
The Warburg effect, a hallmark of cancer, positions lactate dehydrogenase (LDH) as a key therapeutic target. Mammals possess three LDH isozymes (LDH-A, LDH-B, LDH-C) with distinct properties. This review critically re-evaluates the simplistic 'aerobic-anaerobic' paradigm, emphasizing that all isozymes catalyze reversible pyruvate-lactate conversion and contribute to tumor metabolism in a context-dependent manner. While LDH-A inhibition is a primary focus, challenges include metabolic plasticity and compensatory LDH-B upregulation. LDH-B plays a critical role in mitochondrial lactate oxidation. We highlight LDH-C as a compelling cancer/testis antigen target. Beyond glycolysis, LDH-C exhibits unique substrate promiscuity, generating oncometabolites like s-2-hydroxyglutarate from α-ketoglutarate. Its structural distinctions and restricted normal tissue expression offer opportunities for highly selective therapy. A comprehensive understanding of all three isozymes is essential for developing effective metabolic interventions against cancer.
01 Dec 2026MOLECULAR BIOLOGY REPORTS
Deguelin suppresses Nalm6 leukemia cell proliferation through lactate accumulation and ATP depletion
Article
Author: Qiu, Juncheng ; Luo, Xingyan ; Zhao, Ketian ; Wang, Yantang ; Zhang, Ting ; Guo, Huijie ; Feng, Kaiyu ; Liu, Yang ; Yang, Shuxia ; Mo, Chunfen
BACKGROUND:
Acute lymphoblastic leukemia (ALL) is characterized by metabolic reprogramming, including elevated glycolysis and lactate production. Monocarboxylate transporter 1 (MCT1/SLC16A1) is frequently overexpressed in ALL, sustaining glycolytic flux to promote cell proliferation. While the natural flavonoid deguelin is known to induce necroptosis at high concentrations, the mechanisms underlying its anti-leukemic effects at lower, potentially more therapeutically relevant doses remain unclear.
METHODS AND RESULTS:
Nalm6 cells were treated with deguelin (0.08-10 µM) for up to 72 h. Cell viability, apoptosis, cell cycle, reactive oxygen species (ROS), mitochondrial membrane potential (ΔΨm) were analyzed. We found that low concentration of deguelin significantly inhibited proliferation by inducing G2/M phase cell cycle arrest. This was associated with reduced ROS levels and loss of ΔΨm. Mechanistically, low concentration of deguelin activated the GSK-3β/AKT signaling pathway without inducing NF-κB/p70S6K phosphorylation. Furthermore, it concurrently downregulated lactate dehydrogenase A (LDHA) and MCT1 expression, leading to decreased intracellular lactate synthesis and influx, extracellular lactate accumulation, and ultimately, severe intracellular ATP depletion.
CONCLUSIONS:
Our study reveals the mechanism of low concentration of deguelin in ALL. It acts not through classic necroptosis, but via coordinated cell cycle arrest and a unique "metabolic trap" caused by dual inhibition of lactate synthesis and transport. These findings reposition deguelin as a promising candidate for targeted therapy against metabolic vulnerabilities in B-ALL.
01 Dec 2026MEDICAL MICROBIOLOGY AND IMMUNOLOGY
A potent protein vaccines OmpW induces strong protective immunity against Klebsiella pneumoniae in a mouse model
Article
Author: Shang, Yanan ; Jiang, Wei ; Hao, Danrui ; Huang, Ting ; Yang, Ruibin ; Che, Siyou ; Dan, Lufeng ; Lv, Zheng ; Luo, Linqiu ; Zhang, Yundong ; Chu, Yiwen ; Yuan, Yang ; Zhang, Hong ; Zhao, Kelei
100 Deals associated with Chengdu Medical College
Login to view more data
100 Translational Medicine associated with Chengdu Medical College
Login to view more data
Corporation Tree
Boost your research with our corporation tree data.
login
or
Pipeline
Pipeline Snapshot as of 20 Jun 2026
The statistics for drugs in the Pipeline is the current organization and its subsidiaries are counted as organizations,Early Phase 1 is incorporated into Phase 1, Phase 1/2 is incorporated into phase 2, and phase 2/3 is incorporated into phase 3
Preclinical
8
Login to view more data
Current Projects
Login to view more data
Deal
Boost your decision using our deal data.
login
or
Translational Medicine
Boost your research with our translational medicine data.
login
or
Profit
Explore the financial positions of over 360K organizations with Synapse.
login
or
Grant & Funding(NIH)
Access more than 2 million grant and funding information to elevate your research journey.
login
or
Investment
Gain insights on the latest company investments from start-ups to established corporations.
login
or
Financing
Unearth financing trends to validate and advance investment opportunities.
login
or
AI Agents Built for Biopharma Breakthroughs
Accelerate discovery. Empower decisions. Transform outcomes.
Get started for free today!
Accelerate Strategic R&D decision making with Synapse, PatSnap’s AI-powered Connected Innovation Intelligence Platform Built for Life Sciences Professionals.
Start your data trial now!
Synapse data is also accessible to external entities via APIs or data packages. Empower better decisions with the latest in pharmaceutical intelligence.
Bio
Bio Sequences Search & Analysis
Sign up for free
Chemical
Chemical Structures Search & Analysis
Sign up for free